WorldWideScience

Sample records for radiation oncology department

  1. Radiation oncology

    International Nuclear Information System (INIS)

    Anon.

    1977-01-01

    The Radiation Oncology Division has had as its main objectives both to operate an academic training program and to carry out research on radiation therapy of cancer. Since fiscal year 1975, following a directive from ERDA, increased effort has been given to research. The research activities have been complemented by the training program, which has been oriented toward producing radiation oncologists, giving physicians short-term experience in radiation oncology, and teaching medical students about clinical cancer and its radiation therapy. The purpose of the research effort is to improve present modalities of radiation therapy of cancer. As in previous years, the Division has operated as the Radiation Oncology Program of the Department of Radiological Sciences of the University of Puerto Rico School of Medicine. It has provided radiation oncology support to patients at the University Hospital and to academic programs of the University of Puerto Rico Medical Sciences Campus. The patients, in turn, have provided the clinical basis for the educational and research projects of the Division. Funding has been primarily from PRNC (approx. 40%) and from National Cancer Institute grants channeled through the School of Medicine (approx. 60%). Special inter-institutional relationships with the San Juan Veterans Administration Hospital and the Metropolitan Hospital in San Juan have permitted inclusion of patients from these institutions in the Division's research projects. Medical physics and radiotherapy consultations have been provided to the Radiotherapy Department of the VA Hospital

  2. Training program in radiation protection: implantation in a radiation oncology department

    International Nuclear Information System (INIS)

    Chretien, Mario; Morrier, Janelle; Cote, Carl; Lavallee, Marie C.

    2008-01-01

    Full text: Purpose: To introduce the radiation protection training program implemented in the radiation oncology department of the Hotel-Dieu de Quebec. This program seeks to provide an adequate training for all the clinic workers and to fulfill Canadian Nuclear Safety Commission's (CNSC) legislations. Materials and Methods: The radiation protection training program implemented is based on the use of five different education modalities: 1) Oral presentations, when the objective of the formation is to inform a large number of persons about general topics; 2) Periodic journals are published bimonthly and distributed to members of the department. They aim to answer frequently asked questions on the radiation safety domain. Each journal contains one main subject which is vulgarized and short notices, these later added to inform the readers about the departmental news and developments in radiation safety; 3) Electronic self-training presentations are divided into several units. Topics, durations, complexity and evaluations are adapted for different worker groups; 4) Posters are strategically displayed in the department in order to be read by all the radiation oncology employees, even those who are not specialized in the radiation protection area; 5) Simulations are organized for specialised workers to practice and to develop their skills in radiation protection situations as emergencies. A registration method was developed to record all training performed by each member of the department. Results: The training program implemented follows the CNSC recommendations. It allows about 150 members of the department to receive proper radiation safety training. The oral presentations allow an interaction between the trainer and the workers. The periodic journals are simple to write while ensuring continuous training. They are also easy to read and to understand. The e-learning units and their associated evaluations can be done at any time and everywhere in the department. The

  3. Delegation of medical tasks in French radiation oncology departments: current situation and impact on residents' training.

    Science.gov (United States)

    Thureau, S; Challand, T; Bibault, J-E; Biau, J; Cervellera, M; Diaz, O; Faivre, J-C; Fumagalli, I; Leroy, T; Lescut, N; Martin, V; Pichon, B; Riou, O; Dubray, B; Giraud, P; Hennequin, C

    2013-10-01

    A national survey was conducted among the radiation oncology residents about their clinical activities and responsibilities. The aim was to evaluate the clinical workload and to assess how medical tasks are delegated and supervised. A first questionnaire was administered to radiation oncology residents during a national course. A second questionnaire was mailed to 59 heads of departments. The response rate was 62% for radiation oncology residents (99 questionnaires) and 51% for heads of department (30). Eighteen heads of department (64%) declared having written specifications describing the residents' clinical tasks and roles, while only 31 radiation oncology residents (34%) knew about such a document (P=0.009). A majority of residents were satisfied with the amount of medical tasks that were delegated to them. Older residents complained about insufficient exposure to new patient's consultation, treatment planning and portal images validation. The variations observed between departments may induce heterogeneous trainings and should be addressed specifically. National specifications are necessary to reduce heterogeneities in training, and to insure that the residents' training covers all the professional skills required to practice radiation oncology. A frame endorsed by academic and professional societies would also clarify the responsibilities of both residents and seniors. Copyright © 2013 Société française de radiothérapie oncologique (SFRO). Published by Elsevier SAS. All rights reserved.

  4. TU-G-201-00: Imaging Equipment Specification and Selection in Radiation Oncology Departments

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2015-06-15

    This session will update therapeutic physicists on technological advancements and radiation oncology features of commercial CT, MRI, and PET/CT imaging systems. Also described are physicists’ roles in every stage of equipment selection, purchasing, and operation, including defining specifications, evaluating vendors, making recommendations, and optimal and safe use of imaging equipment in radiation oncology environment. The first presentation defines important terminology of CT and PET/CT followed by a review of latest innovations, such as metal artifact reduction, statistical iterative reconstruction, radiation dose management, tissue classification by dual energy CT and spectral CT, improvement in spatial resolution and sensitivity in PET, and potentials of PET/MR. We will also discuss important technical specifications and items in CT and PET/CT purchasing quotes and their impacts. The second presentation will focus on key components in the request for proposal for a MRI simulator and how to evaluate vendor proposals. MRI safety issues in radiation Oncology, including MRI scanner Zones (4-zone design), will be discussed. Basic MR terminologies, important functionalities, and advanced features, which are relevant to radiation therapy, will be discussed. In the third presentation, justification of imaging systems for radiation oncology, considerations in room design and construction in a RO department, shared use with diagnostic radiology, staffing needs and training, clinical/research use cases and implementation, will be discussed. The emphasis will be on understanding and bridging the differences between diagnostic and radiation oncology installations, building consensus amongst stakeholders for purchase and use, and integrating imaging technologies into the radiation oncology environment. Learning Objectives: Learn the latest innovations of major imaging systems relevant to radiation therapy Be able to describe important technical specifications of CT, MRI

  5. Experience of wireless local area network in a radiation oncology department.

    Science.gov (United States)

    Mandal, Abhijit; Asthana, Anupam Kumar; Aggarwal, Lalit Mohan

    2010-01-01

    The aim of this work is to develop a wireless local area network (LAN) between different types of users (Radiation Oncologists, Radiological Physicists, Radiation Technologists, etc) for efficient patient data management and to made easy the availability of information (chair side) to improve the quality of patient care in Radiation Oncology department. We have used mobile workstations (Laptops) and stationary workstations, all equipped with wireless-fidelity (Wi-Fi) access. Wireless standard 802.11g (as recommended by Institute of Electrical and Electronic Engineers (IEEE, Piscataway, NJ) has been used. The wireless networking was configured with the Service Set Identifier (SSID), Media Access Control (MAC) address filtering, and Wired Equivalent Privacy (WEP) network securities. We are successfully using this wireless network in sharing the indigenously developed patient information management software. The proper selection of the hardware and the software combined with a secure wireless LAN setup will lead to a more efficient and productive radiation oncology department.

  6. Evaluating stress, burnout and job satisfaction in New Zealand radiation oncology departments.

    Science.gov (United States)

    Jasperse, M; Herst, P; Dungey, G

    2014-01-01

    This research aimed to determine the levels of occupational stress, burnout and job satisfaction among radiation oncology workers across New Zealand. All oncology staff practising in all eight radiation oncology departments in New Zealand were invited to participate anonymously in a questionnaire, which consisted of the Maslach Burnout Inventory and measures of stress intensity associated with specific occupational stressors, stress reduction strategies and job satisfaction. A total of 171 (out of 349) complete responses were analysed using spss 19; there were 23 oncologists, 111 radiation therapists, 22 radiation nurses and 15 radiation physicists. All participants, regardless of profession, reported high stress levels associated with both patient-centred and organisational stressors. Participants scored high in all three domains of burnout: emotional exhaustion, depersonalisation and personal accomplishment. Interestingly, although organisational stressors predicted higher emotional exhaustion and emotional exhaustion predicted lower job satisfaction, patient stressors were associated with higher job satisfaction. Job satisfaction initiatives such as ongoing education, mentoring and role extension were supported by many participants as was addressing organisational stressors, such as lack of recognition and support from management and unrealistic expectations and demands. New Zealand staff exhibit higher levels of burnout than Maslach Burnout Inventory medical norms and oncology workers in previous international studies. © 2013 John Wiley & Sons Ltd.

  7. Final report from the Spanish Society of Radiotherapy and Oncology Infrastructures Commission about department standards recommendable in radiation oncology

    International Nuclear Information System (INIS)

    Esco, R.; Pardo, J.; Palacios, A.; Biete, A.; Fernandez, J.; Valls, A.; Herrazquin, L.; Roman, P.; Magallon, R.

    2001-01-01

    The publication of the Royal Decree 1566/1988 of July 17 th , about Quality Assurance and Control in Radiation Therapy, mandates the elaboration of protocols in Radiation Therapy. Those protocols must contemplate the material and human resources necessary to implement a quality practical radiation therapy according to law. In order to establish norms regarding human and material resources, it is necessary to establish beforehand some patient care standards that serve as a frame of reference to determine the resources needed for each procedure. Furthermore, the necessary coordination of resources, material and humans that have to be present in a correct patient care planning, mandates the publication of rules that are easy to interpret and follow up. In this direction, both editions of the 'White Book of Oncology in Spain', the 'GAT Document for Radiotherapy', and the rules edited by the Committee of Experts in Radiation Therapy of the Academy of Medical Sciences of Catalunya and Balears, have represented an important advance in the establishment of these criteria in Spain. The Spanish Society of Radiation Therapy and Oncology (AERO), in an attempt to facilitate to all its associates and the health authorities some criteria for planning and implementing resources, requested its Commission of Infrastructures to elaborate a set of rules to determine the necessary resources in each radiation therapy procedure. The objective of this document is to establish some recommendations about the minimal necessities of treatment units and staff, determining their respective work capabilities, to be able to develop a quality radiation therapy in departments already existing. In summary, it is intended that the patient care is limited in a way that quality is not affected by patient overload. Also it tries to offer the Public Administration some planning criteria useful to create the necessary services of Radiation Oncology, with the adequate resources, which will bring a

  8. Meeting the challenge of managed care - Part II: Designing a radiation oncology department and setting up a clinical practice program

    International Nuclear Information System (INIS)

    Halman, Marc A.; Szerlag, Chester

    1997-01-01

    Objective: Identify the business practices necessary to develop a successful radiation oncology department in the current health care environment. Course content will be of interest to new practitioners establishing first time programs or joining existing groups as well as experienced radiation oncologists who are challenged with redesigning programs to be competitive. Course Content: During this session, the following topics will be discussed: 1) Space planning and equipment selection 2) Personnel; creating efficiencies while promoting productivity 3) Professional and Technical Billing; establishing proper fee structures and coding procedures 4) Utilizing benchmarking as a tool to improve operations 5) Information technology in radiation oncology 6) Current and Future Trends: a) Oncology networks b) Reimbursement: managed care and capitation c) Downsizing d) Relative Value Units

  9. Nanotechnology in Radiation Oncology

    Science.gov (United States)

    Wang, Andrew Z.; Tepper, Joel E.

    2014-01-01

    Nanotechnology, the manipulation of matter on atomic and molecular scales, is a relatively new branch of science. It has already made a significant impact on clinical medicine, especially in oncology. Nanomaterial has several characteristics that are ideal for oncology applications, including preferential accumulation in tumors, low distribution in normal tissues, biodistribution, pharmacokinetics, and clearance, that differ from those of small molecules. Because these properties are also well suited for applications in radiation oncology, nanomaterials have been used in many different areas of radiation oncology for imaging and treatment planning, as well as for radiosensitization to improve the therapeutic ratio. In this article, we review the unique properties of nanomaterials that are favorable for oncology applications and examine the various applications of nanotechnology in radiation oncology. We also discuss the future directions of nanotechnology within the context of radiation oncology. PMID:25113769

  10. Evaluation of indoor air quality in a department of radiation oncology located underground

    International Nuclear Information System (INIS)

    Kim, Won Taek; Kwon, Byung Hyun; Kang, Dong Mug; Ki, Yong Kan; Kim, Dong Won; Shin, Yong Chul

    2005-01-01

    contaminated-air circulation immediately. We verified that some IAQ-related factors and inadequate ventilating system could cause subjective symptoms in hospital workers. The evaluation of IAQ was surely needed to improve the underground working environment for hospital workers and patients. On the basis of these data, from now on, we should actively engage in designs of the department of radiation oncology or improvement in environment of the existing facilities

  11. Basic radiation oncology

    International Nuclear Information System (INIS)

    Beyzadeoglu, M. M.; Ebruli, C.

    2008-01-01

    Basic Radiation Oncology is an all-in-one book. It is an up-to-date bedside oriented book integrating the radiation physics, radiobiology and clinical radiation oncology. It includes the essentials of all aspects of radiation oncology with more than 300 practical illustrations, black and white and color figures. The layout and presentation is very practical and enriched with many pearl boxes. Key studies particularly randomized ones are also included at the end of each clinical chapter. Basic knowledge of all high-tech radiation teletherapy units such as tomotherapy, cyberknife, and proton therapy are also given. The first 2 sections review concepts that are crucial in radiation physics and radiobiology. The remaining 11 chapters describe treatment regimens for main cancer sites and tumor types. Basic Radiation Oncology will greatly help meeting the needs for a practical and bedside oriented oncology book for residents, fellows, and clinicians of Radiation, Medical and Surgical Oncology as well as medical students, physicians and medical physicists interested in Clinical Oncology. English Edition of the book Temel Radyasyon Onkolojisi is being published by Springer Heidelberg this year with updated 2009 AJCC Staging as Basic Radiation Oncology

  12. A survey of techniques to reduce and manage external beam radiation-induced xerostomia in British oncology and radiotherapy departments

    International Nuclear Information System (INIS)

    Macknelly, Andrew; Day, Jane

    2009-01-01

    ? - A feasibility study for locally advanced head and neck cancer patients treated with intensity-modulated radiotherapy. Clinical Oncology 2006;18(6):497-504, Braam P, Terhaard C, Roesnink J, Cornelis P, Raaijmakers C. Intensity-modulated radiotherapy significantly reduces xerostomia compared with conventional radiotherapy. International Journal of Radiation Oncology, Biology and Physics 2006, Wendt TG, Abbasi-Senger N, Salz H, Pinquart I, Koscelny S, Przetak S, et al. 3D-conformal-intensity modulated radiotherapy with compensators for head and neck cancer: clinical results of normal tissue sparing. Radiation Oncology 2006;1:18. Available from: (http://www.ro-journal.com/content/1/1/18) [accessed on 21.11.06].]. This, in turn, offers increased normal tissue sparing than conventional radiotherapy [Ng M, Porceddu S, Milner A, Corry J, Hornby C, Hope G, et al. Parotid-sparing radiotherapy: does it really reduce xerostomia? Clinical Oncology 2005;17(8):610-7.]. The survey indicated that all three techniques, however, are still in use in oncology and radiotherapy departments, and several departments stated that financial considerations were hindering their move toward providing IMRT.

  13. Information technologies for radiation oncology

    International Nuclear Information System (INIS)

    Chen, George T.Y.

    1996-01-01

    Electronic exchange of information is profoundly altering the ways in which we share clinical information on patients, our research mission, and the ways we teach. The three panelists each describe their experiences in information exchange. Dr. Michael Vannier is Professor of Radiology at the Mallinkrodt Institute of Radiology, and directs the image processing laboratory. He will provide insights into how radiologists have used the Internet in their specialty. Dr. Joel Goldwein, Associate Professor in the Department of Radiation Oncology at the University of Pennsylvania, will describe his experiences in using the World Wide Web in the practice of academic radiation oncology and the award winning Oncolink Web Site. Dr. Timothy Fox Assistant, Professor of Radiation Oncology at Emory University will discuss wide area networking of multi-site departments, to coordinate center wide clinical, research and teaching activities

  14. Patterns of Care for Lung Cancer in Radiation Oncology Departments of Turkey

    International Nuclear Information System (INIS)

    Demiral, Ayse Nur; Alicikus, Zuemre Arican; Isil Ugur, Vahide; Karadogan, Ilker; Yoeney, Adnan; Andrieu, Meltem Nalca; Yalman, Deniz; Pak, Yuecel; Aksu, Gamze; Ozyigit, Goekhan; Ozkan, Luetfi; Kilciksiz, Sevil; Koca, Sedat; Caloglu, Murat; Yavuz, Ali Aydin; Basak Caglar, Hale; Beyzadeoglu, Murat; Igdem, Sefik

    2008-01-01

    Purpose: To determine the patterns of care for lung cancer in Turkish radiation oncology centers. Methods and Materials: Questionnaire forms from 21 of 24 (87.5%) centers that responded were evaluated. Results: The most frequent histology was non-small cell lung cancer (NSCLC) (81%). The most common postoperative radiotherapy (RT) indications were close/(+) surgical margins (95%) and presence of pN2 disease (91%). The most common indications for postoperative chemotherapy (CHT) were '≥ IB' disease (19%) and the presence of pN2 disease (19%). In Stage IIIA potentially resectable NSCLC, the most frequent treatment approach was neoadjuvant concomitant chemoradiotherapy (CHRT) (57%). In Stage IIIA unresectable and Stage IIIB disease, the most frequent approach was definitive concomitant CHRT (91%). In limited SCLC, the most common treatment approach was concomitant CHRT with cisplatin+etoposide for cycles 1-3, completion of CHT to cycles 4-6, and finally prophylactic cranial irradiation in patients with complete response (71%). Six cycles of cisplatin + etoposide CHT and palliative thoracic RT, when required, was the most commonly used treatment (81%) in extensive SCLC. Sixty-two percent of centers did not have endobronchial brachytherapy (EBB) facilities. Conclusion: There is great variation in diagnostic testing, treatment strategies, indications for postoperative RT and CHT, RT features, and EBB availability for LC cases. To establish standards, national guidelines should be prepared using a multidisciplinary approach

  15. Innovations in radiation oncology

    International Nuclear Information System (INIS)

    Withers, H.R.

    1988-01-01

    The series 'Medical Radiology - Diagnostic Imaging and Radiation Oncology' is the successor to the well known 'Encyclopedia of Medical Radiology/Handbuch der medizinischen Radiologie'. 'Medical Radiology' brings the state of the art on special topics in a timely fashion. This volume 'Innovation in Radiation Oncology', edited by H.R. Withers and L.J. Peters, presents data on the development of new therapeutic strategies in different oncologic diseases. 57 authors wrote 32 chapters covering a braod range of topics. The contributors have written their chapters with the practicing radiation oncologist in mind. The first chapter sets the stage by reviewing the quality of radiation oncology as it is practiced in the majority of radiation oncology centers in the United States. The second chapter examines how we may better predict the possible causes of failure of conventional radiotherapy in order that the most appropriate of a variety of therapeutic options may eventually be offered to patients on an individual basis. The third chapter discussed how our therapeutic endeavors affect the quality of life, a problem created by our ability to be successful. Following these three introductory chapters there are 29 chapters by highly qualified specialists discussing the newest ideas in subjects of concern to the practicing radiation oncologist. With 111 figs

  16. Journey Toward High Reliability: A Comprehensive Safety Program to Improve Quality of Care and Safety Culture in a Large, Multisite Radiation Oncology Department.

    Science.gov (United States)

    Woodhouse, Kristina Demas; Volz, Edna; Maity, Amit; Gabriel, Peter E; Solberg, Timothy D; Bergendahl, Howard W; Hahn, Stephen M

    2016-05-01

    High-reliability organizations (HROs) focus on continuous identification and improvement of safety issues. We sought to advance a large, multisite radiation oncology department toward high reliability through the implementation of a comprehensive safety culture (SC) program at the University of Pennsylvania Department of Radiation Oncology. In 2011, with guidance from safety literature and experts in HROs, we designed an SC framework to reduce radiation errors. All state-reported medical events (SRMEs) from 2009 to 2016 were retrospectively reviewed and plotted on a control chart. Changes in SC grade were assessed using the Agency for Healthcare Research and Quality Hospital Survey. Outcomes measured included the number of radiation treatment fractions and days between SRMEs, as well as SC grade. Multifaceted safety initiatives were implemented at our main academic center and across all network sites. Postintervention results demonstrate increased staff fundamental safety knowledge, enhanced peer review with an electronic system, and special cause variation of SRMEs on control chart analysis. From 2009 to 2016, the number of days and fractions between SRMEs significantly increased, from a mean of 174 to 541 days (P safety framework. Our multifaceted initiatives, focusing on culture and system changes, can be successfully implemented in a large academic radiation oncology department to yield measurable improvements in SC and outcomes. Copyright © 2016 by American Society of Clinical Oncology.

  17. Radiation oncology in Canada.

    Science.gov (United States)

    Giuliani, Meredith; Gospodarowicz, Mary

    2018-01-01

    In this article we provide an overview of the Canadian healthcare system and the cancer care system in Canada as it pertains to the governance, funding and delivery of radiotherapy programmes. We also review the training and practice for radiation oncologists, medical physicists and radiation therapists in Canada. We describe the clinical practice of radiation medicine from patients' referral, assessment, case conferences and the radiotherapy process. Finally, we provide an overview of the practice culture for Radiation Oncology in Canada. © The Author 2017. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.

  18. Qualitative Assessment of Academic Radiation Oncology Department Chairs' Insights on Diversity, Equity, and Inclusion: Progress, Challenges, and Future Aspirations.

    Science.gov (United States)

    Jones, Rochelle D; Chapman, Christina H; Holliday, Emma B; Lalani, Nafisha; Wilson, Emily; Bonner, James A; Movsas, Benjamin; Kalnicki, Shalom; Formenti, Silvia C; Thomas, Charles R; Hahn, Stephen M; Liu, Fei-Fei; Jagsi, Reshma

    2018-05-01

    A lack of diversity has been observed in radiation oncology (RO), with women and certain racial/ethnic groups underrepresented as trainees, faculty, and practicing physicians. We sought to gain a nuanced understanding of how to best promote diversity, equity, and inclusion (DEI) based on the insights of RO department chairs, with particular attention given to the experiences of the few women and underrepresented minorities (URMs) in these influential positions. From March to June 2016, we conducted telephone interviews with 24 RO department chairs (of 27 invited). Purposive sampling was used to invite all chairs who were women (n = 13) or URMs (n = 3) and 11 male chairs who were not URMs. Multiple analysts coded the verbatim transcripts. Five themes were identified: (1) commitment to DEI promotes quality health care and innovation; (2) gaps remain despite some progress with promoting diversity in RO; (3) women and URM faculty continue to experience challenges in various career domains; (4) solutions to DEI issues would be facilitated by acknowledging realities of gender and race; and (5) expansion of the career pipeline is needed. The chairs' insights had policy-relevant implications. Bias training should broach tokenism, blindness, and intersectionality. Efforts to recruit and support diverse talent should be deliberate and proactive. Bridge programs could engage students before their application to medical school. Copyright © 2018 Elsevier Inc. All rights reserved.

  19. Profile of European radiotherapy departments contributing to the EORTC Radiation Oncology Group (ROG) in the 21st century

    NARCIS (Netherlands)

    Budiharto, Tom; Musat, Elena; Poortmans, Philip; Hurkmans, Coen; Monti, Angelo; Bar-Deroma, Raquel; Bernstein, Zvi; van Tienhoven, Geertjan; Collette, Laurence; Duclos, Frédéric; Davis, Bernard; Aird, Edwin

    2008-01-01

    Since 1982, the Radiation Oncology Group of the EORTC (EORTC ROG) has pursued an extensive Quality Assurance (QA) program involving all centres actively participating in its clinical research. The first step is the evaluation of the structure and of the human, technical and organisational resources

  20. Quality in radiation oncology

    International Nuclear Information System (INIS)

    Pawlicki, Todd; Mundt, Arno J.

    2007-01-01

    A modern approach to quality was developed in the United States at Bell Telephone Laboratories during the first part of the 20th century. Over the years, those quality techniques have been adopted and extended by almost every industry. Medicine in general and radiation oncology in particular have been slow to adopt modern quality techniques. This work contains a brief description of the history of research on quality that led to the development of organization-wide quality programs such as Six Sigma. The aim is to discuss the current approach to quality in radiation oncology as well as where quality should be in the future. A strategy is suggested with the goal to provide a threshold improvement in quality over the next 10 years

  1. Encyclopedia of radiation oncology

    Energy Technology Data Exchange (ETDEWEB)

    Brady, Luther W. [Drexel Univ. College of Medicine, Philadelphia, PA (United States); Yaeger, Theodore E. (eds.) [Wake Forest Univ. School of Medicine, Winston-Salem, NC (United States). Dept. of Radiation Oncology

    2013-02-01

    The simple A to Z format provides easy access to relevant information in the field of radiation oncology. Extensive cross references between keywords and related articles enable efficient searches in a user-friendly manner. Fully searchable and hyperlinked electronic online edition. The aim of this comprehensive encyclopedia is to provide detailed information on radiation oncology. The wide range of entries are written by leading experts. They will provide basic and clinical scientists in academia, practice and industry with valuable information about the field of radiation oncology. Those in related fields, students, teachers, and interested laypeople will also benefit from the important and relevant information on the most recent developments. Please note that this publication is available as print only or online only or print + online set. Save 75% of the online list price when purchasing the bundle. For more information on the online version please type the publication title into the search box above, then click on the eReference version in the results list.

  2. Audit of high energy therapy beams in hospital oncology departments by the National Radiation Laboratory

    International Nuclear Information System (INIS)

    Smyth, V.G.

    1994-02-01

    In 1993 the output of every high energy radiotherapy beam used clinically in New Zealand was measured by National Radiation Laboratory (NRL) staff using independent dosimetry equipment. The purpose of this was to audit the dosimetry that is used by hospital physicists for the basis of patient treatments, and to uncover any errors that may be clinically significant. This report analyses the uncertainties involved in comparing the NRL and hospital measurements, and presents the results of the 1993 audit. The overall uncertainty turns out to be about 1.5%. The results for linear accelerator photon beams are consistent with a purely random variation within this uncertainty. Electron beams show some small errors beyond the expected uncertainty. Gamma beams have the potential to be the most accurately measured, but in practice are less accurately measured than linear accelerator beams. None of the disagreements indicated an error of clinical significance. 8 refs., 3 figs., 2 tabs

  3. Evaluation of tumor registry validity in Samsung medical center radiation oncology department

    International Nuclear Information System (INIS)

    Park, Won; Huh, Seung Jae; Kim, Dae Yong; Shin, Seong Soo; Ahn, Yong Chan; Lim, Do Hoon; Kim, Seon Woo

    2004-01-01

    A tumor registry system for the patients treated by radiotherapy at Samsung Medical Center since the opening of a hospital at 1994 was employed. In this study, the tumor registry system was introduced and the validity of the tumor registration was analyzed. The tumor registry system was composed of three parts: patient demographic, diagnostic, and treatment information. All data were input in a screen using a mouse only. Among the 10,000 registered cases in the tumor registry system until Aug, 2002, 199 were randomly selected and their registration data were compared with the patients' medical records. Total input errors were detected in 15 cases (7.5%). There were 8 error items in the part relating to diagnostic information: tumor site 3, pathology 2, AJCC staging 2 and performance status 1. In the part relating to treatment information there were 9 mistaken items: combination treatment 4, the date of initial treatment 3 and radiation completeness 2. According to the assignment doctor, the error ratio was consequently variable. The doctors who did no double-checks showed higher errors than those that did (15.6%: 3.7%). Our tumor registry had errors within 2% for each item. Although the overall data quality was high, further improvement might be achieved through promoting sincerity, continuing training periodic validity tests and keeping double-checks. Also, some items associated with the hospital information system will be input automatically in the next step

  4. Radiation oncology systems integration

    International Nuclear Information System (INIS)

    Ragan, D.P.

    1991-01-01

    ROLE7 is intended as a complementary addition to the HL7 Standard and not as an alternative standard. Attempt should be made to mould data elements which are specific to radiation therapy with existing HL7 elements. This can be accomplished by introducing additional values to some element's table-of-options. Those elements which might be specific to radiation therapy could from new segments to be added to the Ancillary Data Reporting set. In order to accomplish ROLE7, consensus groups need be formed to identify the various functions related to radiation oncology that might motivate information exchange. For each of these functions, the specific data elements and their format must be identified. HL7 is organized with a number of applications which communicate asynchronously. Implementation of ROLE7 would allow uniform access to information across vendors and functions. It would provide improved flexibility in system selection. It would allow a more flexible and affordable upgrade path as systems in radiation oncology improve. (author). 5 refs

  5. Quality Indicators in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Albert, Jeffrey M. [Department of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Das, Prajnan, E-mail: prajdas@mdanderson.org [Department of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States)

    2013-03-15

    Oncologic specialty societies and multidisciplinary collaborative groups have dedicated considerable effort to developing evidence-based quality indicators (QIs) to facilitate quality improvement, accreditation, benchmarking, reimbursement, maintenance of certification, and regulatory reporting. In particular, the field of radiation oncology has a long history of organized quality assessment efforts and continues to work toward developing consensus quality standards in the face of continually evolving technologies and standards of care. This report provides a comprehensive review of the current state of quality assessment in radiation oncology. Specifically, this report highlights implications of the healthcare quality movement for radiation oncology and reviews existing efforts to define and measure quality in the field, with focus on dimensions of quality specific to radiation oncology within the “big picture” of oncologic quality assessment efforts.

  6. Quality Indicators in Radiation Oncology

    International Nuclear Information System (INIS)

    Albert, Jeffrey M.; Das, Prajnan

    2013-01-01

    Oncologic specialty societies and multidisciplinary collaborative groups have dedicated considerable effort to developing evidence-based quality indicators (QIs) to facilitate quality improvement, accreditation, benchmarking, reimbursement, maintenance of certification, and regulatory reporting. In particular, the field of radiation oncology has a long history of organized quality assessment efforts and continues to work toward developing consensus quality standards in the face of continually evolving technologies and standards of care. This report provides a comprehensive review of the current state of quality assessment in radiation oncology. Specifically, this report highlights implications of the healthcare quality movement for radiation oncology and reviews existing efforts to define and measure quality in the field, with focus on dimensions of quality specific to radiation oncology within the “big picture” of oncologic quality assessment efforts

  7. Quantification of the impact of multifaceted initiatives intended to improve operational efficiency and the safety culture: a case study from an academic medical center radiation oncology department.

    Science.gov (United States)

    Chera, Bhishamjit S; Mazur, Lukasz; Jackson, Marianne; Taylor, Kinely; Mosaly, Prithima; Chang, Sha; Deschesne, Kathy; LaChapelle, Dana; Hoyle, Lesley; Saponaro, Patricia; Rockwell, John; Adams, Robert; Marks, Lawrence B

    2014-01-01

    We have systematically been incorporating several operational efficiency and safety initiatives into our academic radiation oncology clinic. We herein quantify the impact of these initiatives on prospectively collected, clinically meaningful, metrics. The data from 5 quality improvement initiatives, each focused on a specific safety/process concern in our clinic, are presented. Data was collected prospectively: operational metrics recorded before and after implementation of the initiative were compared using statistical analysis. Results from the Agency for Health Care Research and Quality (AHRQ) patient safety culture surveys administered during and after many of these initiatives were similarly compared. (1) Workload levels for nurses assisting with brachytherapy were high (National Aeronautics and Space Administration Task Load Index (NASA-TLX) scores >55-60, suggesting, "overwork"). Changes in work flow and procedure room layout reduced workload to more acceptable levels (NASA-TLX 50% to <10%; P < .01). To assess the overall changes in "patient safety culture," we conducted a pre- and postanalysis using the AHRQ survey. Improvements in all measured dimensions were noted. Quality improvement initiatives can be successfully implemented in an academic radiation oncology department to yield measurable improvements in operations resulting in improvement in patient safety culture. Copyright © 2014 American Society for Radiation Oncology. Published by Elsevier Inc. All rights reserved.

  8. Global Health in Radiation Oncology

    DEFF Research Database (Denmark)

    Rodin, Danielle; Yap, Mei Ling; Grover, Surbhi

    2017-01-01

    programs. However, formalized training and career promotion tracks in global health within radiation oncology have been slow to emerge, thereby limiting the sustained involvement of students and faculty, and restricting opportunities for leadership in this space. We examine here potential structures...... and benefits of formalized global health training in radiation oncology. We explore how defining specific competencies in this area can help trainees and practitioners integrate their activities in global health within their existing roles as clinicians, educators, or scientists. This would also help create...... and funding models might be used to further develop and expand radiation oncology services globally....

  9. Imaging Opportunities in Radiation Oncology

    International Nuclear Information System (INIS)

    Balter, James M.; Haffty, Bruce G.; Dunnick, N. Reed; Siegel, Eliot L.

    2011-01-01

    Interdisciplinary efforts may significantly affect the way that clinical knowledge and scientific research related to imaging impact the field of Radiation Oncology. This report summarizes the findings of an intersociety workshop held in October 2008, with the express purpose of exploring 'Imaging Opportunities in Radiation Oncology.' Participants from the American Society for Radiation Oncology (ASTRO), National Institutes of Health (NIH), Radiological Society of North America (RSNA), American Association of physicists in Medicine (AAPM), American Board of Radiology (ABR), Radiation Therapy Oncology Group (RTOG), European Society for Therapeutic Radiology and Oncology (ESTRO), and Society of Nuclear Medicine (SNM) discussed areas of education, clinical practice, and research that bridge disciplines and potentially would lead to improved clinical practice. Findings from this workshop include recommendations for cross-training opportunities within the allowed structured of Radiology and Radiation Oncology residency programs, expanded representation of ASTRO in imaging related multidisciplinary groups (and reciprocal representation within ASTRO committees), increased attention to imaging validation and credentialing for clinical trials (e.g., through the American College of Radiology Imaging Network (ACRIN)), and building ties through collaborative research as well as smaller joint workshops and symposia.

  10. A local-area-network based radiation oncology microcomputer system

    International Nuclear Information System (INIS)

    Chu, W.K.; Taylor, T.K.; Kumar, P.P.; Imray, T.J.

    1985-01-01

    The application of computerized technology in the medical specialty of radiation oncology has gained wide acceptance in the past decade. Recognizing that most radiation oncology department personnel are familiar with computer operations and terminology, it appears reasonable to attempt to expand the computer's applications to other departmental activities, such as scheduling, record keeping, billing, treatment regimen and status, etc. Instead of sharing the processing capability available on the existent treatment minicomputer, the radiation oncology computer system is based upon a microcomputer local area network (LAN). The system was conceptualized in 1984 and completed in March 1985. This article outlines the LAN-based radiation oncology computer system

  11. Profile of European radiotherapy departments contributing to the EORTC Radiation Oncology Group (ROG) in the 21st century

    International Nuclear Information System (INIS)

    Budiharto, Tom; Musat, Elena; Poortmans, Philip; Hurkmans, Coen; Monti, Angelo; Bar-Deroma, Raquel; Bernstein, Zvi; Tienhoven, Geertjan van; Collette, Laurence; Duclos, Frederic; Davis, Bernard; Aird, Edwin

    2008-01-01

    Purpose: Since 1982, the Radiation Oncology Group of the EORTC (EORTC ROG) has pursued an extensive Quality Assurance (QA) program involving all centres actively participating in its clinical research. The first step is the evaluation of the structure and of the human, technical and organisational resources of the centres, to assess their ability to comply with the current requirements for high-tech radiotherapy (RT). Materials and methods: A facility questionnaire (FQ) was developed in 1989 and adapted over the years to match the evolution of RT techniques. We report on the contents of the current FQ that was completed online by 98 active EORTC ROG member institutions from 19 countries, between December 2005 and October 2007. Results: Similar to the data collected previously, large variations in equipment, staffing and workload between centres remain. Currently only 15 centres still use a Cobalt unit. All centres perform 3D Conformal RT, 79% of them can perform IMRT and 54% are able to deliver stereotactic RT. An external reference dosimetry audit (ERDA) was performed in 88% of the centres for photons and in 73% for electrons, but it was recent (<2 years) in only 74% and 60%, respectively. Conclusion: The use of the FQ helps maintain the minimum quality requirements within the EORTC ROG network: recommendations are made on the basis of the analysis of its results. The present analysis shows that modern RT techniques are widely implemented in the clinic but also that ERDA should be performed more frequently. Repeated assessment using the FQ is warranted to document the future evolution of the EORTC ROG institutions

  12. The Radiation Therapy Oncology in the context of oncological practice

    International Nuclear Information System (INIS)

    Kasdorf, P.

    2010-01-01

    This work is about the radiation therapy oncology in the context of oncological practice. The radiotherapy is a speciality within medicine that involves the generation, application and dissemination of knowledge about the biology, causes, prevention and treatment of the cancer and other pathologies by ionising radiation

  13. SU-F-T-247: Collision Risks in a Modern Radiation Oncology Department: An Efficient Approach to Failure Modes and Effects Analysis

    Energy Technology Data Exchange (ETDEWEB)

    Schubert, L; Westerly, D; Vinogradskiy, Y; Fisher, C; Liu, A [University of Colorado Denver, Aurora, CO (United States); Aldridge, J [University of Colorado Hospital, Aurora, CO (United States)

    2016-06-15

    Purpose: Collisions between treatment equipment and patients are potentially catastrophic. Modern technology now commonly involves automated remote motion during imaging and treatment, yet a systematic assessment to identify and mitigate collision risks has yet to be performed. Failure modes and effects analysis (FMEA) is a method of risk assessment that has been increasingly used in healthcare, yet can be resource intensive. This work presents an efficient approach to FMEA to identify collision risks and implement practical interventions within a modern radiation therapy department. Methods: Potential collisions (e.g. failure modes) were assessed for all treatment and simulation rooms by teams consisting of physicists, therapists, and radiation oncologists. Failure modes were grouped into classes according to similar characteristics. A single group meeting was held to identify implementable interventions for the highest priority classes of failure modes. Results: A total of 60 unique failure modes were identified by 6 different teams of physicists, therapists, and radiation oncologists. Failure modes were grouped into four main classes: specific patient setups, automated equipment motion, manual equipment motion, and actions in QA or service mode. Two of these classes, unusual patient setups and automated machine motion, were identified as being high priority in terms severity of consequence and addressability by interventions. The two highest risk classes consisted of 33 failure modes (55% of the total). In a single one hour group meeting, 6 interventions were identified. Those interventions addressed 100% of the high risk classes of failure modes (55% of all failure modes identified). Conclusion: A class-based approach to FMEA was developed to efficiently identify collision risks and implement interventions in a modern radiation oncology department. Failure modes and interventions will be listed, and a comparison of this approach against traditional FMEA methods

  14. SU-F-T-247: Collision Risks in a Modern Radiation Oncology Department: An Efficient Approach to Failure Modes and Effects Analysis

    International Nuclear Information System (INIS)

    Schubert, L; Westerly, D; Vinogradskiy, Y; Fisher, C; Liu, A; Aldridge, J

    2016-01-01

    Purpose: Collisions between treatment equipment and patients are potentially catastrophic. Modern technology now commonly involves automated remote motion during imaging and treatment, yet a systematic assessment to identify and mitigate collision risks has yet to be performed. Failure modes and effects analysis (FMEA) is a method of risk assessment that has been increasingly used in healthcare, yet can be resource intensive. This work presents an efficient approach to FMEA to identify collision risks and implement practical interventions within a modern radiation therapy department. Methods: Potential collisions (e.g. failure modes) were assessed for all treatment and simulation rooms by teams consisting of physicists, therapists, and radiation oncologists. Failure modes were grouped into classes according to similar characteristics. A single group meeting was held to identify implementable interventions for the highest priority classes of failure modes. Results: A total of 60 unique failure modes were identified by 6 different teams of physicists, therapists, and radiation oncologists. Failure modes were grouped into four main classes: specific patient setups, automated equipment motion, manual equipment motion, and actions in QA or service mode. Two of these classes, unusual patient setups and automated machine motion, were identified as being high priority in terms severity of consequence and addressability by interventions. The two highest risk classes consisted of 33 failure modes (55% of the total). In a single one hour group meeting, 6 interventions were identified. Those interventions addressed 100% of the high risk classes of failure modes (55% of all failure modes identified). Conclusion: A class-based approach to FMEA was developed to efficiently identify collision risks and implement interventions in a modern radiation oncology department. Failure modes and interventions will be listed, and a comparison of this approach against traditional FMEA methods

  15. Biophysical models in radiation oncology

    International Nuclear Information System (INIS)

    Cohen, L.

    1984-01-01

    The paper examines and describes dose-time relationships in clinical radiation oncology. Realistic models and parameters for specific tissues, organs, and tumor types are discussed in order to solve difficult problems which arise in radiation oncology. The computer programs presented were written to: derive parameters from experimental and clinical data; plot normal- and tumor-cell survival curves; generate iso-effect tables of tumor-curative doses; identify alternative, equally effective procedures for fraction numbers and treatment times; determine whether a proposed course of treatment is safe and adequate, and what adjustments are needed should results suggest that the procedure is unsafe or inadequate; combine the physical isodose distribution with computed cellular surviving fractions for the tumor and all normal tissues traversed by the beam, estimating the risks of recurrence or complications at various points in the irradiated volume, and adjusting the treatment plan and fractionation scheme to minimize these risks

  16. Female Representation in the Academic Oncology Physician Workforce: Radiation Oncology Losing Ground to Hematology Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Ahmed, Awad A. [Sylvester Comprehensive Cancer Center University of Miami Health System, Miami, Florida (United States); Hwang, Wei-Ting [Department of Biostatistics and Epidemiology, University of Pennsylvania, Philadelphia, Pennsylvania (United States); Holliday, Emma B. [Division of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Chapman, Christina H.; Jagsi, Reshma [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Thomas, Charles R. [Department of Radiation Medicine, Knight Cancer Institute, Oregon Health & Science University, Portland, Oregon (United States); Deville, Curtiland, E-mail: cdeville@jhmi.edu [Department of Radiation Oncology and Molecular Radiation Sciences, Johns Hopkins University, Baltimore, Maryland (United States)

    2017-05-01

    Purpose: Our purpose was to assess comparative female representation trends for trainees and full-time faculty in the academic radiation oncology and hematology oncology workforce of the United States over 3 decades. Methods and Materials: Simple linear regression models with year as the independent variable were used to determine changes in female percentage representation per year and associated 95% confidence intervals for trainees and full-time faculty in each specialty. Results: Peak representation was 48.4% (801/1654) in 2013 for hematology oncology trainees, 39.0% (585/1499) in 2014 for hematology oncology full-time faculty, 34.8% (202/581) in 2007 for radiation oncology trainees, and 27.7% (439/1584) in 2015 for radiation oncology full-time faculty. Representation significantly increased for trainees and full-time faculty in both specialties at approximately 1% per year for hematology oncology trainees and full-time faculty and 0.3% per year for radiation oncology trainees and full-time faculty. Compared with radiation oncology, the rates were 3.84 and 2.94 times greater for hematology oncology trainees and full-time faculty, respectively. Conclusion: Despite increased female trainee and full-time faculty representation over time in the academic oncology physician workforce, radiation oncology is lagging behind hematology oncology, with trainees declining in recent years in radiation oncology; this suggests a de facto ceiling in female representation. Whether such issues as delayed or insufficient exposure, inadequate mentorship, or specialty competitiveness disparately affect female representation in radiation oncology compared to hematology oncology are underexplored and require continued investigation to ensure that the future oncologic physician workforce reflects the diversity of the population it serves.

  17. Female Representation in the Academic Oncology Physician Workforce: Radiation Oncology Losing Ground to Hematology Oncology

    International Nuclear Information System (INIS)

    Ahmed, Awad A.; Hwang, Wei-Ting; Holliday, Emma B.; Chapman, Christina H.; Jagsi, Reshma; Thomas, Charles R.; Deville, Curtiland

    2017-01-01

    Purpose: Our purpose was to assess comparative female representation trends for trainees and full-time faculty in the academic radiation oncology and hematology oncology workforce of the United States over 3 decades. Methods and Materials: Simple linear regression models with year as the independent variable were used to determine changes in female percentage representation per year and associated 95% confidence intervals for trainees and full-time faculty in each specialty. Results: Peak representation was 48.4% (801/1654) in 2013 for hematology oncology trainees, 39.0% (585/1499) in 2014 for hematology oncology full-time faculty, 34.8% (202/581) in 2007 for radiation oncology trainees, and 27.7% (439/1584) in 2015 for radiation oncology full-time faculty. Representation significantly increased for trainees and full-time faculty in both specialties at approximately 1% per year for hematology oncology trainees and full-time faculty and 0.3% per year for radiation oncology trainees and full-time faculty. Compared with radiation oncology, the rates were 3.84 and 2.94 times greater for hematology oncology trainees and full-time faculty, respectively. Conclusion: Despite increased female trainee and full-time faculty representation over time in the academic oncology physician workforce, radiation oncology is lagging behind hematology oncology, with trainees declining in recent years in radiation oncology; this suggests a de facto ceiling in female representation. Whether such issues as delayed or insufficient exposure, inadequate mentorship, or specialty competitiveness disparately affect female representation in radiation oncology compared to hematology oncology are underexplored and require continued investigation to ensure that the future oncologic physician workforce reflects the diversity of the population it serves.

  18. Female Representation in the Academic Oncology Physician Workforce: Radiation Oncology Losing Ground to Hematology Oncology.

    Science.gov (United States)

    Ahmed, Awad A; Hwang, Wei-Ting; Holliday, Emma B; Chapman, Christina H; Jagsi, Reshma; Thomas, Charles R; Deville, Curtiland

    2017-05-01

    Our purpose was to assess comparative female representation trends for trainees and full-time faculty in the academic radiation oncology and hematology oncology workforce of the United States over 3 decades. Simple linear regression models with year as the independent variable were used to determine changes in female percentage representation per year and associated 95% confidence intervals for trainees and full-time faculty in each specialty. Peak representation was 48.4% (801/1654) in 2013 for hematology oncology trainees, 39.0% (585/1499) in 2014 for hematology oncology full-time faculty, 34.8% (202/581) in 2007 for radiation oncology trainees, and 27.7% (439/1584) in 2015 for radiation oncology full-time faculty. Representation significantly increased for trainees and full-time faculty in both specialties at approximately 1% per year for hematology oncology trainees and full-time faculty and 0.3% per year for radiation oncology trainees and full-time faculty. Compared with radiation oncology, the rates were 3.84 and 2.94 times greater for hematology oncology trainees and full-time faculty, respectively. Despite increased female trainee and full-time faculty representation over time in the academic oncology physician workforce, radiation oncology is lagging behind hematology oncology, with trainees declining in recent years in radiation oncology; this suggests a de facto ceiling in female representation. Whether such issues as delayed or insufficient exposure, inadequate mentorship, or specialty competitiveness disparately affect female representation in radiation oncology compared to hematology oncology are underexplored and require continued investigation to ensure that the future oncologic physician workforce reflects the diversity of the population it serves. Copyright © 2017 Elsevier Inc. All rights reserved.

  19. Patient satisfaction in radiation oncology

    International Nuclear Information System (INIS)

    Zissiadis, Y.; Provis, A.; Dhaliwal, S.S.

    2003-01-01

    In this current economic climate where the costs of providing a good medical service are escalating, patients are demanding a higher level of service from the Radiation Oncology providers. This coupled with the rising level of patients' expectations make it absolutely paramount for Radiation Oncology providers to offer the best possible service to their patients. In order to do this, it is essential to assess the present level of patient satisfaction prior to deciding which aspects of the current service need to be changed. In this pilot study, we assess the level of patient satisfaction with aspects of the radiotherapy service and the level of patient anxiety both prior to and following radiotherapy at the Perth Radiation Oncology Centre. A questionnaire was created using a combination of the Information Satisfaction Questionnaire-1 (ISQ-1), the Very Short Questionnaire 9 (VSQ 9) and the State Trait Anxiety Index (STAI). One hundred new patients were studied, all of whom were to have radiotherapy with curative intent. The results of this study are reviewed in this presentation

  20. 78 FR 25304 - Siemens Medical Solutions, USA, Inc., Oncology Care Systems (Radiation Oncology), Including On...

    Science.gov (United States)

    2013-04-30

    ..., USA, Inc., Oncology Care Systems (Radiation Oncology), Including On-Site Leased Workers From Source... Medical Solutions, USA, Inc., Oncology Care Systems (Radiation Oncology), including on- site leased... of February 2013, Siemens Medical Solutions, USA, Inc., Oncology Care Systems (Radiation Oncology...

  1. The Influence of Organizational Commitment, Job Commitment and Job Satisfaction on Professionalism Perceived by Radiotechnologists Working in the Department of Radiation Oncology

    International Nuclear Information System (INIS)

    Gim, Yang Soo; Lee, Sun Young; Lee, Joon Seong; Gwak, Geun Tak; Park, Ju Gyeong; Lee, Seung Hoon; Hwang, Ho In; Cha, Seok Yong

    2012-01-01

    The study is to check the specialty of radiotherapists working in the department of radiation oncology and find job satisfaction, organizational commitment and job commitment having an effect on professional parts. After making analysis of the mutual relation, it is to provide radiotechnologists with making progress in the future. From March 2 to March 30, we had carried out a survey with email. It is possible to have 272 questionnaires answered in the survey. We make use of SPSS 13.0 for Windows to analyze the data collected for study. Frequency and a percentage are meant to show general characteristics, and t-test and ANOVA to do the difference between general properties and professionalism. Pearson's correlation coefficient also is meant to do the correlation of professionalism, organizational job commitment and job satisfaction, and multiple regression analysis to do the factor for a relevant variable to affect professionalism. There are subdivisions in the professionalism informing us of the self-regulation 17.74±2.32/3.55±46, a sense of calling 17.58±2.63/3.52±53, reference of the professional 17.14±2.39/3.43±48, service to the public 15.97±2.48/3.19±50, and autonomy 15.68±2.28/3.14±46. Grand mean turns out to be 83.89±7.63(Summation of items)/ 3.37±0.49(Numbers of items). When it comes to a statistical relation between general characteristics and professionalism, the statistics have it that these come within age (P 2 is 0.504. The results of the factors that influence professionalism working as radiotherapists in the department of radiation oncology have it that the more affective commitment, normative commitment, and job satisfaction we feel, the more professionalism we recognize. We think that the focus of professionalism is increased if getting the chances for radiotherapists to have little to do with developing opportunities given.

  2. Continuing medical education in radiation oncology

    International Nuclear Information System (INIS)

    Chauvet, B.; Barillot, I.; Denis, F.; Cailleux, P.E.; Ardiet, J.M.; Mornex, F.

    2012-01-01

    In France, continuing medical education (CME) and professional practice evaluation (PPE) became mandatory by law in July 2009 for all health professionals. Recently published decrees led to the creation of national specialty councils to implement this organizational device. For radiation oncology, this council includes the French Society for Radiation Oncology (SFRO), the National Radiation Oncology Syndicate (SNRO) and the Association for Continuing Medical Education in Radiation Oncology (AFCOR). The Radiation Oncology National Council will propose a set of programs including CME and PPE, professional thesaurus, labels for CME actions consistent with national requirements, and will organize expertise for public instances. AFCOR remains the primary for CME, but each practitioner can freely choose an organisation for CME, provided that it is certified by the independent scientific commission. The National Order for physicians is the control authority. Radiation oncology has already a strong tradition of independent CME that will continue through this major reform. (authors)

  3. Supportive care in radiation oncology

    International Nuclear Information System (INIS)

    Rotman, M.; John, M.

    1987-01-01

    The radiation therapist, concerned with the disease process and all the technical intricacies of treatment, has usually not been involved in managing the supportive aspects of caring for the patient. Yet, of the team of medical specialists and allied health personnel required in oncology, the radiation therapist is the one most responsible for overseeing the total care of the cancer patient. At times this might include emotional support, prevention and correction of tissue dysfunction, augmentation of nutrition, metabolic and electrolyte regulation, rehabilitation, and vocational support. This chapter is a brief overview of a considerable volume of literature that has occupied the interest of a rather small group of physicians, nutritionists, and psychologists. The discussion highlights the special management problems of the normal-tissue effects of radiation, the related nutritional aspects of cancer care, and certain emotional and pathologic considerations

  4. Preclinical models in radiation oncology

    Directory of Open Access Journals (Sweden)

    Kahn Jenna

    2012-12-01

    Full Text Available Abstract As the incidence of cancer continues to rise, the use of radiotherapy has emerged as a leading treatment modality. Preclinical models in radiation oncology are essential tools for cancer research and therapeutics. Various model systems have been used to test radiation therapy, including in vitro cell culture assays as well as in vivo ectopic and orthotopic xenograft models. This review aims to describe such models, their advantages and disadvantages, particularly as they have been employed in the discovery of molecular targets for tumor radiosensitization. Ultimately, any model system must be judged by its utility in developing more effective cancer therapies, which is in turn dependent on its ability to simulate the biology of tumors as they exist in situ. Although every model has its limitations, each has played a significant role in preclinical testing. Continued advances in preclinical models will allow for the identification and application of targets for radiation in the clinic.

  5. [Oncological emergencies in the emergency department].

    Science.gov (United States)

    Cimpoeşu, Diana; Dumea, Mihaela; Durchi, Simona; Apostoae, F; Olaru, G; Ciolan, Mioara; Popa, O; Corlade-Andrei, Mihaela

    2011-01-01

    to assess the profile and the characteristic of oncological patients, establishing management in patients with neoplasia presented in the emergency department (ED), the analysis of short-term movements in patients with neoplasia whilst in the ED. we performed a retrospective study on nonrandomized consecutive cases. The lot analysis included 1315 oncological patients admitted in the Emergency Department of the Clinical Emergency Hospital "St. Spiridon" Iaşi, in the period June 1st, 2009 - May 31st, 2010. 23.12% of the patients had high suspicion of neoplasia at the first visit to the ED. 67.07% of patients were in metastatic stage disease located as follows: liver metastasis 37.59%, lung metastasis 18.36%, lymph node metastasis 13, 29%. After processing the data there were found statistically significant correlations between the age of patients and the documented/suspected diagnosis of neoplasia (p = 0.01) in the sense that a neoplasia diagnosis in emergency was more frequent in people of young age. It should be mentioned that other studies rarely mention first diagnosis of neoplasia in emergency department with presence of complications. 1315 oncological patients presented in ED, almost a quarter of which presented high suspicion of neoplasia (still without histopathological confirmation) when in ED (23.12%). Most of them were aged male patients (over 65 years old), with tumors of the digestive system. A significant proportion (almost 60%) of these patients ended up in emergency due to complications and the therapy intended life support and pain management. Some of these patients were directed to further exploring and emergency outpatient therapy while 75% of patients were hospitalized after stabilization. Although we expected that the frequency of complications to be higher in patients previously diagnosed with cancer, data analysis showed no statistically significant differences (p = NS) between the rate of complications in patients previously diagnosed with

  6. Exploring the role of educational videos in radiation oncology practice

    International Nuclear Information System (INIS)

    Dally, M.J.; Denham, J.W.; Boddy, G.A.

    1994-01-01

    Patient, staff, and medical student education are essential components of modern radiation oncology practice. Greater involvement of patients in the clinical decision-making process, and the need for other health professionals to be more informed about radiation oncology, provided further demand on resources, despite ever increasing logistic constraints. Videos made by individual departments may augment traditional teaching methods and have applications in documenting clinical practice and response. 8 refs., 1 tab

  7. Future directions in radiation oncology

    International Nuclear Information System (INIS)

    Peters, L.

    1996-01-01

    Full text: Cancer treatment has evolved progressively over the years as a joint result of improvements in technology and better understanding of the biological responses of neoplastic and normal cells to cytotoxic agents. Although major therapeutic 'breakthroughs' are unlikely absent the discovery of exploitable fundamental differences between cancer cells and their normal homologs, further incremental improvements in cancer treatment results can confidently be expected as we apply existing knowledge better and take advantage of new research insights. Areas in which I can foresee significant improvements (in approximate chronological order) are as follows: better physical radiation dose distributions; more effective radiation and chemoradiation protocols based on radiobiological principles; more rational use of radiation adjuvants based on biologic criteria; use of novel targets and vectors for systemic radionuclide therapy; use of genetic markers of radiosensitivity to determine radiation dose tolerances; and use of radiation as a modulator of therapeutic gene expression. Radiation research has contributed greatly to the efficacy of radiation oncology as it is now practised but has even greater potential for the future

  8. Radiation oncology: a primer for medical students.

    Science.gov (United States)

    Berman, Abigail T; Plastaras, John P; Vapiwala, Neha

    2013-09-01

    Radiation oncology requires a complex understanding of cancer biology, radiation physics, and clinical care. This paper equips the medical student to understand the fundamentals of radiation oncology, first with an introduction to cancer treatment and the use of radiation therapy. Considerations during radiation oncology consultations are discussed extensively with an emphasis on how to formulate an assessment and plan including which treatment modality to use. The treatment planning aspects of radiation oncology are then discussed with a brief introduction to how radiation works, followed by a detailed explanation of the nuances of simulation, including different imaging modalities, immobilization, and accounting for motion. The medical student is then instructed on how to participate in contouring, plan generation and evaluation, and the delivery of radiation on the machine. Lastly, potential adverse effects of radiation are discussed with a particular focus on the on-treatment patient.

  9. The Influence of Organizational Commitment, Job Commitment and Job Satisfaction on Professionalism Perceived by Radiotechnologists Working in the Department of Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Gim, Yang Soo; Lee, Sun Young; Lee, Joon Seong; Gwak, Geun Tak; Park, Ju Gyeong; Lee, Seung Hoon; Hwang, Ho In; Cha, Seok Yong [Dept. of Radiation Oncology, Chunbuk National University Hospital, Jeonju (Korea, Republic of)

    2012-09-15

    The study is to check the specialty of radiotherapists working in the department of radiation oncology and find job satisfaction, organizational commitment and job commitment having an effect on professional parts. After making analysis of the mutual relation, it is to provide radiotechnologists with making progress in the future. From March 2 to March 30, we had carried out a survey with email. It is possible to have 272 questionnaires answered in the survey. We make use of SPSS 13.0 for Windows to analyze the data collected for study. Frequency and a percentage are meant to show general characteristics, and t-test and ANOVA to do the difference between general properties and professionalism. Pearson's correlation coefficient also is meant to do the correlation of professionalism, organizational job commitment and job satisfaction, and multiple regression analysis to do the factor for a relevant variable to affect professionalism. There are subdivisions in the professionalism informing us of the self-regulation 17.74{+-}2.32/3.55{+-}46, a sense of calling 17.58{+-}2.63/3.52{+-}53, reference of the professional 17.14{+-}2.39/3.43{+-}48, service to the public 15.97{+-}2.48/3.19{+-}50, and autonomy 15.68{+-}2.28/3.14{+-}46. Grand mean turns out to be 83.89{+-}7.63(Summation of items)/ 3.37{+-}0.49(Numbers of items). When it comes to a statistical relation between general characteristics and professionalism, the statistics have it that these come within age (P<.001), period of employment (P<.001), education status (P<.05), a monthly income (P<.001), radiotherapists who get a special license (P<.001), the position (P<.001), and an opportunity for developing (P<.001). As a result of organizational commitment, job commitment, and job satisfaction, grand mean in organizational commitment proves to be 81.10{+-}8.15/3.34{+-}34. There are subvisions showing affective commitment 28.64{+-}4.61/3.58, continuance commitment 27.54{+-}4.22/3.44{+-}53, and normative commitment

  10. National Institutes of Health Funding in Radiation Oncology: A Snapshot

    Energy Technology Data Exchange (ETDEWEB)

    Steinberg, Michael; McBride, William H.; Vlashi, Erina [Department of Radiation Oncology, David Geffen School of Medicine at University of California, Los Angeles (UCLA), and Jonsson Comprehensive Cancer Center at UCLA, Los Angeles, California (United States); Pajonk, Frank, E-mail: fpajonk@mednet.ucla.edu [Department of Radiation Oncology, David Geffen School of Medicine at University of California, Los Angeles (UCLA), and Jonsson Comprehensive Cancer Center at UCLA, Los Angeles, California (United States)

    2013-06-01

    Currently, pay lines for National Institutes of Health (NIH) grants are at a historical low. In this climate of fierce competition, knowledge about the funding situation in a small field like radiation oncology becomes very important for career planning and recruitment of faculty. Unfortunately, these data cannot be easily extracted from the NIH's database because it does not discriminate between radiology and radiation oncology departments. At the start of fiscal year 2013 we extracted records for 952 individual grants, which were active at the time of analysis from the NIH database. Proposals originating from radiation oncology departments were identified manually. Descriptive statistics were generated using the JMP statistical software package. Our analysis identified 197 grants in radiation oncology. These proposals came from 134 individual investigators in 43 academic institutions. The majority of the grants (118) were awarded to principal investigators at the full professor level, and 122 principal investigators held a PhD degree. In 79% of the grants, the research topic fell into the field of biology, 13% in the field of medical physics. Only 7.6% of the proposals were clinical investigations. Our data suggest that the field of radiation oncology is underfunded by the NIH and that the current level of support does not match the relevance of radiation oncology for cancer patients or the potential of its academic work force.

  11. NIH funding in Radiation Oncology – A snapshot

    Science.gov (United States)

    Steinberg, Michael; McBride, William H.; Vlashi, Erina; Pajonk, Frank

    2013-01-01

    Currently, pay lines for NIH grants are at a historical low. In this climate of fierce competition knowledge about the funding situation in a small field like Radiation Oncology becomes very important for career planning and recruitment of faculty. Unfortunately, this data cannot be easily extracted from the NIH s database because it does not discriminate between Radiology and Radiation Oncology Departments. At the start of fiscal year 2013, we extracted records for 952 individual grants, which were active at the time of analysis from the NIH database. Proposals originating from Radiation Oncology Departments were identified manually. Descriptive statistics were generated using the JMP statistical software package. Our analysis identified 197 grants in Radiation Oncology. These proposals came from 134 individual investigators in 43 academic institutions. The majority of the grants (118) were awarded to PIs at the Full Professor level and 122 PIs held a PhD degree. In 79% of the grants the research topic fell into the field of Biology, in 13 % into the field of Medical Physics. Only 7.6% of the proposals were clinical investigations. Our data suggests that the field of Radiation Oncology is underfunded by the NIH, and that the current level of support does not match the relevance of Radiation Oncology for cancer patients or the potential of its academic work force. PMID:23523324

  12. National Institutes of Health Funding in Radiation Oncology: A Snapshot

    International Nuclear Information System (INIS)

    Steinberg, Michael; McBride, William H.; Vlashi, Erina; Pajonk, Frank

    2013-01-01

    Currently, pay lines for National Institutes of Health (NIH) grants are at a historical low. In this climate of fierce competition, knowledge about the funding situation in a small field like radiation oncology becomes very important for career planning and recruitment of faculty. Unfortunately, these data cannot be easily extracted from the NIH's database because it does not discriminate between radiology and radiation oncology departments. At the start of fiscal year 2013 we extracted records for 952 individual grants, which were active at the time of analysis from the NIH database. Proposals originating from radiation oncology departments were identified manually. Descriptive statistics were generated using the JMP statistical software package. Our analysis identified 197 grants in radiation oncology. These proposals came from 134 individual investigators in 43 academic institutions. The majority of the grants (118) were awarded to principal investigators at the full professor level, and 122 principal investigators held a PhD degree. In 79% of the grants, the research topic fell into the field of biology, 13% in the field of medical physics. Only 7.6% of the proposals were clinical investigations. Our data suggest that the field of radiation oncology is underfunded by the NIH and that the current level of support does not match the relevance of radiation oncology for cancer patients or the potential of its academic work force

  13. National Institutes of Health funding in radiation oncology: a snapshot.

    Science.gov (United States)

    Steinberg, Michael; McBride, William H; Vlashi, Erina; Pajonk, Frank

    2013-06-01

    Currently, pay lines for National Institutes of Health (NIH) grants are at a historical low. In this climate of fierce competition, knowledge about the funding situation in a small field like radiation oncology becomes very important for career planning and recruitment of faculty. Unfortunately, these data cannot be easily extracted from the NIH's database because it does not discriminate between radiology and radiation oncology departments. At the start of fiscal year 2013 we extracted records for 952 individual grants, which were active at the time of analysis from the NIH database. Proposals originating from radiation oncology departments were identified manually. Descriptive statistics were generated using the JMP statistical software package. Our analysis identified 197 grants in radiation oncology. These proposals came from 134 individual investigators in 43 academic institutions. The majority of the grants (118) were awarded to principal investigators at the full professor level, and 122 principal investigators held a PhD degree. In 79% of the grants, the research topic fell into the field of biology, 13% in the field of medical physics. Only 7.6% of the proposals were clinical investigations. Our data suggest that the field of radiation oncology is underfunded by the NIH and that the current level of support does not match the relevance of radiation oncology for cancer patients or the potential of its academic work force. Copyright © 2013 Elsevier Inc. All rights reserved.

  14. Internet utilization by radiation oncology patients

    International Nuclear Information System (INIS)

    Metz, J.M.; Devine, P.; DeNittis, A.; Stambaugh, M.; Jones, H.; Goldwein, J.; Whittington, R.

    2001-01-01

    Purpose: Studies describing the use of the Internet by radiation oncology patients are lacking. This multi-institutional study of cancer patients presenting to academic (AC), community (CO) and veterans (VA) radiation oncology centers was designed to analyze the use of the Internet, predictive factors for utilization, and barriers to access to the Internet. Materials and Methods: A questionnaire evaluating the use of the Internet was administered to 921 consecutive patients presenting to radiation oncology departments at AC, CO and VA Medical Centers. The study included 436 AC patients (47%), 284 CO patients (31%), and 201 VA patients (22%). A computer was available at home to 427 patients (46%) and 337 patients (37%) had Email access. The mean age of the patient population was 64 years (range=14-93). Males represented 70% of the patient population. The most common diagnoses included prostate cancer (33%), breast cancer (13%), and lung cancer (11%). Results: Overall, 265/921 patients (29%) were using the Internet to find cancer related information. The Internet was used by 42% of AC patients, 25% of CO patients and only 5% of VA patients (p<.0001). A computer was available at home in 62% AC vs. 45% CO vs. 12% VA patients (p<.0001). Patients < 60 years were much more likely to use the Internet than older patients (p<.0001). Most of the Internet users considered the information either very reliable (22%) or somewhat reliable (70%). Most patients were looking for information regarding treatment of their cancer (90%), management of side effects of treatment (74%), alternative/complementary treatments (65%) and clinical trials (51%). Unconventional medical therapies were purchased over the Internet by 12% of computer users. Products or services for the treatment or management of cancer were purchased online by 12% of Internet users. Conclusion: A significant number of cancer patients seen in radiation oncology departments at academic and community medical centers

  15. Clinical and Radiation Oncology. Vol. 1

    International Nuclear Information System (INIS)

    Jurga, L.; Adam, Z.; Autrata, R.

    2010-01-01

    The work is two-volume set and has 1,658 pages. It is divided into 5 sections: I. Principles Clinical and radiation oncology. II. Hematological Malignant tumors. III. Solid tumors. IV. Treatment options metastatic Disease. V. Clinical practice in oncology. First volume contains following sections a chapters: Section I: Principles of clinical and radiation oncology, it contains following chapters: (1) The history of clinical/experimental and radiation oncology in the Czech Republic; (2) The history of clinical/experimental and radiation oncology in the Slovak Republic - development and development of oncology in Slovakia; (3) Clinical and radiation oncology as part of evidence-based medicine; (4) Molecular biology; (5) Tumor Disease; (6) Epidemiology and prevention of malignant tumors; (7) Diagnosis, staging, stratification and monitoring of patients in oncology; (8) Imaging methods in oncology; (9) Principles of surgical treatment of cancer diseases; (10) Symptomatology and signaling of malignant tumors - systemic, paraneoplastic and paraendocrine manifestations of tumor diseases; (11) Principles of radiation oncology; (12 Modeling radiobiological effects of radiotherapy; (13) Principles of anticancer chemotherapy; (14) Hormonal manipulation in the treatment of tumors; (15) Principles of biological and targeted treatment of solid tumors; (16) Method of multimodal therapy of malignant tumors; (17) Evaluation of treatment response, performance evaluation criteria (RECIST); (18) Adverse effects of cancer chemotherapy and the principles of their prevention and treatment; (19) Biological principles of hematopoietic stem cell transplantation; (20) Design, analysis and ethical aspects of clinical studies in oncology; (21) Fundamentals of biostatistics for oncologists; (22) Information infrastructure for clinical and radiological oncology based on evidence; (23) Pharmacoeconomic aspects in oncology; (24) Respecting patient preferences when deciding on the strategy and

  16. Labeling for Big Data in radiation oncology: The Radiation Oncology Structures ontology.

    Science.gov (United States)

    Bibault, Jean-Emmanuel; Zapletal, Eric; Rance, Bastien; Giraud, Philippe; Burgun, Anita

    2018-01-01

    Leveraging Electronic Health Records (EHR) and Oncology Information Systems (OIS) has great potential to generate hypotheses for cancer treatment, since they directly provide medical data on a large scale. In order to gather a significant amount of patients with a high level of clinical details, multicenter studies are necessary. A challenge in creating high quality Big Data studies involving several treatment centers is the lack of semantic interoperability between data sources. We present the ontology we developed to address this issue. Radiation Oncology anatomical and target volumes were categorized in anatomical and treatment planning classes. International delineation guidelines specific to radiation oncology were used for lymph nodes areas and target volumes. Hierarchical classes were created to generate The Radiation Oncology Structures (ROS) Ontology. The ROS was then applied to the data from our institution. Four hundred and seventeen classes were created with a maximum of 14 children classes (average = 5). The ontology was then converted into a Web Ontology Language (.owl) format and made available online on Bioportal and GitHub under an Apache 2.0 License. We extracted all structures delineated in our department since the opening in 2001. 20,758 structures were exported from our "record-and-verify" system, demonstrating a significant heterogeneity within a single center. All structures were matched to the ROS ontology before integration into our clinical data warehouse (CDW). In this study we describe a new ontology, specific to radiation oncology, that reports all anatomical and treatment planning structures that can be delineated. This ontology will be used to integrate dosimetric data in the Assistance Publique-Hôpitaux de Paris CDW that stores data from 6.5 million patients (as of February 2017).

  17. Establishment of Database System for Radiation Oncology

    International Nuclear Information System (INIS)

    Kim, Dae Sup; Lee, Chang Ju; Yoo, Soon Mi; Kim, Jong Min; Lee, Woo Seok; Kang, Tae Young; Back, Geum Mun; Hong, Dong Ki; Kwon, Kyung Tae

    2008-01-01

    To enlarge the efficiency of operation and establish a constituency for development of new radiotherapy treatment through database which is established by arranging and indexing radiotherapy related affairs in well organized manner to have easy access by the user. In this study, Access program provided by Microsoft (MS Office Access) was used to operate the data base. The data of radiation oncology was distinguished by a business logs and maintenance expenditure in addition to stock management of accessories with respect to affairs and machinery management. Data for education and research was distinguished by education material for department duties, user manual and related thesis depending upon its property. Registration of data was designed to have input form according to its subject and the information of data was designed to be inspected by making a report. Number of machine failure in addition to its respective repairing hours from machine maintenance expenditure in a period of January 2008 to April 2009 was analyzed with the result of initial system usage and one year after the usage. Radiation oncology database system was accomplished by distinguishing work related and research related criteria. The data are arranged and collected according to its subjects and classes, and can be accessed by searching the required data through referring the descriptions from each criteria. 32.3% of total average time was reduced on analyzing repairing hours by acquiring number of machine failure in addition to its type in a period of January 2008 to April 2009 through machine maintenance expenditure. On distinguishing and indexing present and past data upon its subjective criteria through the database system for radiation oncology, the use of information can be easily accessed to enlarge the efficiency of operation, and in further, can be a constituency for improvement of work process by acquiring various information required for new radiotherapy treatment in real time.

  18. Artificial Intelligence in Medicine and Radiation Oncology.

    Science.gov (United States)

    Weidlich, Vincent; Weidlich, Georg A

    2018-04-13

    Artifical Intelligence (AI) was reviewed with a focus on its potential applicability to radiation oncology. The improvement of process efficiencies and the prevention of errors were found to be the most significant contributions of AI to radiation oncology. It was found that the prevention of errors is most effective when data transfer processes were automated and operational decisions were based on logical or learned evaluations by the system. It was concluded that AI could greatly improve the efficiency and accuracy of radiation oncology operations.

  19. Practicing radiation oncology in the current health care environment - Part III: Information systems for radiation oncology practice

    International Nuclear Information System (INIS)

    Kijewski, Peter

    1996-01-01

    Purpose: This course will review topics to be considered when defining an information systems plan for a department of radiation oncology. A survey of available systems will be presented. Computer information systems can play an important role in the effective administration and operation of a department of radiation oncology. Tasks such as 1) scheduling for physicians, patients, and rooms, 2) charge collection and billing, 3) administrative reporting, and 4) treatment verification can be carried out efficiently with the assistance of computer systems. Operating a department without a state of art computer system will become increasingly difficult as hospitals and healthcare buyers increasingly rely on computer information technology. Communication of the radiation oncology system with outside systems will thus further enhance the utility of the computer system. The steps for the selection and installation of an information system will be discussed: 1) defining the objectives, 2) selecting a suitable system, 3) determining costs, 4) setting up maintenance contracts, and 5) planning for future upgrades

  20. Results of the Association of Directors of Radiation Oncology Programs (ADROP) Survey of Radiation Oncology Residency Program Directors

    International Nuclear Information System (INIS)

    Harris, Eleanor; Abdel-Wahab, May; Spangler, Ann E.; Lawton, Colleen A.; Amdur, Robert J.

    2009-01-01

    Purpose: To survey the radiation oncology residency program directors on the topics of departmental and institutional support systems, residency program structure, Accreditation Council for Graduate Medical Education (ACGME) requirements, and challenges as program director. Methods: A survey was developed and distributed by the leadership of the Association of Directors of Radiation Oncology Programs to all radiation oncology program directors. Summary statistics, medians, and ranges were collated from responses. Results: Radiation oncology program directors had implemented all current required aspects of the ACGME Outcome Project into their training curriculum. Didactic curricula were similar across programs nationally, but research requirements and resources varied widely. Program directors responded that implementation of the ACGME Outcome Project and the external review process were among their greatest challenges. Protected time was the top priority for program directors. Conclusions: The Association of Directors of Radiation Oncology Programs recommends that all radiation oncology program directors have protected time and an administrative stipend to support their important administrative and educational role. Departments and institutions should provide adequate and equitable resources to the program directors and residents to meet increasingly demanding training program requirements.

  1. Natural background radiation and oncologic disease incidence

    International Nuclear Information System (INIS)

    Burenin, P.I.

    1982-01-01

    Cause and effect relationships between oncologic disease incidence in human population and environmental factors are examined using investigation materials of Soviet and foreign authors. The data concerning US white population are adduced. The role and contribution of natural background radiation oncologic disease prevalence have been determined with the help of system information analysis. The probable damage of oncologic disease is shown to decrease as the background radiation level diminishes. The linear nature of dose-response relationspip has been established. The necessity to include the life history of the studied population along with environmental factors in epidemiological study under conditions of multiplicity of cancerogenesis causes is emphasized

  2. 2003 survey of Canadian radiation oncology residents

    International Nuclear Information System (INIS)

    Yee, Don; Fairchild, Alysa; Keyes, Mira; Butler, Jim; Dundas, George

    2005-01-01

    Purpose: Radiation oncology's popularity as a career in Canada has surged in the past 5 years. Consequently, resident numbers in Canadian radiation oncology residencies are at all-time highs. This study aimed to survey Canadian radiation oncology residents about their opinions of their specialty and training experiences. Methods and Materials: Residents of Canadian radiation oncology residencies that enroll trainees through the Canadian Resident Matching Service were identified from a national database. Residents were mailed an anonymous survey. Results: Eight of 101 (7.9%) potential respondents were foreign funded. Fifty-two of 101 (51.5%) residents responded. A strong record of graduating its residents was the most important factor residents considered when choosing programs. Satisfaction with their program was expressed by 92.3% of respondents, and 94.3% expressed satisfaction with their specialty. Respondents planning to practice in Canada totaled 80.8%, and 76.9% plan to have academic careers. Respondents identified job availability and receiving adequate teaching from preceptors during residency as their most important concerns. Conclusions: Though most respondents are satisfied with their programs and specialty, job availability and adequate teaching are concerns. In the future, limited time and resources and the continued popularity of radiation oncology as a career will magnify the challenge of training competent radiation oncologists in Canada

  3. Present status and possibilities of radiation oncology

    Energy Technology Data Exchange (ETDEWEB)

    Scherer, E [Essen Univ. (Gesamthochschule) (Germany, F.R.). Strahlenklinik; Essen Univ. (Gesamthochschule) (Germany, F.R.). Poliklinik)

    1979-01-01

    A survey of the current methodical possibilities of radiation therapy within the limits of interdisciplinary oncology is given. Especially new forms of fractionation and current projects to augment the effect of radiation are discussed. The question of fast neutrons, electroaffine substances and local hyperthermia are dealt with.

  4. Clinical oncology based upon radiation biology

    International Nuclear Information System (INIS)

    Hirata, Hideki

    2016-01-01

    This paper discussed the biological effects of radiation as physical energy, especially those of X-ray as electromagnetic radiation, by associating the position of clinical oncology with classical radiation cell biology as well as recent molecular biology. First, it described the physical and biological effects of radiation, cell death due to radiation and recovery, radiation effects at tissue level, and location information and dosage information in the radiotherapy of cancer. It also described the territories unresolved through radiation biology, such as low-dose high-sensitivity, bystander effects, etc. (A.O.)

  5. Contemporary Trends in Radiation Oncology Resident Research

    International Nuclear Information System (INIS)

    Verma, Vivek; Burt, Lindsay; Gimotty, Phyllis A.; Ojerholm, Eric

    2016-01-01

    Purpose: To test the hypothesis that recent resident research productivity might be different than a decade ago, and to provide contemporary information about resident scholarly activity. Methods and Materials: We compiled a list of radiation oncology residents from the 2 most recent graduating classes (June 2014 and 2015) using the Association of Residents in Radiation Oncology annual directories. We queried the PubMed database for each resident's first-authored publications from postgraduate years (PGY) 2 through 5, plus a 3-month period after residency completion. We abstracted corresponding historical data for 2002 to 2007 from the benchmark publication by Morgan and colleagues (Int J Radiat Oncol Biol Phys 2009;74:1567-1572). We tested the null hypothesis that these 2 samples had the same distribution for number of publications using the Wilcoxon rank-sum test. We explored the association of demographic factors and publication number using multivariable zero-inflated Poisson regression. Results: There were 334 residents publishing 659 eligible first-author publications during residency (range 0-17; interquartile range 0-3; mean 2.0; median 1). The contemporary and historical distributions were significantly different (P<.001); contemporary publication rates were higher. Publications accrued late in residency (27% in PGY-4, 59% in PGY-5), and most were original research (75%). In the historical cohort, half of all articles were published in 3 journals; in contrast, the top half of contemporary publications were spread over 10 journals—most commonly International Journal of Radiation Oncology • Biology • Physics (17%), Practical Radiation Oncology (7%), and Radiation Oncology (4%). Male gender, non-PhD status, and larger residency size were associated with higher number of publications in the multivariable analysis. Conclusion: We observed an increase in first-author publications during training compared with historical data from the mid-2000s. These

  6. Contemporary Trends in Radiation Oncology Resident Research

    Energy Technology Data Exchange (ETDEWEB)

    Verma, Vivek [Department of Radiation Oncology, University of Nebraska, Omaha, Nebraska (United States); Burt, Lindsay [Department of Radiation Oncology, University of Utah, Salt Lake City, Utah (United States); Gimotty, Phyllis A. [Department of Biostatistics and Epidemiology, University of Pennsylvania, Philadelphia, Pennsylvania (United States); Ojerholm, Eric, E-mail: eric.ojerholm@uphs.upenn.edu [Department of Radiation Oncology, University of Pennsylvania, Philadelphia, Pennsylvania (United States)

    2016-11-15

    Purpose: To test the hypothesis that recent resident research productivity might be different than a decade ago, and to provide contemporary information about resident scholarly activity. Methods and Materials: We compiled a list of radiation oncology residents from the 2 most recent graduating classes (June 2014 and 2015) using the Association of Residents in Radiation Oncology annual directories. We queried the PubMed database for each resident's first-authored publications from postgraduate years (PGY) 2 through 5, plus a 3-month period after residency completion. We abstracted corresponding historical data for 2002 to 2007 from the benchmark publication by Morgan and colleagues (Int J Radiat Oncol Biol Phys 2009;74:1567-1572). We tested the null hypothesis that these 2 samples had the same distribution for number of publications using the Wilcoxon rank-sum test. We explored the association of demographic factors and publication number using multivariable zero-inflated Poisson regression. Results: There were 334 residents publishing 659 eligible first-author publications during residency (range 0-17; interquartile range 0-3; mean 2.0; median 1). The contemporary and historical distributions were significantly different (P<.001); contemporary publication rates were higher. Publications accrued late in residency (27% in PGY-4, 59% in PGY-5), and most were original research (75%). In the historical cohort, half of all articles were published in 3 journals; in contrast, the top half of contemporary publications were spread over 10 journals—most commonly International Journal of Radiation Oncology • Biology • Physics (17%), Practical Radiation Oncology (7%), and Radiation Oncology (4%). Male gender, non-PhD status, and larger residency size were associated with higher number of publications in the multivariable analysis. Conclusion: We observed an increase in first-author publications during training compared with historical data from the mid-2000s. These

  7. Improving patient safety in radiation oncology

    International Nuclear Information System (INIS)

    Hendee, William R.; Herman, Michael G.

    2011-01-01

    Beginning in the 1990s, and emphasized in 2000 with the release of an Institute of Medicine report, healthcare providers and institutions have dedicated time and resources to reducing errors that impact the safety and well-being of patients. But in January 2010 the first of a series of articles appeared in the New York Times that described errors in radiation oncology that grievously impacted patients. In response, the American Association of Physicists in Medicine and the American Society of Radiation Oncology sponsored a working meeting entitled ''Safety in Radiation Therapy: A Call to Action''. The meeting attracted 400 attendees, including medical physicists, radiation oncologists, medical dosimetrists, radiation therapists, hospital administrators, regulators, and representatives of equipment manufacturers. The meeting was cohosted by 14 organizations in the United States and Canada. The meeting yielded 20 recommendations that provide a pathway to reducing errors and improving patient safety in radiation therapy facilities everywhere.

  8. Clinical and Radiation Oncology. Vol. 2

    International Nuclear Information System (INIS)

    Jurga, L.; Adam, Z.; Autrata, R.

    2010-01-01

    The work is two-volume set and has 1,658 pages. It is divided into 5 sections: I. Principles Clinical and radiation oncology. II. Hematological Malignant tumors. III. Solid tumors. IV. Treatment options metastatic Disease. V. Clinical practice in oncology. Second volume contains following sections a chapters: Section III: Solid nodes, it contains following chapters: (38) Central nervous system tumors; (39) Tumors of the eye, orbits and adnexas; (40) Head and neck carcinomas; (41) Lung carcinomas and pleural mesothelioma; (42) Mediastinal tumors; (43) Tumors of the esophagus; (44) Gastric carcinomas; (45) Carcinoma of the colon, rectum and anus; (46) Small intestinal cancer; (47) Liver and biliary tract carcinomas; (48) Tumors of the pancreas; (49) Tumors of the kidney and upper urinary tract; (50) Bladder tumors of the bladder, urinary tract and penis; (51) Prostate Carcinoma; (52) Testicular tumors; (53) Malignant neoplasm of the cervix, vulva and vagina; (54) Endometrial carcinoma; (55) Malignant ovarian tumors; (56) Gestational trophoblastic disease; (57) Breast carcinoma - based on a evidence-based approach; (58) Thyroid and parathyroid carcinomas; (59) Dental tumors of endocrine glands; (60) Tumors of the locomotory system; (61) Malignant melanoma; (62) Carcinomas of the skin and skin adnexa; (63) Malignant tumors in immunosuppressed patients; (64) Tumors of unknown primary localization; (65) Children's oncology; (66) Geriatric Oncology; (67) Principles of long-term survival of patients with medically and socially significant types of malignant tumors after treatment. Section IV: Options of metastic disease disease, it contains following chapters: (68) Metastases to the central nervous system; (69) Metastases in the lungs; (70) Metastases in the liver; (71) Metastases into the skeleton. Section V: Clinical practice in oncology, it contains following chapters: (72) Acute conditions in oncology; (73) Prevention and management of radiation and chemical toxicity

  9. Radiation oncology: An Irish hospitals approach to supporting patients

    Energy Technology Data Exchange (ETDEWEB)

    Miller, Caragh [Cork University Hospital (Ireland)], E-mail: caragh.miller@tcd.ie

    2009-02-15

    Despite advances in medical technology, cancer is still one of the leading causes of death globally, leaving many patients to deal with the emotional and psychological aspects associated with cancer and its treatment [Department of Health and Children. A strategy for cancer control in Ireland. National Cancer Forum. Dublin; 2006]. The recognition and management of psychological conditions are an integral part of comprehensive cancer care. As a result, the Health Services Executive as part of the continuing expansion of Cork Radiation Oncology Department created the role of Information and Support Radiation Therapist. This post was specially created during June 2005 to facilitate the smooth entry into the treatment for patients and family members experiencing radiotherapy for the first time. Working alongside the oncology nurses and other health professionals the Information and Support Radiation Therapist aims to provide vital education/information and support to patients and their families. The provision of this new service for patients enables departments to adopt a holistic approach to treatment. This research identifies the cancer services and psychological support services in Ireland. Up-to-date audits of the new patient services established in the Cork Radiation Oncology Department and their psychological contribution towards cancer development and treatment are also discussed.

  10. Radiation oncology: An Irish hospitals approach to supporting patients

    International Nuclear Information System (INIS)

    Miller, Caragh

    2009-01-01

    Despite advances in medical technology, cancer is still one of the leading causes of death globally, leaving many patients to deal with the emotional and psychological aspects associated with cancer and its treatment [Department of Health and Children. A strategy for cancer control in Ireland. National Cancer Forum. Dublin; 2006]. The recognition and management of psychological conditions are an integral part of comprehensive cancer care. As a result, the Health Services Executive as part of the continuing expansion of Cork Radiation Oncology Department created the role of Information and Support Radiation Therapist. This post was specially created during June 2005 to facilitate the smooth entry into the treatment for patients and family members experiencing radiotherapy for the first time. Working alongside the oncology nurses and other health professionals the Information and Support Radiation Therapist aims to provide vital education/information and support to patients and their families. The provision of this new service for patients enables departments to adopt a holistic approach to treatment. This research identifies the cancer services and psychological support services in Ireland. Up-to-date audits of the new patient services established in the Cork Radiation Oncology Department and their psychological contribution towards cancer development and treatment are also discussed

  11. Technology for Innovation in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Chetty, Indrin J. [Department of Radiation Oncology, Henry Ford Hospital, Detroit, Michigan (United States); Martel, Mary K., E-mail: mmartel@mdanderson.org [Department of Radiation Physics, University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Jaffray, David A. [Departments of Radiation Oncology and Medical Biophysics, Princess Margaret Hospital, Toronto, Ontario (Canada); Benedict, Stanley H. [Department of Radiation Oncology, University of California – Davis Cancer Center, Sacramento, California (United States); Hahn, Stephen M. [Department of Radiation Oncology, University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Berbeco, Ross [Department of Radiation Oncology, Brigham and Women' s Hospital, Boston, Massachusetts (United States); Deye, James [Radiation Research Programs, National Cancer Institute, Bethesda, Maryland (United States); Jeraj, Robert [Department of Medical Physics, University of Wisconsin, Madison, Wisconsin (United States); Kavanagh, Brian [Department of Radiation Oncology, University of Colorado, Aurora, Colorado (United States); Krishnan, Sunil [Department of Radiation Oncology, University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Lee, Nancy [Department of Radiation Oncology, Memorial Sloan Kettering Cancer Center, New York, New York (United States); Low, Daniel A. [Department of Radiation Oncology, University of California – Los Angeles, Los Angeles, California (United States); Mankoff, David [Department of Radiology, University of Washington Medical School, Seattle, Washington (United States); Marks, Lawrence B. [Department of Radiation Oncology, University of North Carolina Hospitals, Chapel Hill, North Carolina (United States); Ollendorf, Daniel [Institute for Clinical and Economic Review, Boston, Massachusetts (United States); and others

    2015-11-01

    Radiation therapy is an effective, personalized cancer treatment that has benefited from technological advances associated with the growing ability to identify and target tumors with accuracy and precision. Given that these advances have played a central role in the success of radiation therapy as a major component of comprehensive cancer care, the American Society for Radiation Oncology (ASTRO), the American Association of Physicists in Medicine (AAPM), and the National Cancer Institute (NCI) sponsored a workshop entitled “Technology for Innovation in Radiation Oncology,” which took place at the National Institutes of Health (NIH) in Bethesda, Maryland, on June 13 and 14, 2013. The purpose of this workshop was to discuss emerging technology for the field and to recognize areas for greater research investment. Expert clinicians and scientists discussed innovative technology in radiation oncology, in particular as to how these technologies are being developed and translated to clinical practice in the face of current and future challenges and opportunities. Technologies encompassed topics in functional imaging, treatment devices, nanotechnology, and information technology. The technical, quality, and safety performance of these technologies were also considered. A major theme of the workshop was the growing importance of innovation in the domain of process automation and oncology informatics. The technologically advanced nature of radiation therapy treatments predisposes radiation oncology research teams to take on informatics research initiatives. In addition, the discussion on technology development was balanced with a parallel conversation regarding the need for evidence of efficacy and effectiveness. The linkage between the need for evidence and the efforts in informatics research was clearly identified as synergistic.

  12. Technology for Innovation in Radiation Oncology.

    Science.gov (United States)

    Chetty, Indrin J; Martel, Mary K; Jaffray, David A; Benedict, Stanley H; Hahn, Stephen M; Berbeco, Ross; Deye, James; Jeraj, Robert; Kavanagh, Brian; Krishnan, Sunil; Lee, Nancy; Low, Daniel A; Mankoff, David; Marks, Lawrence B; Ollendorf, Daniel; Paganetti, Harald; Ross, Brian; Siochi, Ramon Alfredo C; Timmerman, Robert D; Wong, John W

    2015-11-01

    Radiation therapy is an effective, personalized cancer treatment that has benefited from technological advances associated with the growing ability to identify and target tumors with accuracy and precision. Given that these advances have played a central role in the success of radiation therapy as a major component of comprehensive cancer care, the American Society for Radiation Oncology (ASTRO), the American Association of Physicists in Medicine (AAPM), and the National Cancer Institute (NCI) sponsored a workshop entitled "Technology for Innovation in Radiation Oncology," which took place at the National Institutes of Health (NIH) in Bethesda, Maryland, on June 13 and 14, 2013. The purpose of this workshop was to discuss emerging technology for the field and to recognize areas for greater research investment. Expert clinicians and scientists discussed innovative technology in radiation oncology, in particular as to how these technologies are being developed and translated to clinical practice in the face of current and future challenges and opportunities. Technologies encompassed topics in functional imaging, treatment devices, nanotechnology, and information technology. The technical, quality, and safety performance of these technologies were also considered. A major theme of the workshop was the growing importance of innovation in the domain of process automation and oncology informatics. The technologically advanced nature of radiation therapy treatments predisposes radiation oncology research teams to take on informatics research initiatives. In addition, the discussion on technology development was balanced with a parallel conversation regarding the need for evidence of efficacy and effectiveness. The linkage between the need for evidence and the efforts in informatics research was clearly identified as synergistic. Copyright © 2015 Elsevier Inc. All rights reserved.

  13. Technology for Innovation in Radiation Oncology

    International Nuclear Information System (INIS)

    Chetty, Indrin J.; Martel, Mary K.; Jaffray, David A.; Benedict, Stanley H.; Hahn, Stephen M.; Berbeco, Ross; Deye, James; Jeraj, Robert; Kavanagh, Brian; Krishnan, Sunil; Lee, Nancy; Low, Daniel A.; Mankoff, David; Marks, Lawrence B.; Ollendorf, Daniel

    2015-01-01

    Radiation therapy is an effective, personalized cancer treatment that has benefited from technological advances associated with the growing ability to identify and target tumors with accuracy and precision. Given that these advances have played a central role in the success of radiation therapy as a major component of comprehensive cancer care, the American Society for Radiation Oncology (ASTRO), the American Association of Physicists in Medicine (AAPM), and the National Cancer Institute (NCI) sponsored a workshop entitled “Technology for Innovation in Radiation Oncology,” which took place at the National Institutes of Health (NIH) in Bethesda, Maryland, on June 13 and 14, 2013. The purpose of this workshop was to discuss emerging technology for the field and to recognize areas for greater research investment. Expert clinicians and scientists discussed innovative technology in radiation oncology, in particular as to how these technologies are being developed and translated to clinical practice in the face of current and future challenges and opportunities. Technologies encompassed topics in functional imaging, treatment devices, nanotechnology, and information technology. The technical, quality, and safety performance of these technologies were also considered. A major theme of the workshop was the growing importance of innovation in the domain of process automation and oncology informatics. The technologically advanced nature of radiation therapy treatments predisposes radiation oncology research teams to take on informatics research initiatives. In addition, the discussion on technology development was balanced with a parallel conversation regarding the need for evidence of efficacy and effectiveness. The linkage between the need for evidence and the efforts in informatics research was clearly identified as synergistic.

  14. The American Society for Radiation Oncology's 2015 Core Physics Curriculum for Radiation Oncology Residents

    International Nuclear Information System (INIS)

    Burmeister, Jay; Chen, Zhe; Chetty, Indrin J.; Dieterich, Sonja; Doemer, Anthony; Dominello, Michael M.; Howell, Rebecca M.; McDermott, Patrick; Nalichowski, Adrian; Prisciandaro, Joann; Ritter, Tim; Smith, Chadd; Schreiber, Eric; Shafman, Timothy; Sutlief, Steven; Xiao, Ying

    2016-01-01

    Purpose: The American Society for Radiation Oncology (ASTRO) Physics Core Curriculum Subcommittee (PCCSC) has updated the recommended physics curriculum for radiation oncology resident education to improve consistency in teaching, intensity, and subject matter. Methods and Materials: The ASTRO PCCSC is composed of physicists and physicians involved in radiation oncology residency education. The PCCSC updated existing sections within the curriculum, created new sections, and attempted to provide additional clinical context to the curricular material through creation of practical clinical experiences. Finally, we reviewed the American Board of Radiology (ABR) blueprint of examination topics for correlation with this curriculum. Results: The new curriculum represents 56 hours of resident physics didactic education, including a 4-hour initial orientation. The committee recommends completion of this curriculum at least twice to assure both timely presentation of material and re-emphasis after clinical experience. In addition, practical clinical physics and treatment planning modules were created as a supplement to the didactic training. Major changes to the curriculum include addition of Fundamental Physics, Stereotactic Radiosurgery/Stereotactic Body Radiation Therapy, and Safety and Incidents sections, and elimination of the Radiopharmaceutical Physics and Dosimetry and Hyperthermia sections. Simulation and Treatment Verification and optional Research and Development in Radiation Oncology sections were also added. A feedback loop was established with the ABR to help assure that the physics component of the ABR radiation oncology initial certification examination remains consistent with this curriculum. Conclusions: The ASTRO physics core curriculum for radiation oncology residents has been updated in an effort to identify the most important physics topics for preparing residents for careers in radiation oncology, to reflect changes in technology and practice since

  15. Radiation oncology a physicist's-eye view

    CERN Document Server

    Goitein, Michael

    2007-01-01

    Radiation Oncology: A Physicist's-Eye View was written for both physicists and medical oncologists with the aim of helping them approach the use of radiation in the treatment of cancer with understanding, confidence, and imagination. The book will let practitioners in one field understand the problems of, and find solutions for, practitioners in the other. It will help them to know "why" certain approaches are fruitful while, at the same time, encouraging them to ask the question "Why not?" in the face of assertions that some proposal of theirs is impractical, unreasonable, or impossible. Unlike a textbook, formal and complete developments of the topics are not among the goals. Instead, the reader will develop a foundation for understanding what the author has found to be matters of importance in radiation oncology during over thirty years of experience. Presentations cover, in largely non-technical language, the principal physical and biological aspects of radiation treatment and address practical clinical c...

  16. Standardizing Naming Conventions in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Santanam, Lakshmi [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (United States); Hurkmans, Coen [Department of Radiation Oncology, Catharina Hospital, Eindhoven (Netherlands); Mutic, Sasa [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (United States); Vliet-Vroegindeweij, Corine van [Department of Radiation Oncology, Thomas Jefferson University Hospital, Philadelphia, PA (United States); Brame, Scott; Straube, William [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (United States); Galvin, James [Department of Radiation Oncology, Thomas Jefferson University Hospital, Philadelphia, PA (United States); Tripuraneni, Prabhakar [Department of Radiation Oncology, Scripps Clinic, LaJolla, CA (United States); Michalski, Jeff [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (United States); Bosch, Walter, E-mail: wbosch@radonc.wustl.edu [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (United States); Advanced Technology Consortium, Image-guided Therapy QA Center, St. Louis, MO (United States)

    2012-07-15

    Purpose: The aim of this study was to report on the development of a standardized target and organ-at-risk naming convention for use in radiation therapy and to present the nomenclature for structure naming for interinstitutional data sharing, clinical trial repositories, integrated multi-institutional collaborative databases, and quality control centers. This taxonomy should also enable improved plan benchmarking between clinical institutions and vendors and facilitation of automated treatment plan quality control. Materials and Methods: The Advanced Technology Consortium, Washington University in St. Louis, Radiation Therapy Oncology Group, Dutch Radiation Oncology Society, and the Clinical Trials RT QA Harmonization Group collaborated in creating this new naming convention. The International Commission on Radiation Units and Measurements guidelines have been used to create standardized nomenclature for target volumes (clinical target volume, internal target volume, planning target volume, etc.), organs at risk, and planning organ-at-risk volumes in radiation therapy. The nomenclature also includes rules for specifying laterality and margins for various structures. The naming rules distinguish tumor and nodal planning target volumes, with correspondence to their respective tumor/nodal clinical target volumes. It also provides rules for basic structure naming, as well as an option for more detailed names. Names of nonstandard structures used mainly for plan optimization or evaluation (rings, islands of dose avoidance, islands where additional dose is needed [dose painting]) are identified separately. Results: In addition to its use in 16 ongoing Radiation Therapy Oncology Group advanced technology clinical trial protocols and several new European Organization for Research and Treatment of Cancer protocols, a pilot version of this naming convention has been evaluated using patient data sets with varying treatment sites. All structures in these data sets were

  17. Standardizing Naming Conventions in Radiation Oncology

    International Nuclear Information System (INIS)

    Santanam, Lakshmi; Hurkmans, Coen; Mutic, Sasa; Vliet-Vroegindeweij, Corine van; Brame, Scott; Straube, William; Galvin, James; Tripuraneni, Prabhakar; Michalski, Jeff; Bosch, Walter

    2012-01-01

    Purpose: The aim of this study was to report on the development of a standardized target and organ-at-risk naming convention for use in radiation therapy and to present the nomenclature for structure naming for interinstitutional data sharing, clinical trial repositories, integrated multi-institutional collaborative databases, and quality control centers. This taxonomy should also enable improved plan benchmarking between clinical institutions and vendors and facilitation of automated treatment plan quality control. Materials and Methods: The Advanced Technology Consortium, Washington University in St. Louis, Radiation Therapy Oncology Group, Dutch Radiation Oncology Society, and the Clinical Trials RT QA Harmonization Group collaborated in creating this new naming convention. The International Commission on Radiation Units and Measurements guidelines have been used to create standardized nomenclature for target volumes (clinical target volume, internal target volume, planning target volume, etc.), organs at risk, and planning organ-at-risk volumes in radiation therapy. The nomenclature also includes rules for specifying laterality and margins for various structures. The naming rules distinguish tumor and nodal planning target volumes, with correspondence to their respective tumor/nodal clinical target volumes. It also provides rules for basic structure naming, as well as an option for more detailed names. Names of nonstandard structures used mainly for plan optimization or evaluation (rings, islands of dose avoidance, islands where additional dose is needed [dose painting]) are identified separately. Results: In addition to its use in 16 ongoing Radiation Therapy Oncology Group advanced technology clinical trial protocols and several new European Organization for Research and Treatment of Cancer protocols, a pilot version of this naming convention has been evaluated using patient data sets with varying treatment sites. All structures in these data sets were

  18. Standardizing naming conventions in radiation oncology.

    Science.gov (United States)

    Santanam, Lakshmi; Hurkmans, Coen; Mutic, Sasa; van Vliet-Vroegindeweij, Corine; Brame, Scott; Straube, William; Galvin, James; Tripuraneni, Prabhakar; Michalski, Jeff; Bosch, Walter

    2012-07-15

    The aim of this study was to report on the development of a standardized target and organ-at-risk naming convention for use in radiation therapy and to present the nomenclature for structure naming for interinstitutional data sharing, clinical trial repositories, integrated multi-institutional collaborative databases, and quality control centers. This taxonomy should also enable improved plan benchmarking between clinical institutions and vendors and facilitation of automated treatment plan quality control. The Advanced Technology Consortium, Washington University in St. Louis, Radiation Therapy Oncology Group, Dutch Radiation Oncology Society, and the Clinical Trials RT QA Harmonization Group collaborated in creating this new naming convention. The International Commission on Radiation Units and Measurements guidelines have been used to create standardized nomenclature for target volumes (clinical target volume, internal target volume, planning target volume, etc.), organs at risk, and planning organ-at-risk volumes in radiation therapy. The nomenclature also includes rules for specifying laterality and margins for various structures. The naming rules distinguish tumor and nodal planning target volumes, with correspondence to their respective tumor/nodal clinical target volumes. It also provides rules for basic structure naming, as well as an option for more detailed names. Names of nonstandard structures used mainly for plan optimization or evaluation (rings, islands of dose avoidance, islands where additional dose is needed [dose painting]) are identified separately. In addition to its use in 16 ongoing Radiation Therapy Oncology Group advanced technology clinical trial protocols and several new European Organization for Research and Treatment of Cancer protocols, a pilot version of this naming convention has been evaluated using patient data sets with varying treatment sites. All structures in these data sets were satisfactorily identified using this

  19. Use of imaging techniques in radiation oncology

    International Nuclear Information System (INIS)

    Borras, C.; Rudder, D.; Jimenez, P.

    2002-01-01

    Imaging techniques are used in radiation oncology for: disease diagnosis, tumor localization and staging, treatment simulation, treatment planning, clinical dosimetry displays, treatment verification and patient follow up. In industrialized countries, up to the 1970's, conventional radiology was used for diagnosis, simulation and planning. Gamma cameras helped tumor staging by detecting metastases. In the 1970's, simulators were developed for exclusive use in radiation oncology departments. Clinical dosimetry displays consisted mainly in axial dose distributions. Treatment verification was done placing films in the radiation beam with the patient under treatment. In the 1980's, 2-D imaging was replaced by 3-D displays with the incorporation of computerized tomography (CT) scanners, and in the 1990's of magnetic resonance imagers (MRI). Ultrasound units, briefly used in the 1960's for treatment planning purposes, were found again useful, mainly for brachytherapy dosimetry. Digital portal imagers allowed accurate treatment field verification. Treatment planning systems incorporated the capability of 'inverse planning', i.e. once the desired dose distribution is decided, the field size, gantry, collimator and couch angles, etc, can be automatically selected. At the end of the millennium, image fusion permitted excellent anatomical display of tumors and adjacent sensitive structures. The 2000's are seeing a change from anatomical to functional imaging with the advent of MRI units capable of spectroscopy at 3 Tesla and positron emission tomography (PET) units. In 2001 combined CT/PET units appeared in RT departments. In 2002, fusion of CT, MRI and PET images became available. Molecular imaging is being developed. The situation in developing countries is quite different. To start with, cancer incidence is different in developing and in industrialized countries. In addition, the health services pattern is different: Cancer treatment is mostly done in public institutions

  20. Managing patients with oncologic complications in the emergency department [digest].

    Science.gov (United States)

    Wacker, David; McCurdy, Michael T; Nusbaum, Jeffrey; Gupta, Nachi

    2018-01-22

    As the prevalence of cancer continues to increase in the general population and improvements in cancer treatment prolong survival, the incidence of patients presenting to the emergency department with oncologic complications will, similarly, continue to rise. This issue reviews 3 of the more common presentations of oncology patients to the emergency department: metastatic spinal cord compression, tumor lysis syndrome, and febrile neutropenia. Signs and symptoms of these conditions can be varied and nonspecific, and may be related to the malignancy itself or to an adverse effect of the cancer treatment. Timely evidence-based decisions in the emergency department regarding diagnostic testing, medications, and arrangement of disposition and oncology follow-up can significantly improve a cancer patient's quality of life. [Points & Pearls is a digest of Emergency Medicine Practice.].

  1. A clinical intranet model for radiation oncology

    International Nuclear Information System (INIS)

    Brooks, Ken; Fox, Tim; Davis, Larry

    1997-01-01

    Purpose: A new paradigm in computing is being formulated from advances in client-server technology. This new way of accessing data in a network is referred to variously as Web-based computing, Internet computing, or Intranet computing. The difference between an internet and intranet being that the former is for global access and the later is only for intra-departmental access. Our purpose with this work is to develop a clinically useful radiation oncology intranet for accessing physically disparate data sources. Materials and Methods: We have developed an intranet client-server system using Windows-NT Server 4.0 running Internet Information Server (IIS) on the back-end and client PCs using a typical World Wide Web (WWW) browser. The clients also take advantage of the Microsoft Open Database Connectivity (ODBC) standard for accessing commercial database systems. The various data sources used include: a traditional Radiation Oncology Information (ROIS) System (VARiS 1.3 tm ); a 3-D treatment planning system (CAD Plan tm ); a beam scanning system (Wellhoffer tm ); as well as an electronic portal imaging device (PortalVision tm ) and a CT-Simulator providing digitally reconstructed radiographs (DRRs) (Picker AcQsim tm ). We were able to leverage previously developed Microsoft Visual C++ applications without major re-writing of source code for this. Results: With the data sources and development materials used, we were able to develop a series of WWW-based clinical tool kits. The tool kits were designed to provide profession-specific clinical information. The physician's tool kit provides a treatment schedule for daily patients along with a dose summary from VARiS and the ability to review portal images and prescription images from the EPID and Picker. The physicists tool kit compares dose summaries from VARiS with an independent check against RTP beam data and serves as a quick 'chart-checker'. Finally, an administrator tool kit provides a summary of periodic charging

  2. MOSFET dosimetry on modern radiation oncology modalities

    International Nuclear Information System (INIS)

    Rosenfeld, A.B.

    2002-01-01

    The development of MOSFET dosimetry is presented with an emphasis on the development of a scanning MOSFET dosimetry system for modern radiation oncology modalities. Fundamental aspects of MOSFETs in relation to their use as dosemeters are briefly discussed. The performance of MOSFET dosemeters in conformal radiotherapy, hadron therapy, intensity-modulated radiotherapy and microbeam radiation therapy is compared with other dosimetric techniques. In particular the application of MOSFET dosemeters in the characterisation and quality assurance of the steep dose gradients associated with the penumbra of some modern radiation oncology modalities is investigated. A new in vivo, on-line, scanning MOSFET read out system is also presented. The system has the ability to read out multiple MOSFET dosemeters with excellent spatial resolution and temperature stability and minimal slow border trapping effects. (author)

  3. Review of advanced catheter technologies in radiation oncology brachytherapy procedures

    OpenAIRE

    Zhou J; Zamdborg L; Sebastian E

    2015-01-01

    Jun Zhou,1,2 Leonid Zamdborg,1 Evelyn Sebastian1 1Department of Radiation Oncology, Beaumont Health System, 2Oakland University William Beaumont School of Medicine, Royal Oak, MI, USA Abstract: The development of new catheter and applicator technologies in recent years has significantly improved treatment accuracy, efficiency, and outcomes in brachytherapy. In this paper, we review these advances, focusing on the performance of catheter imaging and reconstruction techniques in brachytherapy ...

  4. Workplace Bullying in Radiology and Radiation Oncology.

    Science.gov (United States)

    Parikh, Jay R; Harolds, Jay A; Bluth, Edward I

    2017-08-01

    Workplace bullying is common in health care and has recently been reported in both radiology and radiation oncology. The purpose of this article is to increase awareness of bullying and its potential consequences in radiology and radiation oncology. Bullying behavior may involve abuse, humiliation, intimidation, or insults; is usually repetitive; and causes distress in victims. Workplace bullying is more common in health care than in other industries. Surveys of radiation therapists in the United States, student radiographers in England, and physicians-in-training showed that substantial proportions of respondents had been subjected to workplace bullying. No studies were found that addressed workplace bullying specifically in diagnostic radiology or radiation oncology residents. Potential consequences of workplace bullying in health care include anxiety, depression, and health problems in victims; harm to patients as a result of victims' reduced ability to concentrate; and reduced morale and high turnover in the workplace. The Joint Commission has established leadership standards addressing inappropriate behavior, including bullying, in the workplace. The ACR Commission on Human Resources recommends that organizations take steps to prevent bullying. Those steps include education, including education to ensure that the line between the Socratic method and bullying is not crossed, and the establishment of policies to facilitate reporting of bullying and support victims of bullying. Copyright © 2016 American College of Radiology. Published by Elsevier Inc. All rights reserved.

  5. Impact of radiation research on clinical trials in radiation oncology

    International Nuclear Information System (INIS)

    Rubin, P.; Van Ess, J.D.

    1989-01-01

    The authors present an outline review of the history of the formation of the cooperative group called International Clinical Trials in Radiation Oncology (ICTRO), and the following areas are briefly discussed together with some projections for the direction of clinical trials in radiation oncology into the 1990s:- radiosensitizers, radioprotectors, and their combination, drug-radiation interactions, dose/time/fractionation, hyperthermia, biological response modifiers and radiolabelled antibodies, high LET, particularly neutron therapy, large field irradiation and interoperative irradiation, research studies on specific sites. (U.K.)

  6. Value: A Framework for Radiation Oncology

    Science.gov (United States)

    Teckie, Sewit; McCloskey, Susan A.; Steinberg, Michael L.

    2014-01-01

    In the current health care system, high costs without proportional improvements in quality or outcome have prompted widespread calls for change in how we deliver and pay for care. Value-based health care delivery models have been proposed. Multiple impediments exist to achieving value, including misaligned patient and provider incentives, information asymmetries, convoluted and opaque cost structures, and cultural attitudes toward cancer treatment. Radiation oncology as a specialty has recently become a focus of the value discussion. Escalating costs secondary to rapidly evolving technologies, safety breaches, and variable, nonstandardized structures and processes of delivering care have garnered attention. In response, we present a framework for the value discussion in radiation oncology and identify approaches for attaining value, including economic and structural models, process improvements, outcome measurement, and cost assessment. PMID:25113759

  7. Department of Radiation Detectors: Overview

    International Nuclear Information System (INIS)

    Piekoszewski, J.

    1998-01-01

    (full text) Work carried out in 1997 in the Department of Radiation Detectors concentrated on three subjects: (i) Semiconductor Detectors (ii) X-ray Tube Generators (iii) Material Modification using Ion and Plasma Beams. Semiconductor detectors: Semiconductor detectors of ionizing radiation are among the basic tools utilized in such fields of research and industry as nuclear physics, high energy physics, medical (oncology) radiotherapy, radiological protection, environmental monitoring, energy dispersive X-ray fluorescence non-destructive analysis of chemical composition, nuclear power industry. The Department all objectives are: - search for new types of detectors, - adapting modern technologies (especially of industrial microelectronics) to detector manufacturing, - producing unique detectors tailored for physics experiments, - manufacturing standard detectors for radiation measuring instruments, - scientific development of the staff. These 1997 objectives were accomplished particularly by: - research on unique detectors for nuclear physics (e.g. transmission type Si(Li) detectors with extremely thin entrance and exit window), - development of technology of high-resistivity (HRSi) silicon detectors and thermoelectric cooling systems (KBN grant), - study of the applicability of industrial planar technology in producing detectors, - manufacturing detectors developed in previous years, re-generating and servicing customer detectors of various origin. In accomplishing of the above, the Department cooperated with interested groups of physicists from our Institute (P-I and P-II Departments), Warsaw University, Warsaw Heavy Ion Laboratory and with some technology Institutes based in Warsaw (ITME, ITE). Some detectors and services have been delivered to customers on a commercial basis. X-Rat tube generators: The Department conducts research on design and technology of producing X-ray generators based on X-ray tubes of special construction. In 1997, work on a special

  8. Experimental radiation pathology and oncology

    International Nuclear Information System (INIS)

    Finkel, M.P.

    1975-01-01

    The program goal is to provide basic data for evaluating the hazard to man from radioactive materials deposited within the body. The original objective, to obtain dose-response information and to provide data from several species for extrapolating animal data to man, is receiving less attention at present as effort is being put into determining how radiation causes bone cancer and whether viruses play a role. The program began with the very early radiotoxicologic investigations of materials important in the development of the atomic bomb and the necessity to establish maximum permissible levels of exposure to these materials. With the demonstration that bone cancer is the most sensitive indicator of damage from transuranic elements and some of the fission products, bone pathology became the focus of attention. When it became evident that questions of human hazard cannot be answered unequivocally on the basis of dose-response relationships, different approaches were considered, and one based on knowledge of mechanisms of cancer induction seemed most likely to be successful. The detection of viruses in both radiation-induced and spontaneous bone cancer of mice, and the present evidence for a similar virus in bone cancer of man, support the hypothesis that radiation causes cancer by activating endogenous neoplastic information, which can also be expressed as oncornavirus. Present emphases therefore concern understanding the biological, biochemical, and physical attributes of the five murine oncornaviruses that have now been isolated in the course of the program; demonstrating the existence of a comparable human oncornavirus; and discovering how radiation and virus interact in the induction of bone cancer

  9. Radiation oncology medical physics education and training in Queensland

    International Nuclear Information System (INIS)

    West, M.P.; Thomas, B.J.

    2011-01-01

    Full text: The training education and accreditation program (TEAP) for radiation oncology commenced formally in Queensland in 2008 with an initial intake of nine registrars. In 2011 there are 17 registrars across four ACPSEM accredited Queensland Health departments (Mater Radiation Oncology Centre, Princess Alexandria Hospital, Royal Brisbane and Women's Hospital, Townsville Hospital). The Queensland Statewide Cancer Services Plan 2008-2017 outlines significant expansion to oncology services including increases in total number of treatment machines from 14 (2007) to 29-31 (2017) across existing and new clinical departments. A direct implication of this will be the number of qualified ROMPs needed to maintain and develop medical physics services. This presentation will outline ongoing work in the ROMP education and Training portfolio to develop, facilitate and provide training activities for ROMPs undertaking TEAP in the Queensland public system. Initiatives such as Department of Health and Aging scholarships for medical physics students, and the educational challenges associated with competency attainment will also be discussed in greater detail.

  10. Medical legal aspects of radiation oncology

    International Nuclear Information System (INIS)

    Wall, Terry J.

    1996-01-01

    The theoretical basis of, and practical experience in, legal liability in the clinical practice of radiation oncology is reviewed, with a view to developing suggestions to help practitioners limit their exposure to liability. New information regarding the number, size, and legal theories of litigation against radiation oncologists is presented. The most common legal bases of liability are then explored in greater detail, including 'malpractice', and informed consent, with suggestions of improving the specialty's record of documenting informed consent. Collateral consequences of suffering a malpractice claim (i.e., the National Practitioner Data Bank) will also be briefly discussed

  11. Developing aspects of radiation oncology

    International Nuclear Information System (INIS)

    Fowler, J.F.

    1981-01-01

    Both physics and radiobiology provide growing points in modern radiotherapy. Better physical dose distributions appear to be still worth achieving and can be obtained from beams of protons, heavy ions, or negative pi mesons because a peak region of high dose is deposited at depth in tissue. The heavier ion and pions also have biological properties of high LET radiation which could be important: the radioresistance of hypoxic cells in tumors is less, and tissues which are proliferating fast may be relatively more vulnerable. Although fast neutrons provide ordinary physical dose distributions, their high LET properties are similar to those of ions as heavy as neon. Drugs which specifically radiosensitize hypoxic cells offer a way of determining with certainty how important hypoxic cells are in radiotherapy. Hyperthermia is in its early stages but promises to damage just those cells poor in nutrients which are relatively resistant to ionizing radiation. Radioprotecting drugs, which depend upon poor uptake in tumors but high uptake in normal tissues, are also being tested

  12. Burnout in United States Academic Chairs of Radiation Oncology Programs

    Energy Technology Data Exchange (ETDEWEB)

    Kusano, Aaron S. [Department of Radiation Oncology, University of Washington School of Medicine, Seattle, Washington (United States); Thomas, Charles R., E-mail: thomasch@ohsu.edu [Department of Radiation Medicine, Knight Cancer Institute/Oregon Health and Science University, Portland, Oregon (United States); Bonner, James A. [Department of Radiation Oncology, University of Alabama at Birmingham, Birmingham, Alabama (United States); DeWeese, Theodore L. [Department of Radiation Oncology and Molecular Radiation Sciences, Johns Hopkins Medical Institutions, Baltimore, Maryland (United States); Formenti, Silvia C. [Department of Radiation Oncology, New York University, New York, New York (United States); Hahn, Stephen M. [Department of Radiation Oncology, Perelman School of Medicine at the University of Pennsylvania, Philadelphia, Pennsylvania (United States); Lawrence, Theodore S. [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Mittal, Bharat B. [Department of Radiation Oncology, Northwestern University, Chicago, Ilinois (United States)

    2014-02-01

    Purpose: The aims of this study were to determine the self-reported prevalence of burnout in chairs of academic radiation oncology departments, to identify factors contributing to burnout, and to compare the prevalence of burnout with that seen in other academic chair groups. Methods and Materials: An anonymous online survey was administered to the membership of the Society of Chairs of Academic Radiation Oncology Programs (SCAROP). Burnout was measured with the Maslach Burnout Inventory-Human Services Survey (MBI-HSS). Results: Questionnaires were returned from 66 of 87 chairs (76% response rate). Seventy-nine percent of respondents reported satisfaction with their current positions. Common major stressors were budget deficits and human resource issues. One-quarter of chairs reported that it was at least moderately likely that they would step down in the next 1 to 2 years; these individuals demonstrated significantly higher emotional exhaustion. Twenty-five percent of respondents met the MBI-HSS criteria for low burnout, 75% for moderate burnout, and none for high burnout. Group MBI-HSS subscale scores demonstrated a pattern of moderate emotional exhaustion, low depersonalization, and moderate personal accomplishment, comparing favorably with other specialties. Conclusions: This is the first study of burnout in radiation oncology chairs with a high response rate and using a validated psychometric tool. Radiation oncology chairs share similar major stressors to other chair groups, but they demonstrate relatively high job satisfaction and lower burnout. Emotional exhaustion may contribute to the anticipated turnover in coming years. Further efforts addressing individual and institutional factors associated with burnout may improve the relationship with work of chairs and other department members.

  13. Burnout in United States Academic Chairs of Radiation Oncology Programs

    International Nuclear Information System (INIS)

    Kusano, Aaron S.; Thomas, Charles R.; Bonner, James A.; DeWeese, Theodore L.; Formenti, Silvia C.; Hahn, Stephen M.; Lawrence, Theodore S.; Mittal, Bharat B.

    2014-01-01

    Purpose: The aims of this study were to determine the self-reported prevalence of burnout in chairs of academic radiation oncology departments, to identify factors contributing to burnout, and to compare the prevalence of burnout with that seen in other academic chair groups. Methods and Materials: An anonymous online survey was administered to the membership of the Society of Chairs of Academic Radiation Oncology Programs (SCAROP). Burnout was measured with the Maslach Burnout Inventory-Human Services Survey (MBI-HSS). Results: Questionnaires were returned from 66 of 87 chairs (76% response rate). Seventy-nine percent of respondents reported satisfaction with their current positions. Common major stressors were budget deficits and human resource issues. One-quarter of chairs reported that it was at least moderately likely that they would step down in the next 1 to 2 years; these individuals demonstrated significantly higher emotional exhaustion. Twenty-five percent of respondents met the MBI-HSS criteria for low burnout, 75% for moderate burnout, and none for high burnout. Group MBI-HSS subscale scores demonstrated a pattern of moderate emotional exhaustion, low depersonalization, and moderate personal accomplishment, comparing favorably with other specialties. Conclusions: This is the first study of burnout in radiation oncology chairs with a high response rate and using a validated psychometric tool. Radiation oncology chairs share similar major stressors to other chair groups, but they demonstrate relatively high job satisfaction and lower burnout. Emotional exhaustion may contribute to the anticipated turnover in coming years. Further efforts addressing individual and institutional factors associated with burnout may improve the relationship with work of chairs and other department members

  14. Department of Radiation Detectors: Overview

    International Nuclear Information System (INIS)

    Piekoszewski, J.

    1999-01-01

    Full text: Work carried out in 1998 in the Department of Radiation Detectors concentrated on three subjects: (i) Semiconductor Detectors (ii) X-ray Tube Generators (iii) Material Modification Using Ion and Plasma Beams. SEMICONDUCTOR DETECTORS: Semiconductor detectors of ionizing radiation are among the basic tools utilized in such fields of research and industry as nuclear physics, high energy physics, medical (oncology) radiotherapy, radiological protection, environmental monitoring, energy dispersive X-ray fluorescence non-destructive analysis of chemical composition, nuclear power industry. The departmental objectives are: a search for new types of detectors; producing unique detectors tailored for physics experiments; manufacturing standard detectors for radiation measuring instruments; scientific development of the staff. These objectives were accomplished in 1998 particularly by: research on unique thin silicon detectors for identification of particles in E-ΔE telescopes, modernization of technology of manufacturing Ge(Li) detectors capable of detecting broader range of gamma energies, manufacturing detectors developed in previous years, re-generating and servicing customer detectors of various origin. In accomplishment of the above the Department co-operated with groups of physicists from IPJ, PAN Institute of Physics (Warsaw), and with some technology Institutes based in Warsaw (ITME, ITE). Some detectors and services have been delivered to customers on a commercial basis. X-Ray TUBE GENERATORS: The Department conducts research on design and technology of manufacturing X-ray generators as well as on imaging and dosimetry of X-ray beams. Various models of special construction X-ray tubes and their power supplies are under construction. In 1998 work concentrated on: completing laboratory equipment for manufacturing X-ray tubes and their components, developing technology of manufacturing X-ray tubes and their components, completing a laboratory set-up with

  15. Radiation protection in medical imaging and radiation oncology

    CERN Document Server

    Stoeva, Magdalena S

    2016-01-01

    Radiation Protection in Medical Imaging and Radiation Oncology focuses on the professional, operational, and regulatory aspects of radiation protection. Advances in radiation medicine have resulted in new modalities and procedures, some of which have significant potential to cause serious harm. Examples include radiologic procedures that require very long fluoroscopy times, radiolabeled monoclonal antibodies, and intravascular brachytherapy. This book summarizes evidence supporting changes in consensus recommendations, regulations, and health physics practices associated with these recent advances in radiology, nuclear medicine, and radiation oncology. It supports intelligent and practical methods for protection of personnel, the public, and patients. The book is based on current recommendations by the International Commission on Radiological Protection and is complemented by detailed practical sections and professional discussions by the world’s leading medical and health physics professionals. It also ...

  16. Faculty of Radiation Oncology 2010 workforce survey.

    Science.gov (United States)

    Leung, John; Vukolova, Natalia

    2011-12-01

    This paper outlines the key results of the Faculty of Radiation Oncology 2010 workforce survey and compares these results with earlier data. The workforce survey was conducted in mid-2010 using a custom-designed 17-question survey. The overall response rate was 76%. The majority of radiation oncologist respondents were male (n = 212, 71%), but the majority of trainee respondents were female (n = 59, 52.7%). The age range of fellows was 32-92 years (median: 47 years; mean: 49 years) and that of trainees was 27-44 years (median: 31 years; mean: 31.7 years). Most radiation oncologists worked at more than one practice (average: two practices). The majority of radiation oncologists worked in the public sector (n = 169, 64.5%), with some working in 'combination' of public and private sectors (n = 65, 24.8%) and a minority working in the private sector only (n = 28, 10.7%). The hours worked per week ranged from 1 to 85 (mean: 44 h; median: 45 h) for radiation oncologists, while for trainees the range was 16-90 (mean: 47 h; median: 45 h). The number of new cases seen in a year ranged from 1 to 1100 (mean: 275; median: 250). Most radiation oncologists considered themselves generalists with a preferred sub-specialty (43.3%) or specialists (41.9%), while a minority considered themselves as generalists (14.8%). There are a relatively large and increasing number of radiation oncologists and trainees compared with previous years. The excessive workloads evident in previous surveys appear to have diminished. However, further work is required on assessing the impact of ongoing feminisation and sub-specialisation. © 2011 The Authors. Journal of Medical Imaging and Radiation Oncology © 2011 The Royal Australian and New Zealand College of Radiologists.

  17. Paediatric Radiation Oncology. Chapter 21

    International Nuclear Information System (INIS)

    Anacak, Y.; Zaghloul, M.; Laskar, S.

    2017-01-01

    Although cancer is a typical disease of ageing adults, it can be seen at any age and cancer diagnosis in a child is not a rare situation. Every day around the world, many teenagers, young children and even infants are diagnosed with cancer. Cancer in children is an important health care problem, not only for the individual patient and medical staff, but also for families, teachers, friends and society as a whole. In every culture, children are considered innocent human beings and the diagnosis of such an ‘evil’ disease in a young child always induces feelings of unfairness and anguish. Most childhood cancers are curable; using the best treatment options, more than 80% of children with cancer may survive to adulthood. However, cure alone is not the ultimate goal for paediatric cancer treatment; late effects of treatment impact the quality of life of patients. Cure from cancer in a child means adding at least 50–60 years to his or her life, which is long enough to develop serious late effects of the treatment and the induction of secondary cancers. Thus, treatment should be tailored to minimize the exposure of healthy tissues to chemotherapy drugs and radiation. Cancer treatment can be a painful process, often involving surgery, radiotherapy and chemotherapy, and requiring very long treatment periods, which impair the motor and mental development of the child, and his or her educational activities and relations with society. Childhood cancer survivors sometimes have modest to severe sequelae of the disease itself and the treatment used, which may disrupt their development to a healthy adulthood. These cancer survivors should be fully integrated into society and be allowed to live productive lives even when lifelong rehabilitation is required to keep them active.

  18. Radiation Oncology Medical Student Clerkship: Implementation and Evaluation of a Bi-institutional Pilot Curriculum

    Energy Technology Data Exchange (ETDEWEB)

    Golden, Daniel W., E-mail: dgolden@radonc.uchicago.edu [Department of Radiation and Cellular Oncology, University of Chicago Pritzker School of Medicine, Chicago, Illinois (United States); Spektor, Alexander [Department of Radiation Oncology, Brigham and Women' s Hospital and Dana-Farber Cancer Institute, Harvard Medical School, Boston, Massachusetts (United States); Rudra, Sonali; Ranck, Mark C. [Department of Radiation and Cellular Oncology, University of Chicago Pritzker School of Medicine, Chicago, Illinois (United States); Krishnan, Monica S.; Jimenez, Rachel B.; Viswanathan, Akila N. [Department of Radiation Oncology, Brigham and Women' s Hospital and Dana-Farber Cancer Institute, Harvard Medical School, Boston, Massachusetts (United States); Koshy, Matthew; Howard, Andrew R.; Chmura, Steven J. [Department of Radiation and Cellular Oncology, University of Chicago Pritzker School of Medicine, Chicago, Illinois (United States)

    2014-01-01

    Purpose: To develop and evaluate a structured didactic curriculum to complement clinical experiences during radiation oncology clerkships at 2 academic medical centers. Methods and Materials: A structured didactic curriculum was developed to teach fundamentals of radiation oncology and improve confidence in clinical competence. Curriculum lectures included: (1) an overview of radiation oncology (history, types of treatments, and basic clinic flow); (2) fundamentals of radiation biology and physics; and (3) practical aspects of radiation treatment simulation and planning. In addition, a hands-on dosimetry session taught students fundamentals of treatment planning. The curriculum was implemented at 2 academic departments in 2012. Students completed anonymous evaluations using a Likert scale to rate the usefulness of curriculum components (1 = not at all, 5 = extremely). Likert scores are reported as (median [interquartile range]). Results: Eighteen students completed the curriculum during their 4-week rotation (University of Chicago n=13, Harvard Longwood Campus n=5). All curriculum components were rated as extremely useful: introduction to radiation oncology (5 [4-5]); radiation biology and physics (5 [5-5]); practical aspects of radiation oncology (5 [4-5]); and the treatment planning session (5 [5-5]). Students rated the curriculum as “quite useful” to “extremely useful” (1) to help students understand radiation oncology as a specialty; (2) to increase student comfort with their specialty decision; and (3) to help students with their future transition to a radiation oncology residency. Conclusions: A standardized curriculum for medical students completing a 4-week radiation oncology clerkship was successfully implemented at 2 institutions. The curriculum was favorably reviewed. As a result of completing the curriculum, medical students felt more comfortable with their specialty decision and better prepared to begin radiation oncology residency.

  19. Radiation Oncology Medical Student Clerkship: Implementation and Evaluation of a Bi-institutional Pilot Curriculum

    International Nuclear Information System (INIS)

    Golden, Daniel W.; Spektor, Alexander; Rudra, Sonali; Ranck, Mark C.; Krishnan, Monica S.; Jimenez, Rachel B.; Viswanathan, Akila N.; Koshy, Matthew; Howard, Andrew R.; Chmura, Steven J.

    2014-01-01

    Purpose: To develop and evaluate a structured didactic curriculum to complement clinical experiences during radiation oncology clerkships at 2 academic medical centers. Methods and Materials: A structured didactic curriculum was developed to teach fundamentals of radiation oncology and improve confidence in clinical competence. Curriculum lectures included: (1) an overview of radiation oncology (history, types of treatments, and basic clinic flow); (2) fundamentals of radiation biology and physics; and (3) practical aspects of radiation treatment simulation and planning. In addition, a hands-on dosimetry session taught students fundamentals of treatment planning. The curriculum was implemented at 2 academic departments in 2012. Students completed anonymous evaluations using a Likert scale to rate the usefulness of curriculum components (1 = not at all, 5 = extremely). Likert scores are reported as (median [interquartile range]). Results: Eighteen students completed the curriculum during their 4-week rotation (University of Chicago n=13, Harvard Longwood Campus n=5). All curriculum components were rated as extremely useful: introduction to radiation oncology (5 [4-5]); radiation biology and physics (5 [5-5]); practical aspects of radiation oncology (5 [4-5]); and the treatment planning session (5 [5-5]). Students rated the curriculum as “quite useful” to “extremely useful” (1) to help students understand radiation oncology as a specialty; (2) to increase student comfort with their specialty decision; and (3) to help students with their future transition to a radiation oncology residency. Conclusions: A standardized curriculum for medical students completing a 4-week radiation oncology clerkship was successfully implemented at 2 institutions. The curriculum was favorably reviewed. As a result of completing the curriculum, medical students felt more comfortable with their specialty decision and better prepared to begin radiation oncology residency

  20. Oncology

    International Nuclear Information System (INIS)

    1998-01-01

    This paper collects some scientific research works on nuclear medicine developed in Ecuador. The main topics are: Brain metastases, computed tomography assessment; Therapeutic challenge in brain metastases, chemotherapy, surgery or radiotherapy; Neurocysticercosis and oncogenesis; Neurologic complications of radiation and chemotherapy; Cerebral perfusion gammagraphy in neurology and neurosurgery; Neuro- oncologic surgical patient anesthesic management; Pain management in neuro- oncology; Treatment of metastatic lesions of the spine, surgically decompression vs radiation therapy alone; Neuroimagining in spinal metastases

  1. Clinical quality assurance in radiation oncology

    International Nuclear Information System (INIS)

    Anon.

    1991-01-01

    A quality assurance program in radiation oncology monitors and evaluates any departmental functions which have an impact on patient outcome. The ultimate purpose of the program is to maximize health benefit to the patient without a corresponding increase in risk. The foundation of the program should be the credo: at least do no harm, usually do some good and ideally realize the greatest good. The steep dose response relationships for tumor control and complications require a high degree of accuracy and precision throughout the entire process of radiation therapy. It has been shown that failure to control local disease with radiation may result in decreased survival and may increase the cost of care by a factor of 3. Therefore, a comprehensive quality assurance program which seeks to optimize dose delivery and which encompasses both clinical and physics components, is needed

  2. The role of PDGF in radiation oncology

    International Nuclear Information System (INIS)

    Li, Minglun; Jendrossek, Verena; Belka, Claus

    2007-01-01

    Platelet-derived growth factor (PDGF) was originally identified as a constituent of blood serum and subsequently purified from human platelets. PDGF ligand is a dimeric molecule consisting of two disulfide-bonded chains from A-, B-, C- and D-polypeptide chains, which combine to homo- and heterodimers. The PDGF isoforms exert their cellular effects by binding to and activating two structurally related protein tyrosine kinase receptors. PDGF is a potent mitogen and chemoattractant for mesenchymal cells and also a chemoattractant for neutrophils and monocytes. In radiation oncology, PDGF are important for several pathologic processes, including oncogenesis, angiogenesis and fibrogenesis. Autocrine activation of PDGF was observed and interpreted as an important mechanism involved in brain and other tumors. PDGF has been shown to be fundamental for the stability of normal blood vessel formation, and may be essential for the angiogenesis in tumor tissue. PDGF also plays an important role in the proliferative disease, such as atherosclerosis and radiation-induced fibrosis, regarding its proliferative stimulation of fibroblast cells. Moreover, PDGF was also shown to stimulate production of extracellular matrix proteins, which are mainly responsible for the irreversibility of these diseases. This review introduces the structural and functional properties of PDGF and PDGF receptors and discusses the role and mechanism of PDGF signaling in normal and tumor tissues under different conditions in radiation oncology

  3. [Artificial intelligence applied to radiation oncology].

    Science.gov (United States)

    Bibault, J-E; Burgun, A; Giraud, P

    2017-05-01

    Performing randomised comparative clinical trials in radiation oncology remains a challenge when new treatment modalities become available. One of the most recent examples is the lack of phase III trials demonstrating the superiority of intensity-modulated radiation therapy in most of its current indications. A new paradigm is developing that consists in the mining of large databases to answer clinical or translational issues. Beyond national databases (such as SEER or NCDB), that often lack the necessary level of details on the population studied or the treatments performed, electronic health records can be used to create detailed phenotypic profiles of any patients. In parallel, the Record-and-Verify Systems used in radiation oncology precisely document the planned and performed treatments. Artificial Intelligence and machine learning algorithms can be used to incrementally analyse these data in order to generate hypothesis to better personalize treatments. This review discusses how these methods have already been used in previous studies. Copyright © 2017 Société française de radiothérapie oncologique (SFRO). Published by Elsevier SAS. All rights reserved.

  4. A Research Agenda for Radiation Oncology: Results of the Radiation Oncology Institute's Comprehensive Research Needs Assessment

    Energy Technology Data Exchange (ETDEWEB)

    Jagsi, Reshma, E-mail: rjagsi@med.umich.edu [Department of Radiation Oncology, University of Michigan, Ann Arbor, MI (United States); Bekelman, Justin E. [Department of Radiation Oncology, University of Pennsylvania, Philadelphia, PA (United States); Brawley, Otis W. [Department of Hematology and Oncology, Emory University, and American Cancer Society, Atlanta, Georgia (United States); Deasy, Joseph O. [Department of Radiation Oncology, Memorial Sloan-Kettering Cancer Center, New York, NY (United States); Le, Quynh-Thu [Department of Radiation Oncology, Stanford University, Stanford, CA (United States); Michalski, Jeff M. [Department of Radiation Oncology, Washington University, St. Louis, MO (United States); Movsas, Benjamin [Department of Radiation Oncology, Henry Ford Health System, Detroit, MI (United States); Thomas, Charles R. [Department of Radiation Oncology, Oregon Health and Sciences University, Portland, OR (United States); Lawton, Colleen A. [Department of Radiation Oncology, Medical College of Wisconsin, Milwaukee, WI (United States); Lawrence, Theodore S. [Department of Radiation Oncology, University of Michigan, Ann Arbor, MI (United States); Hahn, Stephen M. [Department of Radiation Oncology, University of Pennsylvania, Philadelphia, PA (United States)

    2012-10-01

    Purpose: To promote the rational use of scarce research funding, scholars have developed methods for the systematic identification and prioritization of health research needs. The Radiation Oncology Institute commissioned an independent, comprehensive assessment of research needs for the advancement of radiation oncology care. Methods and Materials: The research needs assessment used a mixed-method, qualitative and quantitative social scientific approach, including structured interviews with diverse stakeholders, focus groups, surveys of American Society for Radiation Oncology (ASTRO) members, and a prioritization exercise using a modified Delphi technique. Results: Six co-equal priorities were identified: (1) Identify and develop communication strategies to help patients and others better understand radiation therapy; (2) Establish a set of quality indicators for major radiation oncology procedures and evaluate their use in radiation oncology delivery; (3) Identify best practices for the management of radiation toxicity and issues in cancer survivorship; (4) Conduct comparative effectiveness studies related to radiation therapy that consider clinical benefit, toxicity (including quality of life), and other outcomes; (5) Assess the value of radiation therapy; and (6) Develop a radiation oncology registry. Conclusions: To our knowledge, this prioritization exercise is the only comprehensive and methodologically rigorous assessment of research needs in the field of radiation oncology. Broad dissemination of these findings is critical to maximally leverage the impact of this work, particularly because grant funding decisions are often made by committees on which highly specialized disciplines such as radiation oncology are not well represented.

  5. A Research Agenda for Radiation Oncology: Results of the Radiation Oncology Institute’s Comprehensive Research Needs Assessment

    International Nuclear Information System (INIS)

    Jagsi, Reshma; Bekelman, Justin E.; Brawley, Otis W.; Deasy, Joseph O.; Le, Quynh-Thu; Michalski, Jeff M.; Movsas, Benjamin; Thomas, Charles R.; Lawton, Colleen A.; Lawrence, Theodore S.; Hahn, Stephen M.

    2012-01-01

    Purpose: To promote the rational use of scarce research funding, scholars have developed methods for the systematic identification and prioritization of health research needs. The Radiation Oncology Institute commissioned an independent, comprehensive assessment of research needs for the advancement of radiation oncology care. Methods and Materials: The research needs assessment used a mixed-method, qualitative and quantitative social scientific approach, including structured interviews with diverse stakeholders, focus groups, surveys of American Society for Radiation Oncology (ASTRO) members, and a prioritization exercise using a modified Delphi technique. Results: Six co-equal priorities were identified: (1) Identify and develop communication strategies to help patients and others better understand radiation therapy; (2) Establish a set of quality indicators for major radiation oncology procedures and evaluate their use in radiation oncology delivery; (3) Identify best practices for the management of radiation toxicity and issues in cancer survivorship; (4) Conduct comparative effectiveness studies related to radiation therapy that consider clinical benefit, toxicity (including quality of life), and other outcomes; (5) Assess the value of radiation therapy; and (6) Develop a radiation oncology registry. Conclusions: To our knowledge, this prioritization exercise is the only comprehensive and methodologically rigorous assessment of research needs in the field of radiation oncology. Broad dissemination of these findings is critical to maximally leverage the impact of this work, particularly because grant funding decisions are often made by committees on which highly specialized disciplines such as radiation oncology are not well represented.

  6. Radiation Oncology in Undergraduate Medical Education: A Literature Review

    International Nuclear Information System (INIS)

    Dennis, Kristopher E.B.; Duncan, Graeme

    2010-01-01

    Purpose: To review the published literature pertaining to radiation oncology in undergraduate medical education. Methods and Materials: Ovid MEDLINE, Ovid MEDLINE Daily Update and EMBASE databases were searched for the 11-year period of January 1, 1998, through the last week of March 2009. A medical librarian used an extensive list of indexed subject headings and text words. Results: The search returned 640 article references, but only seven contained significant information pertaining to teaching radiation oncology to medical undergraduates. One article described a comprehensive oncology curriculum including recommended radiation oncology teaching objectives and sample student evaluations, two described integrating radiation oncology teaching into a radiology rotation, two described multidisciplinary anatomy-based courses intended to reinforce principles of tumor biology and radiotherapy planning, one described an exercise designed to test clinical reasoning skills within radiation oncology cases, and one described a Web-based curriculum involving oncologic physics. Conclusions: To the authors' knowledge, this is the first review of the literature pertaining to teaching radiation oncology to medical undergraduates, and it demonstrates the paucity of published work in this area of medical education. Teaching radiation oncology should begin early in the undergraduate process, should be mandatory for all students, and should impart knowledge relevant to future general practitioners rather than detailed information relevant only to oncologists. Educators should make use of available model curricula and should integrate radiation oncology teaching into existing curricula or construct stand-alone oncology rotations where the principles of radiation oncology can be conveyed. Assessments of student knowledge and curriculum effectiveness are critical.

  7. Maintenance of Certification for Radiation Oncology

    International Nuclear Information System (INIS)

    Kun, Larry E.; Ang, Kian; Erickson, Beth; Harris, Jay; Hoppe, Richard; Leibel, Steve; Davis, Larry; Hattery, Robert

    2005-01-01

    Maintenance of Certification (MOC) recognizes that in addition to medical knowledge, several essential elements involved in delivering quality care must be developed and maintained throughout one's career. The MOC process is designed to facilitate and document professional development of American Board of Radiology (ABR) diplomates in the essential elements of quality care in Radiation Oncology and Radiologic Physics. ABR MOC has been developed in accord with guidelines of the American Board of Medical Specialties. All Radiation Oncology certificates issued since 1995 are 10-year, time-limited certificates; diplomates with time-limited certificates who wish to maintain specialty certification must complete specific requirements of the American Board of Radiology MOC program. Diplomates with lifelong certificates are not required to participate but are strongly encouraged to do so. Maintenance of Certification is based on documentation of participation in the four components of MOC: (1) professional standing, (2) lifelong learning and self-assessment, (3) cognitive expertise, and (4) performance in practice. Through these components, MOC addresses six competencies-medical knowledge, patient care, interpersonal and communication skills, professionalism, practice-based learning and improvement, and systems-based practice. Details of requirements for components 1, 2, and 3 of MOC are outlined along with aspects of the fourth component currently under development

  8. Apps for Radiation Oncology. A Comprehensive Review

    Directory of Open Access Journals (Sweden)

    J.J. Calero

    2017-02-01

    Full Text Available Introduction: Software applications executed on a smart-phone or mobile device (“Apps” are increasingly used by oncologists in their daily work. A comprehensive critical review was conducted on Apps specifically designed for Radiation Oncology, which aims to provide scientific support for these tools and to guide users in choosing the most suited to their needs. Material and methods: A systematic search was conducted in mobile platforms, iOS and Android, returning 157 Apps. Excluding those whose purpose did not match the scope of the study, 31 Apps were methodically analyzed by the following items: Objective Features, List of Functionalities, Consistency in Outcomes and Usability. Results: Apps are presented in groups of features, as Dose Calculators (7 Apps, Clinical Calculators (4, Tools for Staging (7, Multipurpose (7 and Others (6. Each App is presented with the list of attributes and a brief comment. A short summary is provided at the end of each group. Discussion and Recommendations: There are numerous Apps with useful tools at the disposal of radiation oncologists. The most advisable Apps do not match the more expensive. Three all-in-one apps seem advisable above all: RadOnc Reference (in English, Easy Oncology (in German and iOncoR (in Spanish. Others recommendations are suggested for specific tasks: dose calculators, treatment-decision and staging.

  9. Implementation of nanoparticles in therapeutic radiation oncology

    Science.gov (United States)

    Beeler, Erik; Gabani, Prashant; Singh, Om V.

    2017-05-01

    Development and progress of cancer is a very complex disease process to comprehend because of the multiple changes in cellular physiology, pathology, and pathophysiology resulting from the numerous genetic changes from which cancer originates. As a result, most common treatments are not directed at the molecular level but rather at the tissue level. While personalized care is becoming an increasingly aim, the most common cancer treatments are restricted to chemotherapy, radiation, and surgery, each of which has a high likelihood of resulting in rather severe adverse side effects. For example, currently used radiation therapy does not discriminate between normal and cancerous cells and greatly relies on the external targeting of the radiation beams to specific cells and organs. Because of this, there is an immediate need for the development of new and innovative technologies that help to differentiate tumor cells and micrometastases from normal cells and facilitate the complete destruction of those cells. Recent advancements in nanoscience and nanotechnology have paved a way for the development of nanoparticles (NPs) as multifunctional carriers to deliver therapeutic radioisotopes for tumor targeted radiation therapy, to monitor their delivery, and improve the therapeutic index of radiation and tumor response to the treatment. The application of NPs in radiation therapy has aimed to improve outcomes in radiation therapy by increasing therapeutic effect in tumors and reducing toxicity on normal tissues. Because NPs possess unique properties, such as preferential accumulation in tumors and minimal uptake in normal tissues, it makes them ideal for the delivery of radiotherapy. This review provides an overview of the recent development of NPs for carrying and delivering therapeutic radioisotopes for systemic radiation treatment for a variety of cancers in radiation oncology.

  10. DEGRO 2012. 18. annual congress of the German Radiation Oncology Society. Radiation oncology - medical physics - radiation biology. Abstracts

    International Nuclear Information System (INIS)

    Anon.

    2012-01-01

    The volume includes the abstracts of the contributions and posters of the 18th annual congress of the German Radiation Oncology Society DEGRO 2012. The lectures covered the following topics: Radiation physics, therapy planning; gastrointestinal tumors; radiation biology; stererotactic radiotherapy/breast carcinomas; quality management - life quality; head-neck-tumors/lymphomas; NSCL (non-small cell lung carcinomas); pelvic tumors; brain tumors/pediatric tumors. The poster sessions included the following topics: quality management, recurrent tumor therapy; brachytherapy; breast carcinomas and gynecological tumors; pelvis tumors; brain tumors; stereotactic radiotherapy; head-neck carcinomas; NSCL, proton therapy, supporting therapy; clinical radio-oncology, radiation biology, IGRT/IMRT.

  11. Decision making in radiation oncology. Vol. 1

    International Nuclear Information System (INIS)

    Lu, Jiade J.; Brady, Luther W.

    2011-01-01

    Decision Making in Radiation Oncology is a reference book designed to enable radiation oncologists, including those in training, to make diagnostic and treatment decisions effectively and efficiently. The orientation of this groundbreaking publication is entirely practical, in that the focus is on issues relating to cancer management. The design has been carefully chosen based on the belief that ''a picture is worth a thousand words'': Knowledge is conveyed through an illustrative approach using algorithms, schemas, graphics, and tables. Text is kept to a minimum, reducing the effort involved in reading while enhancing understanding. Detailed guidelines are provided for multidisciplinary cancer management as well as for radiation therapy techniques. In addition to the attention-riveting algorithms for diagnosis and treatment, strategies for the management of disease at individual stages are detailed for all the commonly diagnosed malignancies. Detailed attention is given to the core evidence that has shaped the current treatment standards and advanced radiation therapy techniques. Clinical trials that have yielded ''gold standard'' treatment and their results are documented in the schemas. Moreover, radiation techniques, including treatment planning and delivery, are also presented in an illustrative way. (orig.)

  12. Decision making in radiation oncology. Vol. 1

    Energy Technology Data Exchange (ETDEWEB)

    Lu, Jiade J. [National Univ. of Singapore (Singapore). Dept. of Radiation Oncology; Brady, Luther W. (eds.) [Drexel Univ., Philadelphia, PA (United States). Dept. of Radiation Oncology

    2011-10-15

    Decision Making in Radiation Oncology is a reference book designed to enable radiation oncologists, including those in training, to make diagnostic and treatment decisions effectively and efficiently. The orientation of this groundbreaking publication is entirely practical, in that the focus is on issues relating to cancer management. The design has been carefully chosen based on the belief that ''a picture is worth a thousand words'': Knowledge is conveyed through an illustrative approach using algorithms, schemas, graphics, and tables. Text is kept to a minimum, reducing the effort involved in reading while enhancing understanding. Detailed guidelines are provided for multidisciplinary cancer management as well as for radiation therapy techniques. In addition to the attention-riveting algorithms for diagnosis and treatment, strategies for the management of disease at individual stages are detailed for all the commonly diagnosed malignancies. Detailed attention is given to the core evidence that has shaped the current treatment standards and advanced radiation therapy techniques. Clinical trials that have yielded ''gold standard'' treatment and their results are documented in the schemas. Moreover, radiation techniques, including treatment planning and delivery, are also presented in an illustrative way. (orig.)

  13. Integrating the Healthcare Enterprise in Radiation Oncology Plug and Play-The Future of Radiation Oncology?

    International Nuclear Information System (INIS)

    Abdel-Wahab, May; Rengan, Ramesh; Curran, Bruce; Swerdloff, Stuart; Miettinen, Mika; Field, Colin; Ranjitkar, Sunita; Palta, Jatinder; Tripuraneni, Prabhakar

    2010-01-01

    Purpose: To describe the processes and benefits of the integrating healthcare enterprises in radiation oncology (IHE-RO). Methods: The IHE-RO process includes five basic steps. The first step is to identify common interoperability issues encountered in radiation treatment planning and the delivery process. IHE-RO committees partner with vendors to develop solutions (integration profiles) to interoperability problems. The broad application of these integration profiles across a variety of vender platforms is tested annually at the Connectathon event. Demonstration of the seamless integration and transfer of patient data to the potential users are then presented by vendors at the public demonstration event. Users can then integrate these profiles into requests for proposals and vendor contracts by institutions. Results: Incorporation of completed integration profiles into requests for proposals can be done when purchasing new equipment. Vendors can publish IHE integration statements to document the integration profiles supported by their products. As a result, users can reference integration profiles in requests for proposals, simplifying the systems acquisition process. These IHE-RO solutions are now available in many of the commercial radiation oncology-related treatment planning, delivery, and information systems. They are also implemented at cancer care sites around the world. Conclusions: IHE-RO serves an important purpose for the radiation oncology community at large.

  14. The stucture of Korean radiation oncology in 1997

    International Nuclear Information System (INIS)

    Kim, Mi Sook; Yoo, Seoung Yul; Cho, Chul Koo; Yoo, Hyung Jun; Yang, Kwang Mo; Ji, Young Hoon; Kim, Do Jun

    1999-01-01

    To measure the basic structural characteristics of radiation oncology facilities in Korea during 1997 and to compare personnel, equipment and patient loads between Korea and developed countries. Mail surveys were conducted in 1998 and data on treatment machines, personnel and performed new patients were collected. Responses were obtained from the 100 percent of facilities. The consensus data of the whole contry were summarized using Microsoft Excel program. In Korea during 1997, 42 facilities delivered megavoltage radiation therapy with 71 treatment machines, 100 radiation oncologists, 26 medical physicist, 205 technologists and 19,773 new patients. Eighty nine percent of facilities in Korea had linear accelerates at least 6 MeV maximum photon energy. Ninety five percent of facilities had simulators while five percent of facilities had no simulator. Ninety one percent of facilities had computer planning systems and eighty three percent of facilities reported that they had a written quality assurance program. Thirty six percent of facilities had only one radiation oncologist and thirty eight percent of facilities had no medical physicists. The median of the distribution of annual patients load of a facility, patients load per a machine, patients load per a radiation oncologist, patients load per a therapist and therapists per a machine in Korea were 348 patients per a year, 263 patients per a machine, 171 patients per a radiation oncologist, 81 patients per a therapist, and 3 therapists per a machine respectively. The whole scale of the radiation oncology departments in Korea was smaller than Japan and USA in population ratio regard. In case of hardware level like linear accelerators, simulators and computer planning systems, there was no big differences between Korea and USA. The patients loads of radiation oncologists and therapists had no significant differences as compared with USA. However, it was desirable to consider the part time system in USA because there

  15. 2009 Canadian Radiation Oncology Resident Survey

    Energy Technology Data Exchange (ETDEWEB)

    Debenham, Brock, E-mail: debenham@ualberta.net [Department of Radiation Oncology, Cross Cancer Institute, University of Alberta, Edmonton, Alberta (Canada); Banerjee, Robyn [Department of Radiation Oncology, Tom Baker Cancer Centre, University of Calgary, Calgary, Alberta (Canada); Fairchild, Alysa; Dundas, George [Department of Radiation Oncology, Cross Cancer Institute, University of Alberta, Edmonton, Alberta (Canada); Trotter, Theresa [Department of Radiation Oncology, Tom Baker Cancer Centre, University of Calgary, Calgary, Alberta (Canada); Yee, Don [Department of Radiation Oncology, Cross Cancer Institute, University of Alberta, Edmonton, Alberta (Canada)

    2012-03-15

    Purpose: Statistics from the Canadian post-MD education registry show that numbers of Canadian radiation oncology (RO) trainees have risen from 62 in 1999 to approximately 150 per year between 2003 and 2009, contributing to the current perceived downturn in employment opportunities for radiation oncologists in Canada. When last surveyed in 2003, Canadian RO residents identified job availability as their main concern. Our objective was to survey current Canadian RO residents on their training and career plans. Methods and Materials: Trainees from the 13 Canadian residency programs using the national matching service were sought. Potential respondents were identified through individual program directors or chief resident and were e-mailed a secure link to an online survey. Descriptive statistics were used to report responses. Results: The eligible response rate was 53% (83/156). Similar to the 2003 survey, respondents generally expressed high satisfaction with their programs and specialty. The most frequently expressed perceived weakness in their training differed from 2003, with 46.5% of current respondents feeling unprepared to enter the job market. 72% plan on pursuing a postresidency fellowship. Most respondents intend to practice in Canada. Fewer than 20% of respondents believe that there is a strong demand for radiation oncologists in Canada. Conclusions: Respondents to the current survey expressed significant satisfaction with their career choice and training program. However, differences exist compared with the 2003 survey, including the current perceived lack of demand for radiation oncologists in Canada.

  16. 2009 Canadian Radiation Oncology Resident Survey

    International Nuclear Information System (INIS)

    Debenham, Brock; Banerjee, Robyn; Fairchild, Alysa; Dundas, George; Trotter, Theresa; Yee, Don

    2012-01-01

    Purpose: Statistics from the Canadian post-MD education registry show that numbers of Canadian radiation oncology (RO) trainees have risen from 62 in 1999 to approximately 150 per year between 2003 and 2009, contributing to the current perceived downturn in employment opportunities for radiation oncologists in Canada. When last surveyed in 2003, Canadian RO residents identified job availability as their main concern. Our objective was to survey current Canadian RO residents on their training and career plans. Methods and Materials: Trainees from the 13 Canadian residency programs using the national matching service were sought. Potential respondents were identified through individual program directors or chief resident and were e-mailed a secure link to an online survey. Descriptive statistics were used to report responses. Results: The eligible response rate was 53% (83/156). Similar to the 2003 survey, respondents generally expressed high satisfaction with their programs and specialty. The most frequently expressed perceived weakness in their training differed from 2003, with 46.5% of current respondents feeling unprepared to enter the job market. 72% plan on pursuing a postresidency fellowship. Most respondents intend to practice in Canada. Fewer than 20% of respondents believe that there is a strong demand for radiation oncologists in Canada. Conclusions: Respondents to the current survey expressed significant satisfaction with their career choice and training program. However, differences exist compared with the 2003 survey, including the current perceived lack of demand for radiation oncologists in Canada.

  17. The Growth of Academic Radiation Oncology: A Survey of Endowed Professorships in Radiation Oncology

    International Nuclear Information System (INIS)

    Wasserman, Todd H.; Smith, Steven M.; Powell, Simon N.

    2009-01-01

    Purpose: The academic health of a medical specialty can be gauged by the level of university support through endowed professorships. Methods and Materials: We conducted a survey of the 86 academic programs in radiation oncology to determine the current status of endowed chairs in this discipline. Results: Over the past decade, the number of endowed chairs has more than doubled, and it has almost tripled over the past 13 years. The number of programs with at least one chair has increased from 31% to 65%. Conclusions: Coupled with other indicators of academic growth, such as the proportion of graduating residents seeking academic positions, there has been clear and sustained growth in academic radiation oncology.

  18. Information technology resource management in radiation oncology.

    Science.gov (United States)

    Siochi, R Alfredo; Balter, Peter; Bloch, Charles D; Bushe, Harry S; Mayo, Charles S; Curran, Bruce H; Feng, Wenzheng; Kagadis, George C; Kirby, Thomas H; Stern, Robin L

    2009-09-02

    The ever-increasing data demands in a radiation oncology (RO) clinic require medical physicists to have a clearer understanding of the information technology (IT) resource management issues. Clear lines of collaboration and communication among administrators, medical physicists, IT staff, equipment service engineers and vendors need to be established. In order to develop a better understanding of the clinical needs and responsibilities of these various groups, an overview of the role of IT in RO is provided. This is followed by a list of IT related tasks and a resource map. The skill set and knowledge required to implement these tasks are described for the various RO professionals. Finally, various models for assessing one's IT resource needs are described. The exposition of ideas in this white paper is intended to be broad, in order to raise the level of awareness of the RO community; the details behind these concepts will not be given here and are best left to future task group reports.

  19. Faculty of Radiation Oncology 2014 workforce census.

    Science.gov (United States)

    Leung, John; Munro, Philip L; James, Melissa

    2015-12-01

    This paper reports the key findings of the Faculty of Radiation Oncology 2014 workforce census and compares the results with earlier surveys. The census was conducted in mid-2014 with distribution to all radiation oncologists, educational affiliates and trainees listed on the college database. There were six email reminders and responses were anonymous. The overall response rate was 76.1%. The age range of fellows was 32-96 (mean = 49 years, median = 47 years). The majority of the radiation oncologists were male (n = 263, 63%). The minority of radiation oncologists were of Asian descent (n = 43, 13.4%). Radiation oncologists graduated from medical school on average 23 years ago (median = 22 years). A minority of fellows (n = 66, 20%) held another postgraduate qualification. Most radiation oncologists worked, on average, at two practices (median = 2, range 1-7). Practising radiation oncologists worked predominantly in the public sector (n = 131, 49%), but many worked in both the public and private sectors (n = 94, 37%), and a minority worked in the private sector only (n = 38, 14%). The largest proportion of the workforce was from New South Wales accounting for 29% of radiation oncologists. Radiation oncologists worked an average of 43 h/week (median = 43 h, range 6-80). Radiation oncologists who worked in the private sector worked less hours than their public sector or public/private sector colleagues. (38.3 vs. 42.9 vs. 44.3 h, P = 0.042). Victorians worked the fewest average hours per week at 38 h and West Australians the most at 46 h/week. Radiation oncologists averaged 48 min for each new case, 17 min per follow up and 11 min for a treatment review. Radiation oncologists averaged 246 new patients per year (median = 250, range = 20-600) with men (average = 268), Western Australians (average = 354) and those in private practice seeing more (average = 275). Most radiation

  20. The road not taken and choices in radiation oncology.

    Science.gov (United States)

    Coleman, C Norman; Glatstein, Eli

    2010-01-01

    Accomplishments and contributions in a career in radiation oncology, and in medicine in general, involve individual choices that impact the direction of a specialty, decisions in patient care, consequences of treatment outcome, and personal satisfaction. Issues in radiation oncology include: the development and implementation of new radiation treatment technology; the use of multimodality and biologically based therapies; the role of nonradiation "energy" technologies, often by other medical specialties, including the need for quality assurance in treatment and data reporting; and the type of evidence, including appropriate study design, analysis, and rigorous long-term follow-up, that is sought before widespread implementation of a new treatment. Personal choices must weigh: the pressure from institutions-practices, departments, universities, and hospitals; the need to serve society and the underserved; the balance between individual reward and a greater mission; and the critical role of personal values and integrity, often requiring difficult and "life-defining" decisions. The impact that each of us makes in a career is perhaps more a result of character than of the specific details enumerated on one's curriculum vitae. The individual tapestry weaved by choosing the more or less traveled paths during a career results in many pathways that would be called success; however, the one path for which there is no good alternative is that of living and acting with integrity.

  1. 3D planning and radiation oncology residents' training

    International Nuclear Information System (INIS)

    Jayaraman, Subramania

    1991-01-01

    Radiation treatments in radiation oncology clinics have been always planned to irradiate three dimensional (3D) volumes. Though the term 3D planning has come in vogue only in recent years, the essence of 3D planning had been always there. This is because the patient is a 3D subject and every treatment option adopted in a radiotherapy clinic has to be based on a 3D judgement of its acceptability. An essential aspect of training of radiation oncology residents is to help them understand the different techniques and methods used to get an acceptable 3D dose delivery. The tools of 3D planning should be introduced to the residents for their educational value. The regular use of these tools may require not only fast computers and work stations, but also a change of routine in the department. This might be difficult since the departmental routine can evolve only gradually. On the other hand, an insight about the advantages of the tools could be gained through a simple personal computer. Some examples of using the 3D planning tools through a personal computer, for educational purposes have been presented here, using clinical contexts routinely encountered. (author). 5 refs., 10 figs

  2. Meeting the challenge of managed care - Part III: Information systems for radiation oncology practice

    International Nuclear Information System (INIS)

    Kijewski, Peter

    1997-01-01

    Purpose: This course will review topics to be considered when defining an information systems plan for a department of radiation oncology. A survey of available systems will be presented. Computer information systems can play an important role in the effective administration and operation of a department of radiation oncology. Tasks such as 1) scheduling for physicians, patients, and rooms, 2) charge collection and billing, 3) administrative reporting, and 4) treatment verification can be carried out efficiently with the assistance of computer systems. Operating a department without a state of art computer system will become increasingly difficult as hospitals and healthcare buyers increasingly rely on computer information technology. Communication of the radiation oncology system with outside systems will thus further enhance the utility of the computer system. The steps for the selection and installation of an information system will be discussed: 1) defining the objectives, 2) selecting a suitable system, 3) determining costs, 4) setting up maintenance contracts, and 5) planning for future upgrades

  3. A Personal Reflection on the History of Radiation Oncology at Memorial Sloan-Kettering Cancer Center

    International Nuclear Information System (INIS)

    Chu, Florence C.H.

    2011-01-01

    Purpose: To provide a historical and personal narrative of the development of radiation oncology at Memorial Sloan-Kettering Cancer Center (MSKCC), from its founding more than 100 years ago to the present day. Methods and Materials: Historical sources include the Archives of MSKCC, publications by members of MSKCC, the author's personal records and recollections, and her communications with former colleagues, particularly Dr. Basil Hilaris, Dr. Zvi Fuks, and Dr. Beryl McCormick. Conclusions: The author, who spent 38 years at MSKCC, presents the challenges and triumphs of MSKCC's Radiation Oncology Department and details MSKCC's breakthroughs in radiation oncology. She also describes MSKCC's involvement in the founding of the American Society for Therapeutic Radiology and Oncology.

  4. Palliative care and palliative radiation therapy education in radiation oncology: A survey of US radiation oncology program directors.

    Science.gov (United States)

    Wei, Randy L; Colbert, Lauren E; Jones, Joshua; Racsa, Margarita; Kane, Gabrielle; Lutz, Steve; Vapiwala, Neha; Dharmarajan, Kavita V

    The purpose of this study was to assess the state of palliative and supportive care (PSC) and palliative radiation therapy (RT) educational curricula in radiation oncology residency programs in the United States. We surveyed 87 program directors of radiation oncology residency programs in the United States between September 2015 and November 2015. An electronic survey on PSC and palliative RT education during residency was sent to all program directors. The survey consisted of questions on (1) perceived relevance of PSC and palliative RT to radiation oncology training, (2) formal didactic sessions on domains of PSC and palliative RT, (3) effective teaching formats for PSC and palliative RT education, and (4) perceived barriers for integrating PSC and palliative RT into the residency curriculum. A total of 57 responses (63%) was received. Most program directors agreed or strongly agreed that PSC (93%) and palliative radiation therapy (99%) are important competencies for radiation oncology residents and fellows; however, only 67% of residency programs had formal educational activities in principles and practice of PSC. Most programs had 1 or more hours of formal didactics on management of pain (67%), management of neuropathic pain (65%), and management of nausea and vomiting (63%); however, only 35%, 33%, and 30% had dedicated lectures on initial management of fatigue, assessing role of spirituality, and discussing advance care directives, respectively. Last, 85% of programs reported having a formal curriculum on palliative RT. Programs were most likely to have education on palliative radiation to brain, bone, and spine, but less likely on visceral, or skin, metastasis. Residency program directors believe that PSC and palliative RT are important competencies for their trainees and support increasing education in these 2 educational domains. Many residency programs have structured curricula on PSC and palliative radiation education, but room for improvement exists in

  5. Radiation oncology physics: A handbook for teachers and students

    International Nuclear Information System (INIS)

    Podgorsak, E.B.

    2005-07-01

    Radiotherapy, also referred to as radiation therapy, radiation oncology or therapeutic radiology, is one of the three principal modalities used in the treatment of malignant disease (cancer), the other two being surgery and chemotherapy. In contrast to other medical specialties that rely mainly on the clinical knowledge and experience of medical specialists, radiotherapy, with its use of ionizing radiation in the treatment of cancer, relies heavily on modern technology and the collaborative efforts of several professionals whose coordinated team approach greatly influences the outcome of the treatment. The radiotherapy team consists of radiation oncologists, medical physicists, dosimetrists and radiation therapy technologists: all professionals characterized by widely differing educational backgrounds and one common link - the need to understand the basic elements of radiation physics, and the interaction of ionizing radiation with human tissue in particular. This specialized area of physics is referred to as radiation oncology physics, and proficiency in this branch of physics is an absolute necessity for anyone who aspires to achieve excellence in any of the four professions constituting the radiotherapy team. Current advances in radiation oncology are driven mainly by technological development of equipment for radiotherapy procedures and imaging; however, as in the past, these advances rely heavily on the underlying physics. This book is dedicated to students and teachers involved in programmes that train professionals for work in radiation oncology. It provides a compilation of facts on the physics as applied to radiation oncology and as such will be useful to graduate students and residents in medical physics programmes, to residents in radiation oncology, and to students in dosimetry and radiotherapy technology programmes. The level of understanding of the material covered will, of course, be different for the various student groups; however, the basic

  6. Requirements for radiation oncology physics in Australia and New Zealand

    International Nuclear Information System (INIS)

    Oliver, L.; Fitchew, R.; Drew, J.

    2001-01-01

    This Position Paper reviews the role, standards of practice, education, training and staffing requirements for radiation oncology physics. The role and standard of practice for an expert in radiation oncology physics, as defined by the Australasian College of Physical Scientists and Engineers in Medicine (ACPSEM), are consistent with the IAEA recommendations. International standards of safe practice recommend that this physics expert be authorised by a Regulatory Authority (in consultation with the professional organisation). In order to accommodate the international and AHTAC recommendations or any requirements that may be set by a Regulatory Authority, the ACPSEM has defined the criteria for a physicist-in-training, a base level physicist, an advanced level physicist and an expert radiation oncology physicist. The ACPSEM shall compile separate registers for these different radiation oncology physicist categories. What constitutes a satisfactory means of establishing the number of physicists and support physics staff that is required in radiation oncology continues to be debated. The new ACPSEM workforce formula (Formula 2000) yields similar numbers to other international professional body recommendations. The ACPSEM recommends that Australian and New Zealand radiation oncology centres should aim to employ 223 and 46 radiation oncology physics staff respectively. At least 75% of this workforce should be physicists ( 168 in Australia and 35 in New Zealand). An additional 41 registrar physicist positions (34 in Australia and 7 in New Zealand) should be specifically created for training purposes. These registrar positions cater for the present physicist shortfall, the future expansion of radiation oncology and the expected attrition of radiation oncology physicists in the workforce. Registrar physicists shall undertake suitable tertiary education in medical physics with an organised in-house training program.The rapid advances in the theory and methodology of the new

  7. The Development of On-Line Statistics Program for Radiation Oncology

    International Nuclear Information System (INIS)

    Kim, Yoon Jong; Lee, Dong Hoon; Ji, Young Hoon; Lee, Dong Han; Jo, Chul Ku; Kim, Mi Sook; Ru, Sung Rul; Hong, Seung Hong

    2001-01-01

    Purpose : By developing on-line statistics program to record the information of radiation oncology to share the information with internet. It is possible to supply basic reference data for administrative plans to improve radiation oncology. Materials and methods : The information of radiation oncology statistics had been collected by paper forms about 52 hospitals in the past. Now, we can input the data by internet web browsers. The statistics program used windows NT 4.0 operation system, Internet Information Server 4.0 (IIS4.0) as a web server and the Microsoft Access MDB. We used Structured Query Language (SQL), Visual Basic, VBScript and JAVAScript to display the statistics according to years and hospitals. Results : This program shows present conditions about man power, research, therapy machines, technic, brachytherapy, clinic statistics, radiation safety management, institution, quality assurance and radioisotopes in radiation oncology department. The database consists of 38 inputs and 6 outputs windows. Statistical output windows can be increased continuously according to user need. Conclusion : We have developed statistics program to process all of the data in department of radiation oncology for reference information. Users easily could input the data by internet web browsers and share the information

  8. The American Society for Radiation Oncology's 2010 core physics curriculum for radiation oncology residents.

    Science.gov (United States)

    Xiao, Ying; Bernstein, Karen De Amorim; Chetty, Indrin J; Eifel, Patricia; Hughes, Lesley; Klein, Eric E; McDermott, Patrick; Prisciandaro, Joann; Paliwal, Bhudatt; Price, Robert A; Werner-Wasik, Maria; Palta, Jatinder R

    2011-11-15

    In 2004, the American Society for Radiation Oncology (ASTRO) published its first physics education curriculum for residents, which was updated in 2007. A committee composed of physicists and physicians from various residency program teaching institutions was reconvened again to update the curriculum in 2009. Members of this committee have associations with ASTRO, the American Association of Physicists in Medicine, the Association of Residents in Radiation Oncology, the American Board of Radiology (ABR), and the American College of Radiology. Members reviewed and updated assigned subjects from the last curriculum. The updated curriculum was carefully reviewed by a representative from the ABR and other physics and clinical experts. The new curriculum resulted in a recommended 56-h course, excluding initial orientation. Learning objectives are provided for each subject area, and a detailed outline of material to be covered is given for each lecture hour. Some recent changes in the curriculum include the addition of Radiation Incidents and Bioterrorism Response Training as a subject and updates that reflect new treatment techniques and modalities in a number of core subjects. The new curriculum was approved by the ASTRO board in April 2010. We anticipate that physicists will use this curriculum for structuring their teaching programs, and subsequently the ABR will adopt this educational program for its written examination. Currently, the American College of Radiology uses the ASTRO curriculum for their training examination topics. In addition to the curriculum, the committee updated suggested references and the glossary. The ASTRO physics education curriculum for radiation oncology residents has been updated. To ensure continued commitment to a current and relevant curriculum, the subject matter will be updated again in 2 years. Copyright © 2011 Elsevier Inc. All rights reserved.

  9. Geographic Analysis of the Radiation Oncology Workforce

    International Nuclear Information System (INIS)

    Aneja, Sanjay; Smith, Benjamin D.; Gross, Cary P.; Wilson, Lynn D.; Haffty, Bruce G.; Roberts, Kenneth; Yu, James B.

    2012-01-01

    Purpose: To evaluate trends in the geographic distribution of the radiation oncology (RO) workforce. Methods and Materials: We used the 1995 and 2007 versions of the Area Resource File to map the ratio of RO to the population aged 65 years or older (ROR) within different health service areas (HSA) within the United States. We used regression analysis to find associations between population variables and 2007 ROR. We calculated Gini coefficients for ROR to assess the evenness of RO distribution and compared that with primary care physicians and total physicians. Results: There was a 24% increase in the RO workforce from 1995 to 2007. The overall growth in the RO workforce was less than that of primary care or the overall physician workforce. The mean ROR among HSAs increased by more than one radiation oncologist per 100,000 people aged 65 years or older, from 5.08 per 100,000 to 6.16 per 100,000. However, there remained consistent geographic variability concerning RO distribution, specifically affecting the non-metropolitan HSAs. Regression analysis found higher ROR in HSAs that possessed higher education (p = 0.001), higher income (p < 0.001), lower unemployment rates (p < 0.001), and higher minority population (p = 0.022). Gini coefficients showed RO distribution less even than for both primary care physicians and total physicians (0.326 compared with 0.196 and 0.292, respectively). Conclusions: Despite a modest growth in the RO workforce, there exists persistent geographic maldistribution of radiation oncologists allocated along socioeconomic and racial lines. To solve problems surrounding the RO workforce, issues concerning both gross numbers and geographic distribution must be addressed.

  10. Geographic Analysis of the Radiation Oncology Workforce

    Energy Technology Data Exchange (ETDEWEB)

    Aneja, Sanjay [Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, CT (United States); Cancer Outcomes, Policy, and Effectiveness Research Center at Yale, New Haven, CT (United States); Smith, Benjamin D. [University of Texas M. D. Anderson Cancer Center, Houston, TX (United States); Gross, Cary P. [Cancer Outcomes, Policy, and Effectiveness Research Center at Yale, New Haven, CT (United States); Department of General Internal Medicine, Yale University School of Medicine, New Haven, CT (United States); Wilson, Lynn D. [Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, CT (United States); Haffty, Bruce G. [Cancer Institute of New Jersey, New Brunswick, NJ (United States); Roberts, Kenneth [Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, CT (United States); Yu, James B., E-mail: james.b.yu@yale.edu [Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, CT (United States); Cancer Outcomes, Policy, and Effectiveness Research Center at Yale, New Haven, CT (United States)

    2012-04-01

    Purpose: To evaluate trends in the geographic distribution of the radiation oncology (RO) workforce. Methods and Materials: We used the 1995 and 2007 versions of the Area Resource File to map the ratio of RO to the population aged 65 years or older (ROR) within different health service areas (HSA) within the United States. We used regression analysis to find associations between population variables and 2007 ROR. We calculated Gini coefficients for ROR to assess the evenness of RO distribution and compared that with primary care physicians and total physicians. Results: There was a 24% increase in the RO workforce from 1995 to 2007. The overall growth in the RO workforce was less than that of primary care or the overall physician workforce. The mean ROR among HSAs increased by more than one radiation oncologist per 100,000 people aged 65 years or older, from 5.08 per 100,000 to 6.16 per 100,000. However, there remained consistent geographic variability concerning RO distribution, specifically affecting the non-metropolitan HSAs. Regression analysis found higher ROR in HSAs that possessed higher education (p = 0.001), higher income (p < 0.001), lower unemployment rates (p < 0.001), and higher minority population (p = 0.022). Gini coefficients showed RO distribution less even than for both primary care physicians and total physicians (0.326 compared with 0.196 and 0.292, respectively). Conclusions: Despite a modest growth in the RO workforce, there exists persistent geographic maldistribution of radiation oncologists allocated along socioeconomic and racial lines. To solve problems surrounding the RO workforce, issues concerning both gross numbers and geographic distribution must be addressed.

  11. Survey of Radiation Oncology Centres in Australia: report of the radiation oncology treatment quality program

    International Nuclear Information System (INIS)

    Klybaba, M.; Kenny, L.; Kron, T.; Harris, J.; O'Brien, P.

    2009-01-01

    Full text: One of the first steps towards the development of a comprehensive quality program for radiation oncology in Australia has been a survey of practice. This paper reports on the results of the survey that should inform the development of standards for radiation oncology in Australia. A questionnaire of 108 questions spanning aspects of treatment services, equipment, staff, infrastructure and available quality systems was mailed to all facilities providing radiation treatment services in Australia (n = 45). Information of 42 sites was received by June 2006 providing data on 113 operational linear accelerators of which approximately 2/3 are equipped with multi-leaf collimators. More than 75% of facilities were participating in a formal quality assurance (QA) system, with 63% following a nationally or internationally recognised system. However, there was considerable variation in the availability of policies and procedures specific to quality aspects, and the review of these. Policies for monitoring patient waiting times for treatment were documented at just 71% of all facilities. Although 85% of all centres do, in fact, monitor machine throughput, the number and types of efficiency measures varied markedly, thereby limiting the comparative use of these results. Centres identified workload as the single most common factor responsible for limiting staff involvement in both QA processes and clinical trial participation. The data collected in this 'snapshot' survey provide a unique and comprehensive baseline for future comparisons and evaluation of changes

  12. Internet-based communications in radiation oncology

    International Nuclear Information System (INIS)

    Goldwein, Joel W.

    1996-01-01

    Currently, it is estimated that 40 million Americans have access to the Internet. The emergence of widely available software, inexpensive hardware and affordable connectivity have all led to an explosive growth in its use. Medicine in general and radiation oncology specifically are deriving great benefits from this technology. The use of this technology will result in a paradigm shift that is likely to change the way we all communicate. An understanding of the technology is therefore mandatory. The objectives of the course are to provide a practical introduction to the use of Internet technologies as they relate to our profession. The following topics will be reviewed. 1. A brief history of the Internet 2. Getting connected to the Internet 3. Internet venues - The Web, ftp, USENETS ... 4. Basic software tools - email, browsers ... 5. Specific Internet resources 6. Advanced Internet utilization 7. Business and the Internet 8. Intranet utilization 9. Philosophical and medicolegal issues 10. Predictions of the future Upon completion, the attendee will be familiar with the Internet, how it works, and how it can be used to fulfill the research, educational, and clinical care missions of our profession

  13. WE-H-BRB-00: Big Data in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2016-06-15

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  14. WE-H-BRB-00: Big Data in Radiation Oncology

    International Nuclear Information System (INIS)

    2016-01-01

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  15. Fifth nationwide survey on radiation oncology of China in 2006

    International Nuclear Information System (INIS)

    Yin Weibo; Yuyun; Chen Bo; Tian Fenghua

    2007-01-01

    Objective: In order to find out the present status of Chinese Radiation Oncology, the Chinese Society of Radiation Oncology did the fifth nationwide survey on Radiation Oncology in China. Methods: Questionnaire forms had been sent through the board member of Chinese Society of Radiation Oncology to each center throughout the country. The forms, after filing, were returned for analysis. Results: On September 30th, 2006, there were 952 radiation oncology centers. They possess personnel: 5247 doctors including 2 110 residents, 1181 physicists, 6864 nurses, 4559 technicians and 1141 engineers. For equipment: There were 918 linear accelerators, 472 telecobalt units, 146 deep X-ray machine, 827 simulators, 214 CT simulators, 400 brachytherapy units, 400 treatment planning system, 796 dosimeters, 467 X-knife, 149 γ-knife (74 for head only, 75 for the head and body). Treatment: 35 503 beds (35 centers did not report the number of beds), 42 109 patients treated per day, 409 440 new patients were treated per year (no report from 45 centers). Conclusion: Radiation oncology has been developing rapidly in the last 5 years either in quantity or in quality. They are still being considered insufficient in proportion to our population. Training programs and development of QA and QC system ate needed. (authors)

  16. The American Society for Radiation Oncology's 2015 Core Physics Curriculum for Radiation Oncology Residents

    Energy Technology Data Exchange (ETDEWEB)

    Burmeister, Jay, E-mail: burmeist@karmanos.org [Department of Oncology, Karmanos Cancer Center/Wayne State University, Detroit, Michigan (United States); Chen, Zhe [Department of Therapeutic Radiology, Yale University, New Haven, Connecticut (United States); Chetty, Indrin J. [Department of Radiation Oncology, Henry Ford Hospital, Detroit, Michigan (United States); Dieterich, Sonja [Department of Radiation Oncology, University of California – Davis, Sacramento, California (United States); Doemer, Anthony [Department of Radiation Oncology, Henry Ford Hospital, Detroit, Michigan (United States); Dominello, Michael M. [Department of Oncology, Karmanos Cancer Center/Wayne State University, Detroit, Michigan (United States); Howell, Rebecca M. [Department of Radiation Physics, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); McDermott, Patrick [Department of Radiation Oncology, Beaumont Health, Royal Oak, Michigan (United States); Nalichowski, Adrian [Karmanos Cancer Center, Detroit, Michigan (United States); Prisciandaro, Joann [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Ritter, Tim [VA Ann Arbor Healthcare and the University of Michigan, Ann Arbor, Michigan (United States); Smith, Chadd [Department of Radiation Oncology, Henry Ford Hospital, Detroit, Michigan (United States); Schreiber, Eric [Department of Radiation Oncology, University of North Carolina, Chapel Hill, North Carolina (United States); Shafman, Timothy [21st Century Oncology, Fort Myers, Florida (United States); Sutlief, Steven [Department of Radiation Oncology, University of California – San Diego, La Jolla, California (United States); Xiao, Ying [Department of Radiation Oncology, Thomas Jefferson University, Philadelphia, Pennsylvania (United States)

    2016-07-15

    Purpose: The American Society for Radiation Oncology (ASTRO) Physics Core Curriculum Subcommittee (PCCSC) has updated the recommended physics curriculum for radiation oncology resident education to improve consistency in teaching, intensity, and subject matter. Methods and Materials: The ASTRO PCCSC is composed of physicists and physicians involved in radiation oncology residency education. The PCCSC updated existing sections within the curriculum, created new sections, and attempted to provide additional clinical context to the curricular material through creation of practical clinical experiences. Finally, we reviewed the American Board of Radiology (ABR) blueprint of examination topics for correlation with this curriculum. Results: The new curriculum represents 56 hours of resident physics didactic education, including a 4-hour initial orientation. The committee recommends completion of this curriculum at least twice to assure both timely presentation of material and re-emphasis after clinical experience. In addition, practical clinical physics and treatment planning modules were created as a supplement to the didactic training. Major changes to the curriculum include addition of Fundamental Physics, Stereotactic Radiosurgery/Stereotactic Body Radiation Therapy, and Safety and Incidents sections, and elimination of the Radiopharmaceutical Physics and Dosimetry and Hyperthermia sections. Simulation and Treatment Verification and optional Research and Development in Radiation Oncology sections were also added. A feedback loop was established with the ABR to help assure that the physics component of the ABR radiation oncology initial certification examination remains consistent with this curriculum. Conclusions: The ASTRO physics core curriculum for radiation oncology residents has been updated in an effort to identify the most important physics topics for preparing residents for careers in radiation oncology, to reflect changes in technology and practice since

  17. Development of an electronic radiation oncology patient information management system.

    Science.gov (United States)

    Mandal, Abhijit; Asthana, Anupam Kumar; Aggarwal, Lalit Mohan

    2008-01-01

    The quality of patient care is critically influenced by the availability of accurate information and its efficient management. Radiation oncology consists of many information components, for example there may be information related to the patient (e.g., profile, disease site, stage, etc.), to people (radiation oncologists, radiological physicists, technologists, etc.), and to equipment (diagnostic, planning, treatment, etc.). These different data must be integrated. A comprehensive information management system is essential for efficient storage and retrieval of the enormous amounts of information. A radiation therapy patient information system (RTPIS) has been developed using open source software. PHP and JAVA script was used as the programming languages, MySQL as the database, and HTML and CSF as the design tool. This system utilizes typical web browsing technology using a WAMP5 server. Any user having a unique user ID and password can access this RTPIS. The user ID and password is issued separately to each individual according to the person's job responsibilities and accountability, so that users will be able to only access data that is related to their job responsibilities. With this system authentic users will be able to use a simple web browsing procedure to gain instant access. All types of users in the radiation oncology department should find it user-friendly. The maintenance of the system will not require large human resources or space. The file storage and retrieval process would be be satisfactory, unique, uniform, and easily accessible with adequate data protection. There will be very little possibility of unauthorized handling with this system. There will also be minimal risk of loss or accidental destruction of information.

  18. Development of an electronic radiation oncology patient information management system

    Directory of Open Access Journals (Sweden)

    Mandal Abhijit

    2008-01-01

    Full Text Available The quality of patient care is critically influenced by the availability of accurate information and its efficient management. Radiation oncology consists of many information components, for example there may be information related to the patient (e.g., profile, disease site, stage, etc., to people (radiation oncologists, radiological physicists, technologists, etc., and to equipment (diagnostic, planning, treatment, etc.. These different data must be integrated. A comprehensive information management system is essential for efficient storage and retrieval of the enormous amounts of information. A radiation therapy patient information system (RTPIS has been developed using open source software. PHP and JAVA script was used as the programming languages, MySQL as the database, and HTML and CSF as the design tool. This system utilizes typical web browsing technology using a WAMP5 server. Any user having a unique user ID and password can access this RTPIS. The user ID and password is issued separately to each individual according to the person′s job responsibilities and accountability, so that users will be able to only access data that is related to their job responsibilities. With this system authentic users will be able to use a simple web browsing procedure to gain instant access. All types of users in the radiation oncology department should find it user-friendly. The maintenance of the system will not require large human resources or space. The file storage and retrieval process would be be satisfactory, unique, uniform, and easily accessible with adequate data protection. There will be very little possibility of unauthorized handling with this system. There will also be minimal risk of loss or accidental destruction of information.

  19. Lessons Learnt from Past Incidents and Accidents in Radiation Oncology.

    Science.gov (United States)

    Knöös, T

    2017-09-01

    The purpose of this report is to review and compile what have been and can be learnt from incidents and accidents in radiation oncology, especially in external beam and brachytherapy. Some major accidents from the last 20 years will be discussed. The relationship between major events and minor or so-called near misses is mentioned, leading to the next topic of exploring the knowledge hidden among them. The main lessons learnt from the discussion here and elsewhere are that a well-functioning and safe radiotherapy department should help staff to work with awareness and alertness and that documentation and procedures should be in place and known by everyone. It also requires that trained and educated staff with the required competences are in place and, finally, functions and responsibilities are defined and well known. Copyright © 2017 The Royal College of Radiologists. Published by Elsevier Ltd. All rights reserved.

  20. Developing a national radiation oncology registry: From acorns to oaks.

    Science.gov (United States)

    Palta, Jatinder R; Efstathiou, Jason A; Bekelman, Justin E; Mutic, Sasa; Bogardus, Carl R; McNutt, Todd R; Gabriel, Peter E; Lawton, Colleen A; Zietman, Anthony L; Rose, Christopher M

    2012-01-01

    The National Radiation Oncology Registry (NROR) is a collaborative initiative of the Radiation Oncology Institute and the American Society of Radiation Oncology, with input and guidance from other major stakeholders in oncology. The overarching mission of the NROR is to improve the care of cancer patients by capturing reliable information on treatment delivery and health outcomes. The NROR will collect patient-specific radiotherapy data electronically to allow for rapid comparison of the many competing treatment modalities and account for effectiveness, outcome, utilization, quality, safety, and cost. It will provide benchmark data and quality improvement tools for individual practitioners. The NROR steering committee has determined that prostate cancer provides an appropriate model to test the concept and the data capturing software in a limited number of sites. The NROR pilot project will begin with this disease-gathering treatment and outcomes data from a limited number of treatment sites across the range of practice; once feasibility is proven, it will scale up to more sites and diseases. When the NROR is fully implemented, all radiotherapy facilities, along with their radiation oncologists, will be solicited to participate in it. With the broader participation of the radiation oncology community, NROR has the potential to serve as a resource for determining national patterns of care, gaps in treatment quality, comparative effectiveness, and hypothesis generation to identify new linkages between therapeutic processes and outcomes. The NROR will benefit radiation oncologists and other care providers, payors, vendors, policy-makers, and, most importantly, cancer patients by capturing reliable information on population-based radiation treatment delivery. Copyright © 2012 (c) 2010 American Society for Radiation Oncology. Published by Elsevier Inc. All rights reserved. Published by Elsevier Inc. All rights reserved.

  1. A citation anaysis of Chinese Journal of Radiation Oncology

    International Nuclear Information System (INIS)

    Yang Hua; Shi Shuxia

    2005-01-01

    Objective: To evaluate the academic level and the popularity of Chinese Journal of Radiation Oncology. Methods: According to the information of Chinese Medical Citation Index(CMCI), statistically analyzed the amount and distribution of the originals in Chinese Journal of Radiation Oncology cited by the journal included by CMCI. Results: The proportion of cited articles for original articles, short report and review were 73.8%, 58.1% and 60.7% respectively, and average cited numbers for them were 7.2, 3.0 and 3.4. The average of original articles cited by other researchers is 3.9, and there are more articles cited than other journal. The authors of these articles are from the 27 province/or municipalities, Beijing and Shanghai municipalities are in the front of Radiation Oncology research. There are 320 citing journals, and self-citing rate is 9.4%. Conclusions: The Chinese Journal of Radiation Oncology has published high quality articles, and has its own edition characteristics to keep its steady level of research. It is the one of the most important information resource for the radiation oncology researchers and the most important medical journal. (authors)

  2. Advances in radiation oncology in new millennium in Korea

    International Nuclear Information System (INIS)

    Huh, Seung Jae; Park, Charn Il

    2000-01-01

    The objective of recent radiation therapy is to improve the quality of treatment and the after treatment quality of life. In Korea, sharing the same objective, significant advancement was made due to the gradual increase of patient number and rapid increase of treatment facilities. The advancement includes generalization of three-dimensional conformal radiotherapy (3D-CRT), application of linac-based stereotactic radiosurgery (SRS), and furthermore, the introduction of intensity modulated radiation therapy (IMRT). Authors in this paper prospectively review the followings: the advancement of radiation oncology in Korea, the recent status of four-dimensional radiation therapy. IMRT, the concept of the treatment with biological conformity, the trend of combined chemoradiotherapy, the importance of internet and radiation oncology information management system as influenced by the revolution of information technology, and finally the global trend of telemedicine in radiation oncology. Additionally, we suggest the methods to improve radiotherapy treatment, which include improvement of quality assurance (QA) measures by developing Koreanized QA protocol and system, regional study about clinical protocol development for phase three clinical trial, suggestion of unified treatment protocol and guideline by academic or research societies, domestic generation of treatment equipment's or system, establishment of nationwide data base of radiation-oncology-related information, and finally pattems-of-care study about major cancers

  3. Advances in radiation oncology in new millennium in Korea

    Energy Technology Data Exchange (ETDEWEB)

    Huh, Seung Jae [College of Medicine, Sungkyunkwan Univ., Seoul (Korea, Republic of); Park, Charn Il [College of Medicine, Seoul National Univ., Seoul (Korea, Republic of)

    2000-06-01

    The objective of recent radiation therapy is to improve the quality of treatment and the after treatment quality of life. In Korea, sharing the same objective, significant advancement was made due to the gradual increase of patient number and rapid increase of treatment facilities. The advancement includes generalization of three-dimensional conformal radiotherapy (3D-CRT), application of linac-based stereotactic radiosurgery (SRS), and furthermore, the introduction of intensity modulated radiation therapy (IMRT). Authors in this paper prospectively review the followings: the advancement of radiation oncology in Korea, the recent status of four-dimensional radiation therapy. IMRT, the concept of the treatment with biological conformity, the trend of combined chemoradiotherapy, the importance of internet and radiation oncology information management system as influenced by the revolution of information technology, and finally the global trend of telemedicine in radiation oncology. Additionally, we suggest the methods to improve radiotherapy treatment, which include improvement of quality assurance (QA) measures by developing Koreanized QA protocol and system, regional study about clinical protocol development for phase three clinical trial, suggestion of unified treatment protocol and guideline by academic or research societies, domestic generation of treatment equipment's or system, establishment of nationwide data base of radiation-oncology-related information, and finally pattems-of-care study about major cancers.

  4. Safety practices, perceptions, and behaviors in radiation oncology: A national survey of radiation therapists.

    Science.gov (United States)

    Woodhouse, Kristina Demas; Hashemi, David; Betcher, Kathryn; Doucette, Abigail; Weaver, Allison; Monzon, Brian; Rosenthal, Seth A; Vapiwala, Neha

    Radiation therapy is complex and demands high vigilance and precise coordination. Radiation therapists (RTTs) directly deliver radiation and are often the first to discover an error. Yet, few studies have examined the practices of RTTs regarding patient safety. We conducted a national survey to explore the perspectives of RTTs related to quality and safety. In 2016, an electronic survey was sent to a random sample of 1500 RTTs in the United States. The survey assessed department safety, error reporting, safety knowledge, and culture. Questions were multiple choice or recorded on a Likert scale. Results were summarized using descriptive statistics and analyzed using multivariate logistic regression. A total of 702 RTTs from 49 states (47% response rate) completed the survey. Respondents represented a broad distribution across practice settings. Most RTTs rated department patient safety as excellent (61%) or very good (32%), especially if they had an incident learning system (ILS) (odds ratio, 2.0). Only 21% reported using an ILS despite 58% reporting an accessible ILS in their department. RTTs felt errors were most likely to occur with longer shifts and poor multidisciplinary communication; 40% reported that burnout and anxiety negatively affected their ability to deliver care. Workplace bullying was also reported among 17%. Overall, there was interest (62%) in improving knowledge in patient safety. Although most RTTs reported excellent safety cultures within their facilities, overall, there was limited access to and utilization of ILSs by RTTs. Workplace issues identified may also represent barriers to delivering quality care. RTTs were also interested in additional resources regarding quality and safety. These results will further enhance safety initiatives and inform future innovative educational efforts in radiation oncology. Copyright © 2017 American Society for Radiation Oncology. Published by Elsevier Inc. All rights reserved.

  5. Machine learning in radiation oncology theory and applications

    CERN Document Server

    El Naqa, Issam; Murphy, Martin J

    2015-01-01

    ​This book provides a complete overview of the role of machine learning in radiation oncology and medical physics, covering basic theory, methods, and a variety of applications in medical physics and radiotherapy. An introductory section explains machine learning, reviews supervised and unsupervised learning methods, discusses performance evaluation, and summarizes potential applications in radiation oncology. Detailed individual sections are then devoted to the use of machine learning in quality assurance; computer-aided detection, including treatment planning and contouring; image-guided rad

  6. The Pocketable Electronic Devices in Radiation Oncology (PEDRO) Project

    DEFF Research Database (Denmark)

    De Bari, Berardino; Franco, P.; Niyazi, Maximilian

    2016-01-01

    ) members of the national radiation or clinical oncology associations of the countries involved in the study. The 15 items investigated diffusion of MEDs (smartphones and/or tablets), their impact on daily clinical activity, and the differences perceived by participants along time. Results: A total of 386...... in young professionals working in radiation oncology. Looking at these data, it is important to verify the consistency of information found within apps, in order to avoid potential errors eventually detrimental for patients. “Quality assurance” criteria should be specifically developed for medical apps...

  7. Implanted Cardiac Defibrillator Care in Radiation Oncology Patient Population

    International Nuclear Information System (INIS)

    Gelblum, Daphna Y.; Amols, Howard

    2009-01-01

    Purpose: To review the experience of a large cancer center with radiotherapy (RT) patients bearing implantable cardiac defibrillators (ICDs) to propose some preliminary care guidelines as we learn more about the devices and their interaction with the therapeutic radiation environment. Methods and Materials: We collected data on patients with implanted ICDs treated with RT during a 2.5-year period at any of the five Memorial Sloan-Kettering clinical campuses. Information regarding the model, location, and dose detected from the device, as well as the treatment fields, fraction size, and treatment energy was collected. During this time, a new management policy for these patients had been implemented requiring treatment with low-energy beams (6 MV) and close surveillance of the patients in partnership with their electrophysiologist, as they received RT. Results: During the study period, 33 patients were treated with an ICD in place. One patient experienced a default of the device to its initial factory setting that was detected by the patient hearing an auditory signal from the device. This patient had initially been treated with a 15-MV beam. After this episode, his treatment was replanned to be completed with 6-MV photons, and he experienced no further events. Conclusion: Patients with ICDs and other implanted computer-controlled devices will be encountered more frequently in the RT department, and proper management is important. We present a policy for the safe treatment of these patients in the radiation oncology environment.

  8. Health regulations about radiation oncology in Spain: The legislative dilemma between radiation protection and treatment of cancer

    International Nuclear Information System (INIS)

    Esco, R.; Biete, A.; Pardo, J.; Carceller, J.A.; Veira, C.; Palacios, A.; Vazquez, M.G.

    2001-01-01

    The Royal Decree 1566/1998 of July 17th establishes the criteria on quality in radiation therapy and is a cornerstone in Spanish regulation of this medical field. The Royal Decree gives some rules that, from a medical point of view, are considered as a good practice. Radiation protection of patients is necessary to achieve a high quality radiation oncology treatments. That is the reason why Royal decree 1566/1998 is titled 'quality criteria in radiation therapy'. A quality control program must be tailored to every single radiation oncology department and, for this reason, its standardization is difficult. Nevertheless, some medical procedures are defined by the royal decree and such procedures are the minimum criteria that all the departments must follow in the development of its own quality control program. The authors make some reflections about health regulations about radiation oncology in Spain, pointing out that a legislative dilemma between radiation protection and treatment of cancer due to application of the legislative rules may occur. The social and medical cost of rigid bureaucratic procedures is pointed out. A large amount of equipment controls and measurements takes time that could be used in treating patients. This is more important in an environment of limited technical and human resources. (author)

  9. Minimum requirements on a QA program in radiation oncology

    International Nuclear Information System (INIS)

    Almond, P.R.

    1996-01-01

    In April, 1994, the American Association of Physicists in Medicine published a ''Comprehensive QA for radiation oncology:'' a report of the AAPM Radiation Therapy Committee. This is a comprehensive QA program which is likely to become the standard for such programs in the United States. The program stresses the interdisciplinary nature of QA in radiation oncology involving the radiation oncologists, the radiotherapy technologies (radiographers), dosimetrists, and accelerator engineers, as well as the medical physicists. This paper describes a comprehensive quality assurance program with the main emphasis on the quality assurance in radiation therapy using a linear accelerator. The paper deals with QA for a linear accelerator and simulator and QA for treatment planning computers. Next the treatment planning process and QA for individual patients is described. The main features of this report, which should apply to QA programs in any country, emphasizes the responsibilities of the medical physicist. (author). 7 refs, 9 tabs

  10. Minimum requirements on a QA program in radiation oncology

    Energy Technology Data Exchange (ETDEWEB)

    Almond, P R [Louisville Univ., Louisville, KY (United States). J.G. Brown Cancer Center

    1996-08-01

    In April, 1994, the American Association of Physicists in Medicine published a ``Comprehensive QA for radiation oncology:`` a report of the AAPM Radiation Therapy Committee. This is a comprehensive QA program which is likely to become the standard for such programs in the United States. The program stresses the interdisciplinary nature of QA in radiation oncology involving the radiation oncologists, the radiotherapy technologies (radiographers), dosimetrists, and accelerator engineers, as well as the medical physicists. This paper describes a comprehensive quality assurance program with the main emphasis on the quality assurance in radiation therapy using a linear accelerator. The paper deals with QA for a linear accelerator and simulator and QA for treatment planning computers. Next the treatment planning process and QA for individual patients is described. The main features of this report, which should apply to QA programs in any country, emphasizes the responsibilities of the medical physicist. (author). 7 refs, 9 tabs.

  11. Group consensus peer review in radiation oncology: commitment to quality.

    Science.gov (United States)

    Duggar, W Neil; Bhandari, Rahul; Yang, Chunli Claus; Vijayakumar, Srinivasan

    2018-03-27

    Peer review, especially prospective peer review, has been supported by professional organizations as an important element in optimal Radiation Oncology practice based on its demonstration of efficacy at detecting and preventing errors prior to patient treatment. Implementation of peer review is not without barriers, but solutions do exist to mitigate or eliminate some of those barriers. Peer review practice at our institution involves three key elements: new patient conference, treatment planning conference, and chart rounds. The treatment planning conference is an adaptation of the group consensus peer review model from radiology which utilizes a group of peers reviewing each treatment plan prior to implementation. The peer group in radiation oncology includes Radiation Oncologists, Physician Residents, Medical Physicists, Dosimetrists, and Therapists. Thus, technical and clinical aspects of each plan are evaluated simultaneously. Though peer review is held in high regard in Radiation Oncology, many barriers commonly exist preventing optimal implementation such as time intensiveness, repetition, and distraction from clinic time with patients. Through the use of automated review tools and commitment by individuals and administration in regards to staffing, scheduling, and responsibilities, these barriers have been mitigated to implement this Group Consensus Peer Review model into a Radiation Oncology Clinic. A Group Consensus Peer Review model has been implemented with strategies to address common barriers to effective and efficient peer review.

  12. DEGRO 2009. Radiation oncology - medical physics - radiation biology. Abstracts; DEGRO 2009. Radioonkologie - Medizinische Physik - Strahlenbiologie. Abstracts

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2009-06-15

    The special volume of the journal covers the abstracts of the DEGRO 2009 meeting on radiation oncology, medical physics, and radiation biology, covering the following topics: seldom diseases, gastrointestinal tumors, radiation reactions and radiation protection, medical care and science, central nervous system, medical physics, the non-parvicellular lung carcinomas, ear-nose-and throat, target-oriented radiotherapy plus ''X'', radio-oncology - young academics, lymphomas, mammary glands, modern radiotherapy, life quality and palliative radiotherapy, radiotherapy of the prostate carcinoma, imaging for planning and therapy, the digital documentation in clinics and practical experiences, NMR imaging and tomography, hadrons - actual status in Germany, urinal tract oncology, radiotoxicity.

  13. American Society for Radiation Oncology (ASTRO) Survey of Radiation Biology Educators in U.S. and Canadian Radiation Oncology Residency Programs

    International Nuclear Information System (INIS)

    Rosenstein, Barry S.; Held, Kathryn D.; Rockwell, Sara; Williams, Jacqueline P.; Zeman, Elaine M.

    2009-01-01

    Purpose: To obtain, in a survey-based study, detailed information on the faculty currently responsible for teaching radiation biology courses to radiation oncology residents in the United States and Canada. Methods and Materials: In March-December 2007 a survey questionnaire was sent to faculty having primary responsibility for teaching radiation biology to residents in 93 radiation oncology residency programs in the United States and Canada. Results: The responses to this survey document the aging of the faculty who have primary responsibility for teaching radiation biology to radiation oncology residents. The survey found a dramatic decline with time in the percentage of educators whose graduate training was in radiation biology. A significant number of the educators responsible for teaching radiation biology were not fully acquainted with the radiation sciences, either through training or practical application. In addition, many were unfamiliar with some of the organizations setting policies and requirements for resident education. Freely available tools, such as the American Society for Radiation Oncology (ASTRO) Radiation and Cancer Biology Practice Examination and Study Guides, were widely used by residents and educators. Consolidation of resident courses or use of a national radiation biology review course was viewed as unlikely by most programs. Conclusions: A high priority should be given to the development of comprehensive teaching tools to assist those individuals who have responsibility for teaching radiation biology courses but who do not have an extensive background in critical areas of radiobiology related to radiation oncology. These findings also suggest a need for new graduate programs in radiobiology.

  14. Molecular biology in radiation oncology. Radiation oncology perspective of BRCA1 and BRCA2

    International Nuclear Information System (INIS)

    Coleman, C.N.

    1999-01-01

    The breast cancer susceptibility genes, BRCA1 and BRCA2, are used to illustrate the application of molecular biology to clinical radiation oncology. Identified by linkage analysis and cloned, the structure of the genes and the numerous mutations are determined by molecular biology techniques that examine the structure of the DNA and the proteins made by the normal and mutant alleles. Mutations in the non-transcribed portion of the gene will not be found in protein structure assays and may be important in gene function. In addition to potential deleterious mutations, normal polymorphisms of the gene will also be detected, therefore not all differences in gene sequence may represent important mutations, a finding that complicates genetic screening and counseling. The localization of the protein in the nucleus, the expression in relation to cell cycle and the association with RAD51 led to the discovery that the two BRCA genes may be involved in transcriptional regulation and DNA repair. The defect in DNA repair can increase radiosensitivity which might improve local control using breast-conserving treatment in a tumor which is homozygous for the loss of the gene (i.e., BRCA1 and BRCA2 are tumor suppressor genes). This is supported by the early reports of a high rate of local control with breast-conserving therapy. Nonetheless, this radiosensitivity theoretically may also lead to increased susceptibility to carcinogenic effects in surviving cells, a finding that might not be observed for decades. The susceptibility to radiation-induced DNA damage appears also to make the cells more sensitive to chemotherapy. Understanding the role of the normal BRCA genes in DNA repair might help define a novel mechanism for radiation sensitization by interfering with the normal gene function using a variety of molecular or biochemical therapies

  15. Safety and quality assurance management in radiation oncology, What is the role for qualiticians?: example of the Centre Alexis Vautrin; Management de la qualite et de la securite en radiotherapie. Quel role pour les qualiticiens?: exemple au centre Alexis-Vautrin

    Energy Technology Data Exchange (ETDEWEB)

    Aigle, D. [Centre Alexis-Vautrin, Unite qualite et organisation, 54 - Vandoeuvre-les-Nancy (France); Sobczyk, C.; Androni, M.L.; Peiffert, D.; Beckendorf, V.; Marchesi, V.; Buchheit, I.; Noel, A. [Centre Alexis-Vautrin, Dept. de Radiotherapie, 54 - Vandoeuvre-les-Nancy (France)

    2009-10-15

    Since 2007, the Centre Alexis-Vautrin Cancer Institute in Nancy began its safety and quality assurance management policy in the department of radiation oncology. This development induced a collaborative work flow between the quality unit and the department of radiation oncology, with a definition of the responsibilities. The quality unit provides its methodology for the quality assurance, the professionals of the radiation oncology department their expertise. In parallel, a quality referee was nominated in the radiation oncology department to implement the projects for improvement, linked with the quality assurance unit, and under the control of the radiation oncology department staff. (authors)

  16. Assessment of new radiation oncology technology and treatments in radiation oncology the ANROTAT project and collection of IMRT specific data

    International Nuclear Information System (INIS)

    Haworth, A.; Corry, J.; Kron, T.; Duchesne, G.; Ng, M.; Burmeister, B.

    2010-01-01

    Full text: Medical physicists (MP) are familiar with assessing new radiation oncology technology and treatments ( ROT A T) for their own departments but are not usually involved in providing advice to government for funding these technologies. This paper describes the role of the MP within the Commonwealth Government Department of Health and Aging initiative to develop a generic framework for assessment of ROTAT and the collection of data to support Med care Benefits Scheme (MBS) funding of IMRT. The clinical trials group TROG is developing a generic framework for the assessment of NROTAT. This will be tested and data collected to support applications for MBS funding of IMRT and IGRT. The tumour sites of nasopharynx, post-prostatectomy and anal canal have been selected to represent sites that are commonly, occasionally and rarely treated with IMRT respectively. Site selection for data collection will represent a broad range of clinical practices. Data quality is assured through TROG QA procedures and will include dosimetry audits. The final report will assess the clinical efficacy, cost effectiveness and safety of IMRT compared to 3DCRT. Existing clinical trial protocols form the basis for data collection and surrogate endpoints are being developed. Key publications have been identified that correlate specific dose-volume histogram parameters with clinical end-points, recognising limitations of these data in the 1MRT setting. Engagement of MPs within this project will help ensure collection of high quality data that ultimately aims to secure appropriate funding to ensure our patients receive best clinical care. (author)

  17. Project reconversion Service Hospital Radiation Oncology Clinics-Medical School

    International Nuclear Information System (INIS)

    Quarneti, A.; Levaggi, G.

    2004-01-01

    Introduction: The Health Sector operates within the framework of Social Policy and it is therefore one of the ways of distribution of public benefit, like Housing, Education and Social Security. While public spending on health has grown in recent years, its distribution has been uneven and the sector faces funding and management problems. The Service Hospital Radiation Oncology has reduced its health care liavility , lack technological development and unsufficient human resources and training. Aim: developing an inclusive reform bill Service Hospital Radiation Oncology .Material and Methods: This project tends to form a network institutional, introducing concepts of evidence-based medicine, risk models, cost analysis, coding systems, system implementation of quality management (ISO-9000 Standards). Proposes redefining radiotherapy centers and their potential participation in training resource development goals humanos.Promueve scientific research of national interest. Separate strictly administrative function, management and teaching. The project takes into account the characteristics of demand, the need to order it and organize around her, institutional network system and within the Hospital das Clinicas own related services related to Service Hospital Radiation Oncology , Encourages freedom of choice, and confers greater equity in care. The project would managed by the Hospital Clínicas. Conclusions: We believe this proposal identifies problems and opportunities, Service Hospital Radiation Oncology proposes the development of institutional network under one management model

  18. Radiation oncology in the era of precision medicine

    DEFF Research Database (Denmark)

    Baumann, Michael; Krause, Mechthild; Overgaard, Jens

    2016-01-01

    with preservation of health-related quality of life can be achieved in many patients. Two major strategies, acting synergistically, will enable further widening of the therapeutic window of radiation oncology in the era of precision medicine: technology-driven improvement of treatment conformity, including advanced...

  19. Department of Radiation Detectors - Overview

    International Nuclear Information System (INIS)

    Piekoszewski, J.

    1997-01-01

    Work carried out in 1996 in the Department of Radiation Detectors concentrated on three subjects: (i) Semiconductor Detectors (ii) X-ray Tube Generators (iii) Material Modification Using Ion and Plasma Beams. The Departamental objectives are: a search for new types of detectors, adapting modern technologies (especially of industrial microelectronics) to detector manufacturing, producing unique detectors tailored for physics experiments, manufacturing standard detectors for radiation measuring instruments. These objectives were accomplished in 1996 by: research on unique detectors for nuclear physics (e.g. a spherical set of particle detectors silicon ball), detectors for particle identification), development of technology of high-resistivity silicon detectors HRSi (grant proposal), development of thermoelectric cooling systems (grant proposal), research on p-i-n photodiode-based personal dosimeters, study of applicability of industrial planar technology in producing detectors, manufacturing detectors developed in previous years, re-generating and servicing customer detectors of various origin. The Department conducts research on the design and technology involved in producing X-ray generators based on X-ray tubes of special construction. Various tube models and their power supplies were developed. Some work has also been devoted to the detection and dosimetry of X-rays. X-ray tube generators are applied to non-destructive testing and are components of analytical systems such as: X-ray fluorescence chemical composition analysis, gauges of layer thickness and composition stress measurements, on-line control of processes, others where an X-ray tube may replace a radio-isotope source. In 1996, the Department: reviewed the domestic demand for X-ray generators, developed an X-ray generator for diagnosis of ostheroporosis of human limbs, prepared a grant proposal for the development of a new instrument for radiotherapy, the so-called needle-like X-ray tube. (author)

  20. Department of Radiation Detectors - Overview

    Energy Technology Data Exchange (ETDEWEB)

    Piekoszewski, J. [Soltan Inst. for Nuclear Studies, Otwock-Swierk (Poland)

    1997-12-31

    Work carried out in 1996 in the Department of Radiation Detectors concentrated on three subjects: (i) Semiconductor Detectors (ii) X-ray Tube Generators (iii) Material Modification Using Ion and Plasma Beams. The Departamental objectives are: a search for new types of detectors, adapting modern technologies (especially of industrial microelectronics) to detector manufacturing, producing unique detectors tailored for physics experiments, manufacturing standard detectors for radiation measuring instruments. These objectives were accomplished in 1996 by: research on unique detectors for nuclear physics (e.g. a spherical set of particle detectors silicon ball), detectors for particle identification), development of technology of high-resistivity silicon detectors HRSi (grant proposal), development of thermoelectric cooling systems (grant proposal), research on p-i-n photodiode-based personal dosimeters, study of applicability of industrial planar technology in producing detectors, manufacturing detectors developed in previous years, re-generating and servicing customer detectors of various origin. The Department conducts research on the design and technology involved in producing X-ray generators based on X-ray tubes of special construction. Various tube models and their power supplies were developed. Some work has also been devoted to the detection and dosimetry of X-rays. X-ray tube generators are applied to non-destructive testing and are components of analytical systems such as: X-ray fluorescence chemical composition analysis, gauges of layer thickness and composition stress measurements, on-line control of processes, others where an X-ray tube may replace a radio-isotope source. In 1996, the Department: reviewed the domestic demand for X-ray generators, developed an X-ray generator for diagnosis of ostheroporosis of human limbs, prepared a grant proposal for the development of a new instrument for radiotherapy, the so-called needle-like X-ray tube. (author).

  1. "Radio-oncomics" : The potential of radiomics in radiation oncology.

    Science.gov (United States)

    Peeken, Jan Caspar; Nüsslin, Fridtjof; Combs, Stephanie E

    2017-10-01

    Radiomics, a recently introduced concept, describes quantitative computerized algorithm-based feature extraction from imaging data including computer tomography (CT), magnetic resonance imaging (MRT), or positron-emission tomography (PET) images. For radiation oncology it offers the potential to significantly influence clinical decision-making and thus therapy planning and follow-up workflow. After image acquisition, image preprocessing, and defining regions of interest by structure segmentation, algorithms are applied to calculate shape, intensity, texture, and multiscale filter features. By combining multiple features and correlating them with clinical outcome, prognostic models can be created. Retrospective studies have proposed radiomics classifiers predicting, e. g., overall survival, radiation treatment response, distant metastases, or radiation-related toxicity. Besides, radiomics features can be correlated with genomic information ("radiogenomics") and could be used for tumor characterization. Distinct patterns based on data-based as well as genomics-based features will influence radiation oncology in the future. Individualized treatments in terms of dose level adaption and target volume definition, as well as other outcome-related parameters will depend on radiomics and radiogenomics. By integration of various datasets, the prognostic power can be increased making radiomics a valuable part of future precision medicine approaches. This perspective demonstrates the evidence for the radiomics concept in radiation oncology. The necessity of further studies to integrate radiomics classifiers into clinical decision-making and the radiation therapy workflow is emphasized.

  2. Radiation protection in radio-oncology

    International Nuclear Information System (INIS)

    Hartz, Juliane Marie; Joost, Sophie; Hildebrandt, Guido

    2017-01-01

    Based on the high technical status of radiation protection the occupational exposure of radiological personnel is no more of predominant importance. No defined dose limits exist for patients in the frame of therapeutic applications in contrary to the radiological personnel. As a consequence walk-downs radiotherapeutic institutions twice the year have been initiated in order to guarantee a maximum of radiation protection for patient's treatment. An actualization of radiation protection knowledge of the radiological personnel is required.

  3. An Increase in Medical Student Knowledge of Radiation Oncology: A Pre-Post Examination Analysis of the Oncology Education Initiative

    International Nuclear Information System (INIS)

    Hirsch, Ariel E.; Mulleady Bishop, Pauline; Dad, Luqman; Singh, Deeptej; Slanetz, Priscilla J.

    2009-01-01

    Purpose: The Oncology Education Initiative was created to advance oncology and radiation oncology education by integrating structured didactics into the existing core radiology clerkship. We set out to determine whether the addition of structured didactics could lead to a significant increase in overall medical student knowledge about radiation oncology. Methods and Materials: We conducted a pre- and posttest examining concepts in general radiation oncology, breast cancer, and prostate cancer. The 15-question, multiple-choice exam was administered before and after a 1.5-hour didactic lecture by an attending physician in radiation oncology. Individual question changes, overall student changes, and overall categorical changes were analyzed. All hypothesis tests were two-tailed (significance level 0.05). Results: Of the 153 fourth-year students, 137 (90%) took the pre- and posttest and were present for the didactic lecture. The average test grade improved from 59% to 70% (p = 0.011). Improvement was seen in all questions except clinical vignettes involving correct identification of TNM staging. Statistically significant improvement (p ≤ 0.03) was seen in the questions regarding acute and late side effects of radiation, brachytherapy for prostate cancer, delivery of radiation treatment, and management of early-stage breast cancer. Conclusions: Addition of didactics in radiation oncology significantly improves medical students' knowledge of the topic. Despite perceived difficulty in teaching radiation oncology and the assumption that it is beyond the scope of reasonable knowledge for medical students, we have shown that even with one dedicated lecture, students can learn and absorb general principles regarding radiation oncology

  4. Grade Inflation in Medical Student Radiation Oncology Clerkships: Missed Opportunities for Feedback?

    International Nuclear Information System (INIS)

    Grover, Surbhi; Swisher-McClure, Samuel; Sosnowicz, Stasha; Li, Jiaqi; Mitra, Nandita; Berman, Abigail T.; Baffic, Cordelia; Vapiwala, Neha; Freedman, Gary M.

    2015-01-01

    Purpose: To test the hypothesis that medical student radiation oncology elective rotation grades are inflated and cannot be used to distinguish residency applicants. Methods and Materials: The records of 196 applicants to a single radiation oncology residency program in 2011 and 2012 were retrospectively reviewed. The grades for each rotation in radiation oncology were collected and converted to a standardized 4-point grading scale (honors, high pass, pass, fail). Pass/fail grades were scored as not applicable. The primary study endpoint was to compare the distribution of applicants' grades in radiation oncology with their grades in medicine, surgery, pediatrics, and obstetrics/gynecology core clerkships. Results: The mean United States Medical Licensing Examination Step 1 score of the applicants was 237 (range, 188-269), 43% had additional Masters or PhD degrees, and 74% had at least 1 publication. Twenty-nine applicants were graded for radiation oncology rotations on a pass/fail basis and were excluded from the final analysis. Of the remaining applicants (n=167), 80% received the highest possible grade for their radiation oncology rotations. Grades in radiation oncology were significantly higher than each of the other 4 clerkships studied (P<.001). Of all applicants, 195 of 196 matched into a radiation oncology residency. Higher grades in radiation oncology were associated with significantly higher grades in the pediatrics core clerkship (P=.002). However, other medical school performance metrics were not significantly associated with higher grades in radiation oncology. Conclusions: Although our study group consists of a selected group of radiation oncology applicants, their grades in radiation oncology clerkships were highly skewed toward the highest grades when compared with grades in other core clerkships. Student grading in radiation oncology clerkships should be re-evaluated to incorporate more objective and detailed performance metrics to allow for

  5. Radiation Research Department annual report 2002

    International Nuclear Information System (INIS)

    Majborn, B.; Damkjaer. A.; Nielsen, S.P.

    2003-06-01

    The report presents a summary of the work of the Radiation Research Department in 2002. The departments research and development activities are organized in two research programmes: 'Radiation Physics' and 'Radioecology and Tracer Studies'. In addition the department is responsible for the task 'Dosimetry'. Lists of publications, committee memberships and staff members are included. (au)

  6. [Possibilities and perspectives of quality management in radiation oncology].

    Science.gov (United States)

    Seegenschmiedt, M H; Zehe, M; Fehlauer, F; Barzen, G

    2012-11-01

    The medical discipline radiation oncology and radiation therapy (treatment with ionizing radiation) has developed rapidly in the last decade due to new technologies (imaging, computer technology, software, organization) and is one of the most important pillars of tumor therapy. Structure and process quality play a decisive role in the quality of outcome results (therapy success, tumor response, avoidance of side effects) in this field. Since 2007 all institutions in the health and social system are committed to introduce and continuously develop a quality management (QM) system. The complex terms of reference, the complicated technical instruments, the highly specialized personnel and the time-consuming processes for planning, implementation and assessment of radiation therapy made it logical to introduce a QM system in radiation oncology, independent of the legal requirements. The Radiation Center Hamburg (SZHH) has functioned as a medical care center under medical leadership and management since 2009. The total QM and organization system implemented for the Radiation Center Hamburg was prepared in 2008 and 2009 and certified in June 2010 by the accreditation body (TÜV-Süd) for DIN EN ISO 9001:2008. The main function of the QM system of the SZHH is to make the basic principles understandable for insiders and outsiders, to have clear structures, to integrate management principles into the routine and therefore to organize the learning processes more effectively both for interior and exterior aspects.

  7. Target volume definition in radiation oncology

    CERN Document Server

    Grosu, Anca-Ligia

    2015-01-01

    The main objective of this book is to provide radiation oncologists with a clear, up-to-date guide to tumor delineation and contouring of organs at risk. With this in mind, a detailed overview of recent advances in imaging for radiation treatment planning is presented. Novel concepts for target volume delineation are explained, taking into account the innovations in imaging technology. Special attention is paid to the role of the newer imaging modalities, such as positron emission tomography and diffusion and perfusion magnetic resonance imaging. All of the most important tumor entities treate

  8. Toward a national consensus: teaching radiobiology to radiation oncology residents

    International Nuclear Information System (INIS)

    Zeman, Elaine M.; Dynlacht, Joseph R.; Rosenstein, Barry S.; Dewhirst, Mark W.

    2002-01-01

    Purpose: The ASTRO Joint Working Group on Radiobiology Teaching, a committee composed of members having affiliations with several national radiation oncology and biology-related societies and organizations, commissioned a survey designed to address issues of manpower, curriculum standardization, and instructor feedback as they relate to resident training in radiation biology. Methods and Materials: Radiation biology instructors at U.S. radiation oncology training programs were identified and asked to respond to a comprehensive electronic questionnaire dealing with instructor educational background, radiation biology course content, and sources of feedback with respect to curriculum planning and resident performance on standardized radiation biology examinations. Results: Eighty-five radiation biology instructors were identified, representing 73 radiation oncology residency training programs. A total of 52 analyzable responses to the questionnaire were received, corresponding to a response rate of 61.2%. Conclusion: There is a decreasing supply of instructors qualified to teach classic, and to some extent, clinical, radiobiology to radiation oncology residents. Additionally, those instructors with classic training in radiobiology are less likely to be comfortable teaching cancer molecular biology or other topics in cancer biology. Thus, a gap exists in teaching the whole complement of cancer and radiobiology curricula, particularly in those programs in which the sole responsibility for teaching falls to one faculty member (50% of training programs are in this category). On average, the percentage of total teaching time devoted to classic radiobiology (50%), clinical radiobiology (30%), and molecular and cancer biology (20%) is appropriate, relative to the current makeup of the board examination. Nevertheless large variability exists between training programs with respect to the total number of contact hours per complete radiobiology course (ranging from

  9. The radiation oncology workforce: A focus on medical dosimetry

    Energy Technology Data Exchange (ETDEWEB)

    Robinson, Gregg F., E-mail: grobinson@medicaldosimetry.org [American Association of Medical Dosimetrists, Herndon, VA (United States); Mobile, Katherine [American Association of Medical Dosimetrists, Herndon, VA (United States); Yu, Yan [Thomas Jefferson University, Philadelphia, PA (United States)

    2014-07-01

    The 2012 Radiation Oncology Workforce survey was conducted to assess the current state of the entire workforce, predict its future needs and concerns, and evaluate quality improvement and safety within the field. This article describes the dosimetrist segment results. The American Society for Radiation Oncology (ASTRO) Workforce Subcommittee, in conjunction with other specialty societies, conducted an online survey targeting all segments of the radiation oncology treatment team. The data from the dosimetrist respondents are presented in this article. Of the 2573 dosimetrists who were surveyed, 890 responded, which resulted in a 35% segment response rate. Most respondents were women (67%), whereas only a third were men (33%). More than half of the medical dosimetrists were older than 45 years (69.2%), whereas the 45 to 54 years age group represented the highest percentage of respondents (37%). Most medical dosimetrists stated that their workload was appropriate (52%), with respondents working a reported average of 41.7 ± 4 hours per week. Overall, 86% of medical dosimetrists indicated that they were satisfied with their career, and 69% were satisfied in their current position. Overall, 61% of respondents felt that there was an oversupply of medical dosimetrists in the field, 14% reported that supply and demand was balanced, and the remaining 25% felt that there was an undersupply. The medical dosimetrists' greatest concerns included documentation/paperwork (78%), uninsured patients (80%), and insufficient reimbursement rates (87%). This survey provided an insight into the dosimetrist perspective of the radiation oncology workforce. Though an overwhelming majority has conveyed satisfaction concerning their career, the study allowed a spotlight to be placed on the profession's current concerns, such as insufficient reimbursement rates and possible oversupply of dosimetrists within the field.

  10. The radiation oncology workforce: A focus on medical dosimetry

    International Nuclear Information System (INIS)

    Robinson, Gregg F.; Mobile, Katherine; Yu, Yan

    2014-01-01

    The 2012 Radiation Oncology Workforce survey was conducted to assess the current state of the entire workforce, predict its future needs and concerns, and evaluate quality improvement and safety within the field. This article describes the dosimetrist segment results. The American Society for Radiation Oncology (ASTRO) Workforce Subcommittee, in conjunction with other specialty societies, conducted an online survey targeting all segments of the radiation oncology treatment team. The data from the dosimetrist respondents are presented in this article. Of the 2573 dosimetrists who were surveyed, 890 responded, which resulted in a 35% segment response rate. Most respondents were women (67%), whereas only a third were men (33%). More than half of the medical dosimetrists were older than 45 years (69.2%), whereas the 45 to 54 years age group represented the highest percentage of respondents (37%). Most medical dosimetrists stated that their workload was appropriate (52%), with respondents working a reported average of 41.7 ± 4 hours per week. Overall, 86% of medical dosimetrists indicated that they were satisfied with their career, and 69% were satisfied in their current position. Overall, 61% of respondents felt that there was an oversupply of medical dosimetrists in the field, 14% reported that supply and demand was balanced, and the remaining 25% felt that there was an undersupply. The medical dosimetrists' greatest concerns included documentation/paperwork (78%), uninsured patients (80%), and insufficient reimbursement rates (87%). This survey provided an insight into the dosimetrist perspective of the radiation oncology workforce. Though an overwhelming majority has conveyed satisfaction concerning their career, the study allowed a spotlight to be placed on the profession's current concerns, such as insufficient reimbursement rates and possible oversupply of dosimetrists within the field

  11. Health Economics in Radiation Oncology: Introducing the ESTRO HERO project

    International Nuclear Information System (INIS)

    Lievens, Yolande; Grau, Cai

    2012-01-01

    New evidence based regimens and novel high precision technology have reinforced the important role of radiotherapy in the management of cancer. Current data estimate that more than 50% of all cancer patients would benefit from radiotherapy during the course of their disease. Within recent years, the radiotherapy community has become more than conscious of the ever-increasing necessity to come up with objective data to endorse the crucial role and position of radiation therapy within the rapidly changing global oncology landscape. In an era of ever expanding health care costs, proven safety and effectiveness is not sufficient anymore to obtain funding, objective data about cost and cost-effectiveness are nowadays additionally requested. It is in this context that ESTRO is launching the HERO-project (Health Economics in Radiation Oncology), with the overall aim to develop a knowledge base and a model for health economic evaluation of radiation treatments at the European level. To accomplish these objectives, the HERO project will address needs, accessibility, cost and cost-effectiveness of radiotherapy. The results will raise the profile of radiotherapy in the European cancer management context and help countries prioritizing radiotherapy as a highly cost-effective treatment strategy. This article describes the different steps and aims within the HERO-project, starting from evidence on the role of radiotherapy within the global oncology landscape and highlighting weaknesses that may undermine this position.

  12. Health economics in radiation oncology: introducing the ESTRO HERO project.

    Science.gov (United States)

    Lievens, Yolande; Grau, Cai

    2012-04-01

    New evidence based regimens and novel high precision technology have reinforced the important role of radiotherapy in the management of cancer. Current data estimate that more than 50% of all cancer patients would benefit from radiotherapy during the course of their disease. Within recent years, the radiotherapy community has become more than conscious of the ever-increasing necessity to come up with objective data to endorse the crucial role and position of radiation therapy within the rapidly changing global oncology landscape. In an era of ever expanding health care costs, proven safety and effectiveness is not sufficient anymore to obtain funding, objective data about cost and cost-effectiveness are nowadays additionally requested. It is in this context that ESTRO is launching the HERO-project (Health Economics in Radiation Oncology), with the overall aim to develop a knowledge base and a model for health economic evaluation of radiation treatments at the European level. To accomplish these objectives, the HERO project will address needs, accessibility, cost and cost-effectiveness of radiotherapy. The results will raise the profile of radiotherapy in the European cancer management context and help countries prioritizing radiotherapy as a highly cost-effective treatment strategy. This article describes the different steps and aims within the HERO-project, starting from evidence on the role of radiotherapy within the global oncology landscape and highlighting weaknesses that may undermine this position. Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.

  13. Carcinoma of the urethra: radiation oncology.

    Science.gov (United States)

    Koontz, Bridget F; Lee, W Robert

    2010-08-01

    Urethral cancer is a rare but aggressive neoplasm. Early-stage distal lesions can be successfully treated with a single modality. Results for definitive radiotherapy using either or both external beam radiation therapy and brachytherapy have shown excellent cure rates in men and women. The primary advantage of radiotherapy is organ preservation. Advanced tumors, however, have poor outcomes with single modality treatment. Results have been improved using a combination of radiotherapy and chemotherapy, chiefly 5-fluorouracil and mitomycin C. Although literature is limited to case reports because of the rarity of the disease, the markedly improved results compared with older results of surgery with or without radiation warrant consideration. Copyright 2010 Elsevier Inc. All rights reserved.

  14. Present status and future aspects of radiation oncology in Korea

    International Nuclear Information System (INIS)

    Huh, Seung Jae

    2006-01-01

    An analysis of the infrastructure for radiotherapy in Korea was performed to establish a baseline plan in 2006 for future development. The data were obtained from 61 radiotherapy centers. The survey covered then number of radiotherapy centers, major equipment and personnel. Centers were classified into technical level groups according to the IAEA criteria. 28,789 new patients were treated with radiation therapy in 2004. There were 104 megavoltage devices in 61 institutions, which included 96 linear accelerators, two Cobalt 60 units, three Tomotherapy units, two Cyberknife units and one proton accelerator in 2006. Thirty-five high dose rate remote after-loading systems and 20 CT-simulators were surveyed. Personnel included 132 radiation oncologists, 50 radiation oncology residents, 64 medical physicists, 130 nurses and 369 radiation therapy technologists. All of the facilities employed treatment-planning computers and simulators, among these thirty-two percent (20 facilities) used a CT-simulator. Sixty-six percent (40 facilities) used a PET/CT scanner, and 35% (22 facilities) had the capacity to implement intensity modulated radiation therapy. Twenty-five facilities (41%) were included in technical level 3 group (having one of intensity modulated radiotherapy, stereotactic radiotherapy or intra-operative radiotherapy system). Radiation oncology in Korea evolved greatly in both quality and quantity recently and demand for radiotherapy in Korea is increasing steadily. The information in this analysis represents important data to develop the future planning of equipment and human resources

  15. Radiation oncology training in the United States: report from the Radiation Oncology Resident Training Working Group organized by the Society of Chairman of Academic Radiation Oncology Programs (SCAROP)

    International Nuclear Information System (INIS)

    1999-01-01

    Purpose: In response to the major changes occurring in healthcare, medical education, and cancer research, SCAROP addressed issues related to post-graduate education that could enhance existing programs and complement the present system. Methods and Materials: SCAROP brought together a Working Group with a broad range of representatives organized in subcommittees to address: training, curriculum, and model building. Results: The Working Group emphasized the importance of training physicians with the necessary clinical, scientific, and analytical skills, and the need to provide expert radiation oncology services to patients throughout the United States. Opportunities currently exist for graduates in academic medicine, although there may be limited time and financial resources available to support academic pursuits. Conclusions: In the face of diminishing resources for training and education and the increased scope of knowledge required, a number of models for resident training are considered that can provide flexibility to complement the present system. This report is intended to initiate dialogue among the organizations responsible for radiation oncology resident education so that resident training can continually evolve to meet the needs of cancer patients and take advantage of opportunities for progress through innovative cancer care and research

  16. A National Radiation Oncology Medical Student Clerkship Survey: Didactic Curricular Components Increase Confidence in Clinical Competency

    Energy Technology Data Exchange (ETDEWEB)

    Jagadeesan, Vikrant S. [Department of Radiation and Cellular Oncology, Pritzker School of Medicine, University of Chicago, Chicago, Illinois (United States); Raleigh, David R. [Department of Radiation Oncology, School of Medicine, University of California–San Francisco, San Francisco, California (United States); Koshy, Matthew; Howard, Andrew R.; Chmura, Steven J. [Department of Radiation and Cellular Oncology, Pritzker School of Medicine, University of Chicago, Chicago, Illinois (United States); Golden, Daniel W., E-mail: dgolden@radonc.uchicago.edu [Department of Radiation and Cellular Oncology, Pritzker School of Medicine, University of Chicago, Chicago, Illinois (United States)

    2014-01-01

    Purpose: Students applying to radiation oncology residency programs complete 1 or more radiation oncology clerkships. This study assesses student experiences and perspectives during radiation oncology clerkships. The impact of didactic components and number of clerkship experiences in relation to confidence in clinical competency and preparation to function as a first-year radiation oncology resident are evaluated. Methods and Materials: An anonymous, Internet-based survey was sent via direct e-mail to all applicants to a single radiation oncology residency program during the 2012-2013 academic year. The survey was composed of 3 main sections including questions regarding baseline demographic information and prior radiation oncology experience, rotation experiences, and ideal clerkship curriculum content. Results: The survey response rate was 37% (70 of 188). Respondents reported 191 unique clerkship experiences. Of the respondents, 27% (19 of 70) completed at least 1 clerkship with a didactic component geared towards their level of training. Completing a clerkship with a didactic component was significantly associated with a respondent's confidence to function as a first-year radiation oncology resident (Wilcoxon rank–sum P=.03). However, the total number of clerkships completed did not correlate with confidence to pursue radiation oncology as a specialty (Spearman ρ P=.48) or confidence to function as a first year resident (Spearman ρ P=.43). Conclusions: Based on responses to this survey, rotating students perceive that the majority of radiation oncology clerkships do not have formal didactic curricula. Survey respondents who completed a clerkship with a didactic curriculum reported feeling more prepared to function as a radiation oncology resident. However, completing an increasing number of clerkships does not appear to improve confidence in the decision to pursue radiation oncology as a career or to function as a radiation oncology resident. These

  17. A national radiation oncology medical student clerkship survey: didactic curricular components increase confidence in clinical competency.

    Science.gov (United States)

    Jagadeesan, Vikrant S; Raleigh, David R; Koshy, Matthew; Howard, Andrew R; Chmura, Steven J; Golden, Daniel W

    2014-01-01

    Students applying to radiation oncology residency programs complete 1 or more radiation oncology clerkships. This study assesses student experiences and perspectives during radiation oncology clerkships. The impact of didactic components and number of clerkship experiences in relation to confidence in clinical competency and preparation to function as a first-year radiation oncology resident are evaluated. An anonymous, Internet-based survey was sent via direct e-mail to all applicants to a single radiation oncology residency program during the 2012-2013 academic year. The survey was composed of 3 main sections including questions regarding baseline demographic information and prior radiation oncology experience, rotation experiences, and ideal clerkship curriculum content. The survey response rate was 37% (70 of 188). Respondents reported 191 unique clerkship experiences. Of the respondents, 27% (19 of 70) completed at least 1 clerkship with a didactic component geared towards their level of training. Completing a clerkship with a didactic component was significantly associated with a respondent's confidence to function as a first-year radiation oncology resident (Wilcoxon rank-sum P=.03). However, the total number of clerkships completed did not correlate with confidence to pursue radiation oncology as a specialty (Spearman ρ P=.48) or confidence to function as a first year resident (Spearman ρ P=.43). Based on responses to this survey, rotating students perceive that the majority of radiation oncology clerkships do not have formal didactic curricula. Survey respondents who completed a clerkship with a didactic curriculum reported feeling more prepared to function as a radiation oncology resident. However, completing an increasing number of clerkships does not appear to improve confidence in the decision to pursue radiation oncology as a career or to function as a radiation oncology resident. These results support further development of structured didactic

  18. A National Radiation Oncology Medical Student Clerkship Survey: Didactic Curricular Components Increase Confidence in Clinical Competency

    International Nuclear Information System (INIS)

    Jagadeesan, Vikrant S.; Raleigh, David R.; Koshy, Matthew; Howard, Andrew R.; Chmura, Steven J.; Golden, Daniel W.

    2014-01-01

    Purpose: Students applying to radiation oncology residency programs complete 1 or more radiation oncology clerkships. This study assesses student experiences and perspectives during radiation oncology clerkships. The impact of didactic components and number of clerkship experiences in relation to confidence in clinical competency and preparation to function as a first-year radiation oncology resident are evaluated. Methods and Materials: An anonymous, Internet-based survey was sent via direct e-mail to all applicants to a single radiation oncology residency program during the 2012-2013 academic year. The survey was composed of 3 main sections including questions regarding baseline demographic information and prior radiation oncology experience, rotation experiences, and ideal clerkship curriculum content. Results: The survey response rate was 37% (70 of 188). Respondents reported 191 unique clerkship experiences. Of the respondents, 27% (19 of 70) completed at least 1 clerkship with a didactic component geared towards their level of training. Completing a clerkship with a didactic component was significantly associated with a respondent's confidence to function as a first-year radiation oncology resident (Wilcoxon rank–sum P=.03). However, the total number of clerkships completed did not correlate with confidence to pursue radiation oncology as a specialty (Spearman ρ P=.48) or confidence to function as a first year resident (Spearman ρ P=.43). Conclusions: Based on responses to this survey, rotating students perceive that the majority of radiation oncology clerkships do not have formal didactic curricula. Survey respondents who completed a clerkship with a didactic curriculum reported feeling more prepared to function as a radiation oncology resident. However, completing an increasing number of clerkships does not appear to improve confidence in the decision to pursue radiation oncology as a career or to function as a radiation oncology resident. These results

  19. Radiation oncology in Australia: a historical and evolutionary perspective

    International Nuclear Information System (INIS)

    Sandeman, T.F.

    1996-01-01

    This presentation tracks the development of the therapeutic application of radiation in Australia. Within six months of Roentgen's discovery, the Crooke's x-ray tube and later a radium plaque was used in Australia for treatment, in particular by the dermatologists. By 1920s radiology was an established specialty. A series of conferences was held between 1930 and 1940 to discuss the provision of cancer treatment, the integration of research and particularly, the establishment of central registry. The author also paid tribute to a a series of scientific personalities for their contribution to the Australian radiation oncology. 22 refs., ills

  20. Radiation oncology: radiobiological and physiological perspectives

    International Nuclear Information System (INIS)

    Awwad, H.K.

    1990-01-01

    This book deals with the normal tissue and tumor radiation-induced responses in terms of the underlying radiobiological and physiological process. Coverage includes the following topics: Functional test for normal tissue responses. Relation to the underlying target cell, Clinical structural end-points, e.g., increased lung density in CT-scan. Conditions and parameters of the LQ-model in clinical applications. An NSD-type of formalism is still clinically applicable. Clinical importance of the kinetics of recovery. The notion of normal tissue tolerance and tumor control. The steepness of the response curve. How accurate radiotherpy should be. The volume effect: clinical, biological and physiological perspectives. The tumor bed effect, residual damage and the problems of reirradiation. Radiation-induced perturbations of the immune response. Clinical consequences. Exploitation to a therapeutic benefit. Hypoxia in human solid tumors. Probing and methods of control. Growth of human tumors. Parameters, measurement and clinical implications. The dose-rate effect. The optimum use of low dose rate irradiation in human cancer

  1. Interventional Radiation Oncology (IRO): Transition of a magnetic resonance simulator to a brachytherapy suite.

    Science.gov (United States)

    Anderson, Roberta; Armour, Elwood; Beeckler, Courtney; Briner, Valerie; Choflet, Amanda; Cox, Andrea; Fader, Amanda N; Hannah, Marie N; Hobbs, Robert; Huang, Ellen; Kiely, Marilyn; Lee, Junghoon; Morcos, Marc; McMillan, Paige E; Miller, Dave; Ng, Sook Kien; Prasad, Rashmi; Souranis, Annette; Thomsen, Robert; DeWeese, Theodore L; Viswanathan, Akila N

    2018-03-13

    As a core component of a new gynecologic cancer radiation program, we envisioned, structured, and implemented a novel Interventional Radiation Oncology (IRO) unit and magnetic resonance (MR)-brachytherapy environment in an existing MR simulator. We describe the external and internal processes required over a 6-8 month time frame to develop a clinical and research program for gynecologic brachytherapy and to successfully convert an MR simulator into an IRO unit. Support of the institution and department resulted in conversion of an MR simulator to a procedural suite. Development of the MR gynecologic brachytherapy program required novel equipment, staffing, infrastructural development, and cooperative team development with anesthetists, nurses, therapists, physicists, and physicians to ensure a safe and functional environment. Creation of a separate IRO unit permitted a novel billing structure. The creation of an MR-brachytherapy environment in an MR simulator is feasible. Developing infrastructure includes several collaborative elements. Unique to the field of radiation oncology, formalizing the space as an Interventional Radiation Oncology unit permits a sustainable financial structure. Copyright © 2018 American Brachytherapy Society. Published by Elsevier Inc. All rights reserved.

  2. Oncologic emergencies in a cancer center emergency department and in general emergency departments countywide and nationwide.

    Science.gov (United States)

    Yang, Zhi; Yang, Runxiang; Kwak, Min Ji; Qdaisat, Aiham; Lin, Junzhong; Begley, Charles E; Reyes-Gibby, Cielito C; Yeung, Sai-Ching Jim

    2018-01-01

    Although cancer patients (CPs) are increasingly likely to visit emergency department (ED), no population-based study has compared the characteristics of CPs and non-cancer patients (NCPs) who visit the ED and examined factors associated with hospitalization via the ED. In this study, we (1) compared characteristics and diagnoses between CPs and NCPs who visited the ED in a cancer center or general hospital; (2) compared characteristics and diagnoses between CPs and NCPs who were hospitalized via the ED in a cancer center or general hospital; and (3) investigated important factors associated with such hospitalization. We analyzed patient characteristic and diagnosis [based on International Classification of Diseases-9 (ICD-9) codes] data from the ED of a comprehensive cancer center (MDACC), 24 general EDs in Harris County, Texas (HCED), and the National Hospital Ambulatory Medical Care Survey (NHAMCS) from 1/1/2007-12/31/2009. Approximately 3.4 million ED visits were analyzed: 47,245, 3,248,973, and 104,566 visits for MDACC, HCED, and NHAMCS, respectively, of which 44,143 (93.4%), 44,583 (1.4%), and 632 (0.6%) were CP visits. CPs were older than NCPs and stayed longer in EDs. Lung, gastrointestinal (excluding colorectal), and genitourinary (excluding prostate) cancers were the three most common diagnoses related to ED visits at general EDs. CPs visiting MDACC were more likely than CPs visiting HCED to be privately insured. CPs were more likely than NCPs to be hospitalized. Pneumonia and influenza, fluid and electrolyte disorders, and fever were important predictive factors for CP hospitalization; coronary artery disease, cerebrovascular disease, and heart failure were important factors for NCP hospitalization. CPs consumed more ED resources than NCPs and had a higher hospitalization rate. Given the differences in characteristics and diagnoses between CPs and NCPs, ED physicians must pay special attention to CPs and be familiar with their unique set of oncologic

  3. ASTRO's core physics curriculum for radiation oncology residents

    International Nuclear Information System (INIS)

    Klein, Eric E.; Balter, James M.; Chaney, Edward L.; Gerbi, Bruce J.; Hughes, Lesley

    2004-01-01

    In 2002, the Radiation Physics Committee of the American Society of Therapeutic Radiology and Oncology (ASTRO) appointed an Ad-hoc Committee on Physics Teaching to Medical Residents. The main initiative of the committee was to develop a core curriculum for physics education. Prior publications that have analyzed physics teaching have pointed to wide discrepancies among teaching programs. The committee was composed of physicists or physicians from various residency program based institutions. Simultaneously, members had associations with the American Association of Physicists in Medicine (AAPM), ASTRO, Association of Residents in Radiation Oncology (ARRO), American Board of Radiology (ABR), and the American College of Radiology (ACR). The latter two organizations' representatives were on the physics examination committees, as one of the main agendas was to provide a feedback loop between the examining organizations and ASTRO. The document resulted in a recommended 54-h course. Some of the subjects were based on American College of Graduate Medical Education (ACGME) requirements (particles, hyperthermia), whereas the majority of the subjects along with the appropriated hours per subject were devised and agreed upon by the committee. For each subject there are learning objectives and for each hour there is a detailed outline of material to be covered. Some of the required subjects/h are being taught in most institutions (i.e., Radiation Measurement and Calibration for 4 h), whereas some may be new subjects (4 h of Imaging for Radiation Oncology). The curriculum was completed and approved by the ASTRO Board in late 2003 and is slated for dissemination to the community in 2004. It is our hope that teaching physicists will adopt the recommended curriculum for their classes, and simultaneously that the ABR for its written physics examination and the ACR for its training examination will use the recommended curriculum as the basis for subject matter and depth of

  4. Evaluation of Health Economics in Radiation Oncology: A Systematic Review

    Energy Technology Data Exchange (ETDEWEB)

    Nguyen, Timothy K.; Goodman, Chris D. [Department of Radiation Oncology, London Regional Cancer Program, London, Ontario (Canada); Boldt, R. Gabriel [London Health Sciences Centre, London, Ontario (Canada); Warner, Andrew; Palma, David A. [Department of Radiation Oncology, London Regional Cancer Program, London, Ontario (Canada); Rodrigues, George B. [Department of Radiation Oncology, London Regional Cancer Program, London, Ontario (Canada); Department of Epidemiology and Biostatistics, Western University, London, Ontario (Canada); Lock, Michael I. [Department of Radiation Oncology, London Regional Cancer Program, London, Ontario (Canada); Mishra, Mark V. [Department of Radiation Oncology, University of Maryland, Baltimore, Maryland (United States); Zaric, Gregory S. [Department of Epidemiology and Biostatistics, Western University, London, Ontario (Canada); Ivey Business School, Western University, London, Ontario (Canada); Louie, Alexander V., E-mail: Dr.alexlouie@gmail.com [Department of Radiation Oncology, London Regional Cancer Program, London, Ontario (Canada); Department of Epidemiology and Biostatistics, Western University, London, Ontario (Canada)

    2016-04-01

    Purpose: Despite the rising costs in radiation oncology, the impact of health economics research on radiation therapy practice analysis patterns is unclear. We performed a systematic review of cost-effectiveness analyses (CEAs) and cost-utility analyses (CUAs) to identify trends in reporting quality in the radiation oncology literature over time. Methods and Materials: A systematic review of radiation oncology economic evaluations up to 2014 was performed, using MEDLINE and EMBASE databases. The Consolidated Health Economic Evaluation Reporting Standards guideline informed data abstraction variables including study demographics, economic parameters, and methodological details. Tufts Medical Center CEA registry quality scores provided a basis for qualitative assessment of included studies. Studies were stratified by 3 time periods (1995-2004, 2005-2009, and 2010-2014). The Cochran-Armitage trend test and linear trend test were used to identify trends over time. Results: In total, 102 articles were selected for final review. Most studies were in the context of a model (61%) or clinical trial (28%). Many studies lacked a conflict of interest (COI) statement (67%), a sponsorship statement (48%), a reported study time horizon (35%), and the use of discounting (29%). There was a significant increase over time in the reporting of a COI statement (P<.001), health care payer perspective (P=.019), sensitivity analyses using multivariate (P=.043) or probabilistic methods (P=.011), incremental cost-effectiveness threshold (P<.001), secondary source utility weights (P=.010), and cost effectiveness acceptability curves (P=.049). There was a trend toward improvement in Tuft scores over time (P=.065). Conclusions: Recent reports demonstrate improved reporting rates in economic evaluations; however, there remains significant room for improvement as reporting rates are still suboptimal. As fiscal pressures rise, we will rely on economic assessments to guide our practice decisions

  5. Evaluation of Health Economics in Radiation Oncology: A Systematic Review

    International Nuclear Information System (INIS)

    Nguyen, Timothy K.; Goodman, Chris D.; Boldt, R. Gabriel; Warner, Andrew; Palma, David A.; Rodrigues, George B.; Lock, Michael I.; Mishra, Mark V.; Zaric, Gregory S.; Louie, Alexander V.

    2016-01-01

    Purpose: Despite the rising costs in radiation oncology, the impact of health economics research on radiation therapy practice analysis patterns is unclear. We performed a systematic review of cost-effectiveness analyses (CEAs) and cost-utility analyses (CUAs) to identify trends in reporting quality in the radiation oncology literature over time. Methods and Materials: A systematic review of radiation oncology economic evaluations up to 2014 was performed, using MEDLINE and EMBASE databases. The Consolidated Health Economic Evaluation Reporting Standards guideline informed data abstraction variables including study demographics, economic parameters, and methodological details. Tufts Medical Center CEA registry quality scores provided a basis for qualitative assessment of included studies. Studies were stratified by 3 time periods (1995-2004, 2005-2009, and 2010-2014). The Cochran-Armitage trend test and linear trend test were used to identify trends over time. Results: In total, 102 articles were selected for final review. Most studies were in the context of a model (61%) or clinical trial (28%). Many studies lacked a conflict of interest (COI) statement (67%), a sponsorship statement (48%), a reported study time horizon (35%), and the use of discounting (29%). There was a significant increase over time in the reporting of a COI statement (P<.001), health care payer perspective (P=.019), sensitivity analyses using multivariate (P=.043) or probabilistic methods (P=.011), incremental cost-effectiveness threshold (P<.001), secondary source utility weights (P=.010), and cost effectiveness acceptability curves (P=.049). There was a trend toward improvement in Tuft scores over time (P=.065). Conclusions: Recent reports demonstrate improved reporting rates in economic evaluations; however, there remains significant room for improvement as reporting rates are still suboptimal. As fiscal pressures rise, we will rely on economic assessments to guide our practice decisions

  6. Results of the 1993 Association of Residents in Radiation Oncology survey

    International Nuclear Information System (INIS)

    Ling, Stella M.; Flynn, Daniel F.

    1996-01-01

    In 1993, the Association of Residents in Radiation Oncology (ARRO) conducted its tenth annual survey of all residents training in radiation oncology in the United States. The characteristics of current residents are described. Factors influencing the choice of Radiation Oncology as a medical specialty, and posttraining career plans were identified. Residents raised issues on the adequacy of training, problems in work routine, and expressed concerns about board certification and recertification, and about decreased future practice opportunities

  7. Establishing a Global Radiation Oncology Collaboration in Education (GRaCE)

    DEFF Research Database (Denmark)

    Turner, Sandra; Eriksen, Jesper G; Trotter, Theresa

    2015-01-01

    Representatives from countries and regions world-wide who have implemented modern competency-based radiation- or clinical oncology curricula for training medical specialists, met to determine the feasibility and value of an ongoing international collaboration. In this forum, educational leaders...... with similar goals, would provide a valuable vehicle to ensure training program currency, through sharing of resources and expertise, and enhance high quality radiation oncology education. Potential projects for the Global Radiation Oncology Collaboration in Education (GRaCE) were agreed upon...

  8. A new ambulatory classification and funding model for radiation oncology: non-admitted patients in Victorian hospitals.

    Science.gov (United States)

    Antioch, K M; Walsh, M K; Anderson, D; Wilson, R; Chambers, C; Willmer, P

    1998-01-01

    The Victorian Department of Human Services has developed a classification and funding model for non-admitted radiation oncology patients. Agencies were previously funded on an historical cost input basis. For 1996-97, payments were made according to the new Non-admitted Radiation Oncology Classification System and include four key components. Fixed grants are based on Weighted Radiation Therapy Services targets for megavoltage courses, planning procedures (dosimetry and simulation) and consultations. The additional throughput pool covers additional Weighted Radiation Therapy Services once targets are reached, with access conditional on the utilisation of a minimum number of megavoltage fields by each hospital. Block grants cover specialised treatments, such as brachytherapy, allied health payments and other support services. Compensation grants were available to bring payments up to the level of the previous year. There is potential to provide incentives to promote best practice in Australia through linking appropriate practice to funding models. Key Australian and international developments should be monitored, including economic evaluation studies, classification and funding models, and the deliberations of the American College of Radiology, the American Society for Therapeutic Radiology and Oncology, the Trans-Tasman Radiation Oncology Group and the Council of Oncology Societies of Australia. National impact on clinical practice guidelines in Australia can be achieved through the Quality of Care and Health Outcomes Committee of the National Health and Medical Research Council.

  9. Radiation Research Department annual report 2002

    Energy Technology Data Exchange (ETDEWEB)

    Majborn, B.; Damkjaer, A.; Nielsen, S.P. (eds.)

    2003-06-01

    The report presents a summary of the work of the Radiation Research Department in 2002. The departments research and development activities are organized in two research programmes: 'Radiation Physics' and 'Radioecology and Tracer Studies'. In addition the department is responsible for the task 'Dosimetry'. Lists of publications, committee memberships and staff members are included. (au)

  10. Industry Funding Among Leadership in Medical Oncology and Radiation Oncology in 2015.

    Science.gov (United States)

    Yoo, Stella K; Ahmed, Awad A; Ileto, Jan; Zaorsky, Nicholas G; Deville, Curtiland; Holliday, Emma B; Wilson, Lynn D; Jagsi, Reshma; Thomas, Charles R

    2017-10-01

    To quantify and determine the relationship between oncology departmental/division heads and private industry vis-à-vis potential financial conflict of interests (FCOIs) as publicly reported by the Centers for Medicare and Medicaid Services Open Payments database. We extracted the names of the chairs/chiefs in medical oncology (MO) and chairs of radiation oncology (RO) for 81 different institutions with both RO and MO training programs as reported by the Association of American Medical Colleges. For each leader, the amount of consulting fees and research payments received in 2015 was determined. Logistic modeling was used to assess associations between the 2 endpoints of receiving a consulting fee and receiving a research payment with various institution-specific and practitioner-specific variables included as covariates: specialty, sex, National Cancer Institute designation, PhD status, and geographic region. The majority of leaders in MO were reported to have received consulting fees or research payments (69.5%) compared with a minority of RO chairs (27.2%). Among those receiving payments, the average (range) consulting fee was $13,413 ($200-$70,423) for MO leaders and $6463 ($837-$16,205) for RO chairs; the average research payment for MO leaders receiving payments was $240,446 ($156-$1,234,762) and $295,089 ($160-$1,219,564) for RO chairs. On multivariable regression when the endpoint was receipt of a research payment, those receiving a consulting fee (odds ratio [OR]: 5.34; 95% confidence interval [CI]: 2.22-13.65) and MO leaders (OR: 5.54; 95% CI: 2.62-12.18) were more likely to receive research payments. Examination of the receipt of consulting fees as the endpoint showed that those receiving a research payment (OR: 5.41; 95% CI: 2.23-13.99) and MO leaders (OR: 3.06; 95% CI: 1.21-8.13) were more likely to receive a consulting fee. Leaders in academic oncology receive consulting or research payments from industry. Relationships between oncology leaders and

  11. Development of radiation oncology learning system combined with multi-institutional radiotherapy database (ROGAD)

    International Nuclear Information System (INIS)

    Takemura, Akihiro; Iinuma, Masahiro; Kou, Hiroko; Harauchi, Hajime; Inamura, Kiyonari

    1999-01-01

    We have constructed and are operating a multi-institutional radiotherapy database ROGAD (Radiation Oncology Greater Area Database) since 1992. One of it's purpose is 'to optimize individual radiotherapy plans'. We developed Radiation oncology learning system combined with ROGAD' which conforms to that purpose. Several medical doctors evaluated our system. According to those evaluations, we are now confident that our system is able to contribute to improvement of radiotherapy results. Our final target is to generate a good cyclic relationship among three components: radiotherapy results according to ''Radiation oncology learning system combined with ROGAD.'; The growth of ROGAD; and radiation oncology learning system. (author)

  12. International Outreach: What Is the Responsibility of ASTRO and the Major International Radiation Oncology Societies?

    International Nuclear Information System (INIS)

    Mayr, Nina A.; Hu, Kenneth S.; Liao, Zhongxing; Viswanathan, Akila N.; Wall, Terry J.; Amendola, Beatriz E.; Calaguas, Miriam J.; Palta, Jatinder R.; Yue, Ning J.; Rengan, Ramesh; Williams, Timothy R.

    2014-01-01

    In this era of globalization and rapid advances in radiation oncology worldwide, the American Society for Radiation Oncology (ASTRO) is committed to help decrease profound regional disparities through the work of the International Education Subcommittee (IES). The IES has expanded its base, reach, and activities to foster educational advances through a variety of educational methods with broad scope, in addition to committing to the advancement of radiation oncology care for cancer patients around the world, through close collaboration with our sister radiation oncology societies and other educational, governmental, and organizational groups

  13. International Outreach: What Is the Responsibility of ASTRO and the Major International Radiation Oncology Societies?

    Energy Technology Data Exchange (ETDEWEB)

    Mayr, Nina A., E-mail: ninamayr@uw.edu [Department of Radiation Oncology, University of Washington School of Medicine, Seattle, Washington (United States); Hu, Kenneth S. [Department of Radiation Oncology, Beth Israel Medical Center, New York, New York (United States); Liao, Zhongxing [Department of Radiation Oncology, University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Viswanathan, Akila N. [Department of Radiation Oncology, Dana-Farber/Brigham and Women' s Cancer Center, Harvard Medical School, Boston, Massachusetts (United States); Wall, Terry J. [St. Luke' s Cancer Institute, Kansas City, Missouri (United States); Amendola, Beatriz E. [Innovative Cancer Institute, Miami, Florida (United States); Calaguas, Miriam J. [Department of Radiation Oncology, St. Luke' s Medical Center, Quezon City (Philippines); Palta, Jatinder R. [Department of Radiation Oncology, Virginia Commonwealth University, Richmond, Virginia (United States); Yue, Ning J. [Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New Brunswick, New Jersey (United States); Rengan, Ramesh [Department of Radiation Oncology, University of Washington School of Medicine, Seattle, Washington (United States); Williams, Timothy R. [Lynn Cancer Institute, Boca Raton Regional Hospital, Boca Raton, Florida (United States)

    2014-07-01

    In this era of globalization and rapid advances in radiation oncology worldwide, the American Society for Radiation Oncology (ASTRO) is committed to help decrease profound regional disparities through the work of the International Education Subcommittee (IES). The IES has expanded its base, reach, and activities to foster educational advances through a variety of educational methods with broad scope, in addition to committing to the advancement of radiation oncology care for cancer patients around the world, through close collaboration with our sister radiation oncology societies and other educational, governmental, and organizational groups.

  14. Clinical trial or standard treatment? Shared decision making at the department of oncology

    DEFF Research Database (Denmark)

    Gregersen, Trine Ammentorp; Birkelund, Regner; Ammentorp, Jette

    2016-01-01

    Title: Clinical trial or standard treatment? Shared decision making at the department of oncology. Authors: Ph.d. student, Trine A. Gregersen. Trine.gregersen@rsyd.dk. Department of Oncology. Health Services Research Unit Lillebaelt Hospital / IRS University of Southern Denmark. Professor, Regner...... are involved in difficult treatment decisions including participation in clinical trials. The literature indicates that the decision is very often based on little knowledge about the treatment and that many patients who have consented to participate in a clinical trial are not always aware...... that they are participating in a trial. This place great demand on the healthcare providers’ ability to involve and advise patients in the decisions. The aim of this study is to investigate the characteristics of the communication when decisions about participation in clinical oncology trial are made and the patients...

  15. The role of imaging in pediatric radiation oncology

    International Nuclear Information System (INIS)

    Stowe, S.M.

    1985-01-01

    The pediatric radiation oncologist is involved in treating a different spectrum of tumors that is generally seen by the adult radiation oncologist. More than one-third of pediatric patients with malignancies suffer from acute lymphocytic leukemia and lymphomas. Approximately one-quarter of the patients have primary tumors of the brain and central nervous system, while the remaining patients mostly present with mesenchymal sarcomas as opposed to the carcinomas more generally seen in adult practice. Pediatric tumors are frequently deep seated and therefore more difficult to evaluate by physical examination that the typical adult epithelial tumors. In the following sections, the various tumor types and locations are discussed with reference to the specific imaging requirements for each of the groups. This is preceded by a brief introduction to modern radiation oncology in order to clarify the role of these modalities

  16. Development of new on-line statistical program for the Korean Society for Radiation Oncology.

    Science.gov (United States)

    Song, Si Yeol; Ahn, Seung Do; Chung, Weon Kuu; Shin, Kyung Hwan; Choi, Eun Kyung; Cho, Kwan Ho

    2015-06-01

    To develop new on-line statistical program for the Korean Society for Radiation Oncology (KOSRO) to collect and extract medical data in radiation oncology more efficiently. The statistical program is a web-based program. The directory was placed in a sub-folder of the homepage of KOSRO and its web address is http://www.kosro.or.kr/asda. The operating systems server is Linux and the webserver is the Apache HTTP server. For database (DB) server, MySQL is adopted and dedicated scripting language is the PHP. Each ID and password are controlled independently and all screen pages for data input or analysis are made to be friendly to users. Scroll-down menu is actively used for the convenience of user and the consistence of data analysis. Year of data is one of top categories and main topics include human resource, equipment, clinical statistics, specialized treatment and research achievement. Each topic or category has several subcategorized topics. Real-time on-line report of analysis is produced immediately after entering each data and the administrator is able to monitor status of data input of each hospital. Backup of data as spread sheets can be accessed by the administrator and be used for academic works by any members of the KOSRO. The new on-line statistical program was developed to collect data from nationwide departments of radiation oncology. Intuitive screen and consistent input structure are expected to promote entering data of member hospitals and annual statistics should be a cornerstone of advance in radiation oncology.

  17. Development of new on line statistical program for the Korean society for radiation oncology

    International Nuclear Information System (INIS)

    Song, Si Yeol; Ahn, Seung Do; Choi, Eun Kyung; Chung, Weon Kuu; Shin, Kyung Hwan; Cho, Kwan Ho

    2015-01-01

    To develop new on-line statistical program for the Korean Society for Radiation Oncology (KOSRO) to collect and extract medical data in radiation oncology more efficiently. The statistical program is a web-based program. The directory was placed in a sub-folder of the homepage of KOSRO and its web address is http://www.kosro.or.kr/asda. The operating systems server is Linux and the webserver is the Apache HTTP server. For database (DB) server, MySQL is adopted and dedicated scripting language is the PHP. Each ID and password are controlled independently and all screen pages for data input or analysis are made to be friendly to users. Scroll-down menu is actively used for the convenience of user and the consistence of data analysis. Year of data is one of top categories and main topics include human resource, equipment, clinical statistics, specialized treatment and research achievement. Each topic or category has several subcategorized topics. Real-time on-line report of analysis is produced immediately after entering each data and the administrator is able to monitor status of data input of each hospital. Backup of data as spread sheets can be accessed by the administrator and be used for academic works by any members of the KOSRO. The new on-line statistical program was developed to collect data from nationwide departments of radiation oncology. Intuitive screen and consistent input structure are expected to promote entering data of member hospitals and annual statistics should be a cornerstone of advance in radiation oncology

  18. Development of new on line statistical program for the Korean society for radiation oncology

    Energy Technology Data Exchange (ETDEWEB)

    Song, Si Yeol; Ahn, Seung Do; Choi, Eun Kyung [Dept. of Radiation Oncology, Asan Medical Center, University of Ulsan College of Medicine, Seoul (Korea, Republic of); Chung, Weon Kuu [Dept. of Radiation Oncology, Kyung Hee University Hospital at Kangdong, Kyung Hee University School of Medicine, Seoul (Korea, Republic of); Shin, Kyung Hwan [Dept. of Radiation Oncology, Seoul National University Hospital, Seoul National University College of Medicine, Seoul (Korea, Republic of); Cho, Kwan Ho [Dept. of Radiation Oncology, Proton Therapy Center, National Cancer Center Hospital, Goyang (Korea, Republic of)

    2015-06-15

    To develop new on-line statistical program for the Korean Society for Radiation Oncology (KOSRO) to collect and extract medical data in radiation oncology more efficiently. The statistical program is a web-based program. The directory was placed in a sub-folder of the homepage of KOSRO and its web address is http://www.kosro.or.kr/asda. The operating systems server is Linux and the webserver is the Apache HTTP server. For database (DB) server, MySQL is adopted and dedicated scripting language is the PHP. Each ID and password are controlled independently and all screen pages for data input or analysis are made to be friendly to users. Scroll-down menu is actively used for the convenience of user and the consistence of data analysis. Year of data is one of top categories and main topics include human resource, equipment, clinical statistics, specialized treatment and research achievement. Each topic or category has several subcategorized topics. Real-time on-line report of analysis is produced immediately after entering each data and the administrator is able to monitor status of data input of each hospital. Backup of data as spread sheets can be accessed by the administrator and be used for academic works by any members of the KOSRO. The new on-line statistical program was developed to collect data from nationwide departments of radiation oncology. Intuitive screen and consistent input structure are expected to promote entering data of member hospitals and annual statistics should be a cornerstone of advance in radiation oncology.

  19. The American Society for Radiation Oncology's 2010 Core Physics Curriculum for Radiation Oncology Residents

    Energy Technology Data Exchange (ETDEWEB)

    Xiao Ying, E-mail: ying.xiao@jefferson.edu [Thomas Jefferson University Hospital, Philadelphia, PA (United States); De Amorim Bernstein, Karen [Montefiore Medical Center, Bronx, NY (United States); Chetty, Indrin J. [Henry Ford Health System, Detroit, MI (United States); Eifel, Patricia [M. D. Anderson Cancer Center, Houston, TX (United States); Hughes, Lesley [Cooper University Hospital, Camden, NJ (United States); Klein, Eric E. [Washington University, Saint Louis, MO (United States); McDermott, Patrick [William Beaumont Hospital, Royal Oak, MI (United States); Prisciandaro, Joann [University of Michigan, Ann Arbor, MI (United States); Paliwal, Bhudatt [University of Wisconsin, Madison, WI (United States); Price, Robert A. [Fox Chase Cancer Center, Philadelphia, PA (United States); Werner-Wasik, Maria [Thomas Jefferson University Hospital, Philadelphia, PA (United States); Palta, Jatinder R. [University of Florida, Gainesville, FL (United States)

    2011-11-15

    Purpose: In 2004, the American Society for Radiation Oncology (ASTRO) published its first physics education curriculum for residents, which was updated in 2007. A committee composed of physicists and physicians from various residency program teaching institutions was reconvened again to update the curriculum in 2009. Methods and Materials: Members of this committee have associations with ASTRO, the American Association of Physicists in Medicine, the Association of Residents in Radiation Oncology, the American Board of Radiology (ABR), and the American College of Radiology. Members reviewed and updated assigned subjects from the last curriculum. The updated curriculum was carefully reviewed by a representative from the ABR and other physics and clinical experts. Results: The new curriculum resulted in a recommended 56-h course, excluding initial orientation. Learning objectives are provided for each subject area, and a detailed outline of material to be covered is given for each lecture hour. Some recent changes in the curriculum include the addition of Radiation Incidents and Bioterrorism Response Training as a subject and updates that reflect new treatment techniques and modalities in a number of core subjects. The new curriculum was approved by the ASTRO board in April 2010. We anticipate that physicists will use this curriculum for structuring their teaching programs, and subsequently the ABR will adopt this educational program for its written examination. Currently, the American College of Radiology uses the ASTRO curriculum for their training examination topics. In addition to the curriculum, the committee updated suggested references and the glossary. Conclusions: The ASTRO physics education curriculum for radiation oncology residents has been updated. To ensure continued commitment to a current and relevant curriculum, the subject matter will be updated again in 2 years.

  20. The History and Role of Accelerators in Radiation Oncology

    Science.gov (United States)

    Smith, Alfred

    2003-04-01

    Over one million people are diagnosed with cancer (excluding skin cancer) each year in the United States - about half of those patients will receive radiation as part of their treatment. Radiation Oncology is the field of medicine that specializes in the treatment of cancer with radiation. The evolution of Radiation Oncology, and its success as a cancer treatment modality, has generally paralleled developments in imaging and accelerator technologies. Accelerators, the topic of this paper, have proven to be highly reliable, safe and efficient sources of radiation for cancer treatment. Advances in accelerator technology, especially those that have provided higher energies and dose rates, and more localized (to the tumor volume) dose distributions, have enabled significant improvements in the outcomes of cancer treatments. The use of Cobalt 60 beams has greatly declined in the past decade. Radiation beams used in cancer treatment include x-rays, electrons, protons, negative pions, neutrons, and ions of helium, carbon, neon and silicon. X-rays and electrons, produced by linear electron accelerators, have been the most widely used. The history of medical accelerators can be traced from Roentgen's discovery of x-rays in 1895. The evolution of medical electron accelerators will be discussed and the use of x-ray tubes, electrostatic accelerators, betatrons, and linear accelerators will be described. Heavy particle cancer treatments began in 1955 using proton beams from the Berkeley 184-inch cyclotron. Accelerators that have been used for heavy particle therapy include the Berkeley Bevalac, Los Alamos Pion Facility, Fermi Laboratory, and various research and medical cyclotrons and synchrotrons. Heavy particle accelerators and their application for cancer treatment will be discussed.

  1. Ethics in the Legal and Business Practices of Radiation Oncology.

    Science.gov (United States)

    Wall, Terry J

    2017-10-01

    Ethical issues arise when a professional endeavor such as medicine, which seeks to place the well-being of others over the self-interest of the practitioner, meets granular business and legal decisions involved in making a livelihood out of a professional calling. The use of restrictive covenants, involvement in self-referral patterns, and maintaining appropriate comity among physicians while engaged in the marketplace are common challenges in radiation oncology practice. A paradigm of analysis is presented to help navigate these management challenges. Copyright © 2017 Elsevier Inc. All rights reserved.

  2. Radiation Research Department annual report 2003

    DEFF Research Database (Denmark)

    Majborn, Benny; Damkjær, A.; Nielsen, Sven Poul

    2004-01-01

    This report presents a summary of the work of the Radiation Research Department in 2003. The main research areas were dosimetry, nuclear emergency preparedness, radioecology, and radioanalytical techniques. List of publications, committee memberships andstaff members are included....

  3. Radiation Research Department annual report 2003

    Energy Technology Data Exchange (ETDEWEB)

    Majborn, B.; Damkjaer, A.; Nielsen, S.P. (eds.)

    2004-06-01

    This report presents a summary of the work of the Radiation Research Department in 2003. The main research areas were dosimetry, nuclear emergency preparedness, radioecology, and radioanalytical techniques. Lists of publications, committee memberships and staff members are included. (au)

  4. The role of medical physicists in developing a generic research framework for the assessment of new radiation oncology technology and treatments in radiation oncology

    International Nuclear Information System (INIS)

    Grand, M.M.; Amin, R.; Cornes, D.A.; Duchesne, G.; Haworth, A.; Kron, T.; Burmeister, B.

    2010-01-01

    Full text: TROG Cancer Research has secured funding from the Australian Government Department of Health and Ageing to develop and pilot an evaluation framework for new radiation oncology technologies and treatments. Four site specific projects will be undertaken to test the framework including IMRT for nasopharynx, anal canal and post-prostatectomy and IGRT for prostate fiducial markers. Multidisciplinary Expert Groups that include medical physicists, have been appointed for each site specific project. Each project will collect data from at least ten treatment centres who have been credentialed. The Framework will have the capacity to gather information to substantiate the clinical efficacy and cost effectiveness of new technologies and treatments in radiation oncology. The framework will be tested by gathering data to evaluate the superiority of IMRT and lGRT over other treatments and economic analysis will examine the potential trade-off between efficiency and the clinical gains to a patient. It is anticipated that the outcome of this research will inform future funding decisions. The involvement of medical physicists has been central to development of the framework, protocol development and the credentialing process. (author)

  5. Description of the role of nonphysician practitioners in radiation oncology

    International Nuclear Information System (INIS)

    Kelvin, Joanne Frankel; Moore-Higgs, Giselle Josephine

    1999-01-01

    Purpose: With changes in reimbursement and a decrease in the number of residents, there is a need to explore new ways of achieving high-quality patient care in radiation oncology. One mechanism is the implementation of nonphysician practitioner roles. The purpose of this paper is to describe the roles and responsibilities of clinical nurse specialists (CNSs), nurse practitioners (NPs), and physician assistants (PAs) currently working in the field of radiation oncology in the United States. Methods and Materials: A nationwide mailing was sent to elicit responses to an 8-page self-report questionnaire. Results: The final sample of 86 included 45 (52%) CNSs, 31 (36%) NPs, and 10 (12%) PAs. Two-thirds worked in private practice settings. Most of the nonphysician practitioners frequently obtained histories (57-90%) and ordered laboratory studies (52-68%). However, NPs and PAs were more likely than CNSs to frequently perform 'medical' services such as perform physical exams (42-80% vs. 19-36%), order radiologic studies (50% vs. 17%), and prescribe medication (60-84% vs. 26%). CNSs were more likely to provide 'supportive' services such as develop educational materials, participate in quality improvement initiatives, and develop policies and procedures. Conclusions: Nonphysician practitioners are not substituting for physicians, but rather are working in collaboration with them, performing designated tasks

  6. Monoclonal antibodies: potential role in radiation therapy and oncology

    International Nuclear Information System (INIS)

    Order, S.E.

    1982-01-01

    Specificity, which is a hallmark of the immune system, will be used in radiation oncology in both diagnosis and therapy through the application of radiolabelled monoclonal and polyclonal antibodies. Antigenic specificities, antibody preparations, and the tumor as a target for radiolabelled antibody is reviewed. Several clinical situations, i.e. single tumor cell suspensions, intraperitoneal single cells and masses, and solid tumors are reviewed in regard to both immune antibody targeting and specific differences between tumors in these regions. The concentration of tumor associated antigens is introductory to radiolabelled antibodies in diagnosis. In the radiation therapy of solid tumors, data regarding tumor dose, tumor effective half-life, varied antibody preparations, and the use of radiolabelled antibody as a method of tumor implantation is discussed using antiferritin 131 I-IgG as a model in hepatoma. The theoretical applications of monoclonal antibody integrated in cancer therapy are then presented as a new goal for future development

  7. Radiation oncology training in Poland: results of a national survey (2007)

    International Nuclear Information System (INIS)

    Niemiec, M.; Kepka, L.; Lindner, B.; Bujko, K.; Lindner, B.; Maciejewski, B.

    2008-01-01

    The aim of this survey was to evaluate the quality of training in radiation oncology in Poland in relation to the ESTRO recommendations, and to learn motivations, level of satisfaction, complaints, suggestions and career plans of radiation oncologists.The detailed questionnaire was addressed to radiation oncologists from all centres in Poland who have been certified as specialists after 1990. Of the 212 approached, 103 radiation oncologists responded to the questionnaire (49%). In general, 40% of respondents declared that the majority of tutors/supervisors devoted sufficient time to their training (60% in academic, 28% in regional centres); 60% had access to the literature, and 50% to the internet. The number of treated patients during the training period ranged from 10 to 3000 (median: 375). 69% of the respondents completed a training in another Polish oncology centre (median duration - 2 months), 21% underwent such training abroad, 55% attended international courses/ conferences. Respondents from academic centres had access and attended national and/or international training more often than those from regional centres. Financial matters have been listed as a major obstacle for out-door training by 93% of respondents. 64% of respondents were pleased or rather pleased with the general quality of training, and the remaining 36% were unsatisfied (these mainly from regional centres). Considering career plans, 72% respondents wanted to continue practice at their employing institutions; however 24% have declared a wish to continue their career abroad. This first national survey has shown some weak points in radiotherapy training in Poland, mainly the quality differences between the departments in favour of academic centres. Some of the problems can and should be solved by the Polish Society of Radiation Oncology, others need legislation changes and decisions at the level of the Ministry of Health. (authors)

  8. Implementing and Integrating a Clinically-Driven Electronic Medical Record (EMR for Radiation Oncology in a Large Medical Enterprise

    Directory of Open Access Journals (Sweden)

    John Paxton Kirkpatrick

    2013-04-01

    Full Text Available Purpose/Objective: While our department is heavily invested in computer-based treatment planning, we historically relied on paper-based charts for management of Radiation Oncology patients. In early 2009, we initiated the process of conversion to an electronic medical record (EMR eliminating the need for paper charts. Key goals included the ability to readily access information wherever and whenever needed, without compromising safety, treatment quality, confidentiality or productivity.Methodology: In February, 2009, we formed a multi-disciplinary team of Radiation Oncology physicians, nurses, therapists, administrators, physicists/dosimetrists, and information technology (IT specialists, along with staff from the Duke Health System IT department. The team identified all existing processes and associated information/reports, established the framework for the EMR system and generated, tested and implemented specific EMR processes.Results: Two broad classes of information were identified: information which must be readily accessed by anyone in the health system versus that used solely within the Radiation Oncology department. Examples of the former are consultation reports, weekly treatment check notes and treatment summaries; the latter includes treatment plans, daily therapy records and quality assurance reports. To manage the former, we utilized the enterprise-wide system , which required an intensive effort to design and implement procedures to export information from Radiation Oncology into that system. To manage "Radiation Oncology" data, we used our existing system (ARIA, Varian Medical Systems. The ability to access both systems simultaneously from a single workstation (WS was essential, requiring new WS and modified software. As of January, 2010, all new treatments were managed solely with an EMR. We find that an EMR makes information more widely accessible and does not compromise patient safety, treatment quality or confidentiality

  9. American Society for Radiation Oncology (ASTRO) 2012 Workforce Study: The Radiation Oncologists' and Residents' Perspectives

    International Nuclear Information System (INIS)

    Pohar, Surjeet; Fung, Claire Y.; Hopkins, Shane; Miller, Robert; Azawi, Samar; Arnone, Anna; Patton, Caroline; Olsen, Christine

    2013-01-01

    Purpose: The American Society for Radiation Oncology (ASTRO) conducted the 2012 Radiation Oncology Workforce Survey to obtain an up-to-date picture of the workforce, assess its needs and concerns, and identify quality and safety improvement opportunities. The results pertaining to radiation oncologists (ROs) and residents (RORs) are presented here. Methods: The ASTRO Workforce Subcommittee, in collaboration with allied radiation oncology professional societies, conducted a survey study in early 2012. An online survey questionnaire was sent to all segments of the radiation oncology workforce. Respondents who were actively working were included in the analysis. This manuscript describes the data for ROs and RORs. Results: A total of 3618 ROs and 568 RORs were surveyed. The response rate for both groups was 29%, with 1047 RO and 165 ROR responses. Among ROs, the 2 most common racial groups were white (80%) and Asian (15%), and the male-to-female ratio was 2.85 (74% male). The median age of ROs was 51. ROs averaged 253.4 new patient consults in a year and 22.9 on-treatment patients. More than 86% of ROs reported being satisfied or very satisfied overall with their career. Close to half of ROs reported having burnout feelings. There was a trend toward more frequent burnout feelings with increasing numbers of new patient consults. ROs' top concerns were related to documentation, reimbursement, and patients' health insurance coverage. Ninety-five percent of ROs felt confident when implementing new technology. Fifty-one percent of ROs thought that the supply of ROs was balanced with demand, and 33% perceived an oversupply. Conclusions: This study provides a current snapshot of the 2012 radiation oncology physician workforce. There was a predominance of whites and men. Job satisfaction level was high. However a substantial fraction of ROs reported burnout feelings. Perceptions about supply and demand balance were mixed. ROs top concerns reflect areas of attention for the

  10. Risk management of radiation therapy. Survey by north Japan radiation therapy oncology group

    International Nuclear Information System (INIS)

    Aoki, Masahiko; Abe, Yoshinao; Yamada, Shogo; Hareyama, Masato; Nakamura, Ryuji; Sugita, Tadashi; Miyano, Takashi

    2004-01-01

    A North Japan Radiation Oncology Group (NJRTOG) survey was carried out to disclose the risk management of radiation therapy. During April 2002, we sent questionnaires to radiation therapy facilities in northern Japan. There were 31 replies from 27 facilities. Many incidents and accidents were reported, including old cases. Although 60% of facilities had a risk management manual and/or risk manager, only 20% had risk management manuals for radiation therapy. Eighty five percent of radiation oncologists thought that incidents may be due to a lack of manpower. Ninety percent of radiation oncologists want to know the type of cases happened in other facilities. The risk management system is still insufficient for radiation therapy. We hope that our data will be a great help to develop risk management strategies for radiation therapy for all radiation oncologists in Japan. (author)

  11. The teaching of physics and related courses to residents in radiation oncology

    International Nuclear Information System (INIS)

    Dunscombe, P.

    1989-01-01

    A survey of physics and related teaching to radiation oncology residents in 21 Canadian cancer centres was undertaken in December 1987 and January 1988. This survey illustrates a very considerable variation in the formal teaching of physics to aspiring radiation oncologists with, for example, the number of hours offered ranging from 40 to 160 in those 10 centres that have a training program. It would appear to be of benefit to radiation oncology residents, those charged with teaching them, and the radiation oncology community as a whole, to develop specific guidelines for this aspect of resident education. (8 refs., tab.)

  12. Positron emission tomography in pediatric radiation oncology: integration in the treatment-planning process

    International Nuclear Information System (INIS)

    Krasin, M.J.; Hudson, M.M.; Kaste, S.C.

    2004-01-01

    The application of PET imaging to pediatric radiation oncology allows new approaches to targeting and selection of radiation dose based not only on the size of a tumor, but also on its metabolic activity. In order to integrate PET into treatment planning for radiation oncology, logistical issues regarding patient setup, image fusion, and target selection must be addressed. Through prospective study, the role of PET in pediatric malignancies will be established for diagnosis, treatment, and surveillance. To explore the potential role of PET and its incorporation into treatment planning in pediatric radiation oncology, an example case of pediatric Hodgkin's disease is discussed. (orig.)

  13. Is there a role for radiation therapists within veterinary oncology?

    Energy Technology Data Exchange (ETDEWEB)

    Surjan, Yolanda, E-mail: Yolanda.Surjan@newcastle.edu.au [Medical Radiation Science (MRS), School of Health Sciences, University of Newcastle, Callaghan, NSW 2308 (Australia); Warren-Forward, Helen [Medical Radiation Science (MRS), School of Health Sciences, University of Newcastle, Callaghan, NSW 2308 (Australia); Milross, Christopher [Department of Radiation Oncology, Royal Prince Alfred Hospital, Camperdown, Sydney (Australia)

    2011-08-15

    Role expansion recognises enlargement of existing scope of practice within radiation therapy (RT). Over the past decade, there has been increasing involvement and movement towards advanced practice in the form of role extension in specialised areas of practice including brachytherapy, image fusion and quality assurance. It is also recognised that radiation therapy expert practitioners exist in the areas of imaging immobilisation, treatment, education and research. The acquisition of additional skills has hastened the need for autonomy within the RT profession and with this comes the responsibility to share our knowledge and specialist abilities with the wider community. Radiation therapy is a highly specialised profession working to treat a commonly encountered ailment like cancer and we should ask ourselves what other community members could benefit from our knowledge and skills. Cancer is not limited to the human population but affects animals as readily and severely. Particular types of cancers have been identified as being comparable with that of humans; one such tumour is squamous cell carcinoma (SCC). Squamous cell carcinoma is the most commonly found tumour of the eye and adnexa in horses. Comparatively, SCC in humans is the most common cancer in Australia. Whilst human treatment is well established with surgery and radiation therapy offering comparable control rates, the treatment within Australia's Veterinary Oncology field is currently at a standstill. It is reported, however, that the use of interstitial brachytherapy has been shown to be highly effective and thoroughly practiced and established within the United States of America (USA). This paper reviews current literature in readiness for the potential for radiation therapy cross-over into the veterinary sphere with regard to the implementation of treatment and radiation safety protocols for the use of interstitial brachytherapy in horses.

  14. Is there a role for radiation therapists within veterinary oncology?

    International Nuclear Information System (INIS)

    Surjan, Yolanda; Warren-Forward, Helen; Milross, Christopher

    2011-01-01

    Role expansion recognises enlargement of existing scope of practice within radiation therapy (RT). Over the past decade, there has been increasing involvement and movement towards advanced practice in the form of role extension in specialised areas of practice including brachytherapy, image fusion and quality assurance. It is also recognised that radiation therapy expert practitioners exist in the areas of imaging immobilisation, treatment, education and research. The acquisition of additional skills has hastened the need for autonomy within the RT profession and with this comes the responsibility to share our knowledge and specialist abilities with the wider community. Radiation therapy is a highly specialised profession working to treat a commonly encountered ailment like cancer and we should ask ourselves what other community members could benefit from our knowledge and skills. Cancer is not limited to the human population but affects animals as readily and severely. Particular types of cancers have been identified as being comparable with that of humans; one such tumour is squamous cell carcinoma (SCC). Squamous cell carcinoma is the most commonly found tumour of the eye and adnexa in horses. Comparatively, SCC in humans is the most common cancer in Australia. Whilst human treatment is well established with surgery and radiation therapy offering comparable control rates, the treatment within Australia's Veterinary Oncology field is currently at a standstill. It is reported, however, that the use of interstitial brachytherapy has been shown to be highly effective and thoroughly practiced and established within the United States of America (USA). This paper reviews current literature in readiness for the potential for radiation therapy cross-over into the veterinary sphere with regard to the implementation of treatment and radiation safety protocols for the use of interstitial brachytherapy in horses.

  15. Radiation Therapy Oncology Group clinical trials with misonidazole

    International Nuclear Information System (INIS)

    Wasserman, T.H.; Stetz, J.; Phillips, T.L.

    1981-01-01

    This paper presents a review of the progressive clinical trials of the hypoxic cell radiosensitizer, misonidazole, in the Radiation Therapy Oncology Group (RTOG). Presentation is made of all the schemas of the recently completed and currently active RTOG Phase II and Phase III studies. Detailed information is provided on the clinical toxicity of the Phase II trials, specifically regarding neurotoxicity. With limitations in drug total dose, a variety of dose schedules have proven to be tolerable, with a moderate incidence of nausea and vomiting and mild peripheral neuropathy or central neuropathy. No other organ toxicity has been seen, specifically no liver, renal or bone marrow toxicities. An additional Phase III malignant glioma trial in the Brain Tumor Study Group is described

  16. Comparison of methods for prioritizing risk in radiation oncology

    International Nuclear Information System (INIS)

    Biazotto, Bruna; Tokarski, Marcio

    2016-01-01

    Proactive risk management tools, such as Failure Mode and Effect Analysis (FEMA), were imported from engineering and have been widely used in Radiation Oncology. An important step in this process is the risk prioritization and there are many methods to do that. This paper compares the risk prioritization of computerized planning phase in interstitial implants with high dose rate brachytherapy performed with Health Care Failure Mode and Effect Analysis (HFMEA) and FMEA with guidelines given by the Task Group 100 (TG 100) of the American Association of Physicists in Medicine. Out of the 33 possible failure modes of this process, 21 require more attention when evaluated by HFMEA and 22, when evaluated by FMEA TG 100. Despite the high coincidence between the methods, the execution of HFMEA was simpler. (author)

  17. Through a glass darkly: predicting the future of radiation oncology

    International Nuclear Information System (INIS)

    Peters, Lester J.

    1995-01-01

    To position ourselves professionally for the inevitable transition to managed care demands serious self-appraisal. Like most procedural medical specialties, radiation oncology is currently ill prepared for a capitated system of payment. To prosper under capitation, we need to increase the utility of radiation therapy per unit cost. This can be achieved by making the following adaptive responses: (a) we must ensure that the needs of medical practice drive the use of costly technology and not vice versa; (b) we must subordinate firmly held beliefs and prejudices to solid scientific data and be prepared to modify our practice when more cost-effective alternatives exist; and (c) we must be increasingly conscious of outcome, not process, in deciding among treatment options; and (d) we must acknowledge the need to prioritize the use of finite resources so that the maximum effort is expended on those who have the most to gain from treatment. These changes will permit us to develop guidelines for appropriate use of radiation therapy, and to demonstrate the excellent value of the service we can provide, which is the ultimate key to success. Though the future may at times seem bleak, we can shape it with our actions: the best way to predict the future is to create it

  18. A syllabus for the education and training of radiation oncology nurses

    International Nuclear Information System (INIS)

    2007-01-01

    A dramatic rise in cancer incidence across the developing world is stretching already limited resources and equipment. Shortages of qualified staff and equipment are growing constraints to treating cancer efficiently. More than 5000 radiotherapy machines are presently needed to help patients fight cancer. But the entire developing world has only about 2200 such machines. Experts predict a long term crisis in managing cancer, with an estimated five million new patients requiring radiation therapy every year. Meeting the challenge is not simply a matter of providing appropriate equipment. There must be sufficient trained and knowledgeable staff with clinical and medical physics expertise to deliver a safe and effective radiation dose. Appropriate facilities and radiation protection infrastructure for monitoring and regulatory control are needed. Moreover, cancer treatment must be carried out in a comprehensive context of prevention, early diagnosis and palliative care. In the early stages of development of a radiotherapy department or unit the staffing needs of radiotherapy services should also be specifically and carefully addressed. To make radiotherapy available to all patients who need it, human resources should be urgently expanded globally along with the rational acquisition of additional equipment. The recommended staffing - for a basic radiotherapy facility with 1 teletherapy machine, simulator and high dose-rate brachytherapy - should be: 5 radiation oncologists, 4 medical physicists, 7-8 radiation therapy technologists (RTTs), 3 oncology nurses and 1 maintenance engineer. Where possible, training should be undertaken in centres with patient populations, equipment and training programmes relevant to the needs of the country. Radiotherapy staff should also be required to obtain a qualification adequate for registration in their own country. The human resources listed above could treat on average about 1000 patients per year by extending operations to a

  19. A Profile of Academic Training Program Directors and Chairs in Radiation Oncology

    International Nuclear Information System (INIS)

    Wilson, Lynn D.; Haffty, Bruce G.; Smith, Benjamin D.

    2013-01-01

    Purpose: To identify objective characteristics and benchmarks for program leadership in academic radiation oncology. Methods and Materials: A study of the 87 Accreditation Council for Graduate Medical Education radiation oncology training program directors (PD) and their chairs was performed. Variables included age, gender, original training department, highest degree, rank, endowed chair assignment, National Institutes of Health (NIH) funding, and Hirsch index (H-index). Data were gathered from online sources such as departmental websites, NIH RePORTER, and Scopus. Results: There were a total of 87 PD. The median age was 48, and 14 (16%) were MD/PhD. A total of 21 (24%) were female, and rank was relatively equally distributed above instructor. Of the 26 professors, at least 7 (27%) were female. At least 24 (28%) were working at the institution from which they had received their training. A total of 6 individuals held endowed chairs. Only 2 PD had active NIH funding in 2012. The median H-index was 12 (range, 0-51) but the index dropped to 9 (range, 0-38) when those who served as both PD and chair were removed from the group. A total of 76 chairs were identified at the time of the study. The median age was 55, and 9 (12%) were MD/PhD. A total of 7 (9%) of the chairs were female, and rank was professor for all with the exception of 1 who was listed as “Head” and was an associate professor. Of the 76 chairs, at least 10 (13%) were working at the institution from which they received their training. There were a total of 21 individuals with endowed chairs. A total of 13 (17%) had NIH funding in 2012. The median H-index was 29 (range, 3-60). Conclusions: These data provide benchmarks for individuals and departments evaluating leadership positions in the field of academic radiation oncology. Such data are useful for evaluating leadership trends over time and comparing academic radiation oncology with other specialties

  20. A Profile of Academic Training Program Directors and Chairs in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Wilson, Lynn D., E-mail: Lynn.wilson@yale.edu [Department of Therapeutic Radiology, Yale University School of Medicine, Smilow Cancer Hospital, New Haven, Connecticut (United States); Haffty, Bruce G. [Department of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Smith, Benjamin D. [Department of Radiation Oncology, UMDNJ-RWJMS, Cancer Institute of New Jersey, New Brunswick, New Jersey (United States)

    2013-04-01

    Purpose: To identify objective characteristics and benchmarks for program leadership in academic radiation oncology. Methods and Materials: A study of the 87 Accreditation Council for Graduate Medical Education radiation oncology training program directors (PD) and their chairs was performed. Variables included age, gender, original training department, highest degree, rank, endowed chair assignment, National Institutes of Health (NIH) funding, and Hirsch index (H-index). Data were gathered from online sources such as departmental websites, NIH RePORTER, and Scopus. Results: There were a total of 87 PD. The median age was 48, and 14 (16%) were MD/PhD. A total of 21 (24%) were female, and rank was relatively equally distributed above instructor. Of the 26 professors, at least 7 (27%) were female. At least 24 (28%) were working at the institution from which they had received their training. A total of 6 individuals held endowed chairs. Only 2 PD had active NIH funding in 2012. The median H-index was 12 (range, 0-51) but the index dropped to 9 (range, 0-38) when those who served as both PD and chair were removed from the group. A total of 76 chairs were identified at the time of the study. The median age was 55, and 9 (12%) were MD/PhD. A total of 7 (9%) of the chairs were female, and rank was professor for all with the exception of 1 who was listed as “Head” and was an associate professor. Of the 76 chairs, at least 10 (13%) were working at the institution from which they received their training. There were a total of 21 individuals with endowed chairs. A total of 13 (17%) had NIH funding in 2012. The median H-index was 29 (range, 3-60). Conclusions: These data provide benchmarks for individuals and departments evaluating leadership positions in the field of academic radiation oncology. Such data are useful for evaluating leadership trends over time and comparing academic radiation oncology with other specialties.

  1. Clinical Training of Medical Physicists Specializing in Radiation Oncology

    International Nuclear Information System (INIS)

    2009-01-01

    The application of radiation in human health, for both diagnosis and treatment of disease, is an important component of the work of the IAEA. The responsibility for the increasing technical aspects of this work is undertaken by the medical physicist. To ensure good practice in this vital area structured clinical training programmes are required to complement academic learning. This publication is intended to be a guide to the practical implementation of such a programme for radiation therapy. There is a general and growing awareness that radiation medicine is increasingly dependant on well trained medical physicists that are based in the clinical setting. However an analysis of the availability of medical physicists indicates a large shortfall of qualified and capable professionals. This is particularly evident in developing countries. While strategies to increase academic educational opportunities are critical to such countries, the need for guidance on structured clinical training was recognised by the members of the Regional Cooperative Agreement (RCA) for research, development and training related to nuclear sciences for Asia and the Pacific. Consequently a technical cooperation regional project (RAS6038) under the RCA programme was formulated to address this need in the Asia Pacific region by developing suitable material and establishing its viability. Development of a clinical training guide for medical physicists specialising in radiation therapy was started in 2005 with the appointment of a core drafting committee of regional and international experts. Since 2005 the IAEA has convened two additional consultant group meetings including additional experts to prepare the present publication. The publication drew heavily, particularly in the initial stages, from the experience and documents of the Clinical Training Programme for Radiation Oncology Medical Physicists as developed by the Australasian College of Physical Scientists and Engineers in Medicine. Their

  2. Quantitative assessment of workload and stressors in clinical radiation oncology.

    Science.gov (United States)

    Mazur, Lukasz M; Mosaly, Prithima R; Jackson, Marianne; Chang, Sha X; Burkhardt, Katharin Deschesne; Adams, Robert D; Jones, Ellen L; Hoyle, Lesley; Xu, Jing; Rockwell, John; Marks, Lawrence B

    2012-08-01

    Workload level and sources of stressors have been implicated as sources of error in multiple settings. We assessed workload levels and sources of stressors among radiation oncology professionals. Furthermore, we explored the potential association between workload and the frequency of reported radiotherapy incidents by the World Health Organization (WHO). Data collection was aimed at various tasks performed by 21 study participants from different radiation oncology professional subgroups (simulation therapists, radiation therapists, physicists, dosimetrists, and physicians). Workload was assessed using National Aeronautics and Space Administration Task-Load Index (NASA TLX). Sources of stressors were quantified using observational methods and segregated using a standard taxonomy. Comparisons between professional subgroups and tasks were made using analysis of variance ANOVA, multivariate ANOVA, and Duncan test. An association between workload levels (NASA TLX) and the frequency of radiotherapy incidents (WHO incidents) was explored (Pearson correlation test). A total of 173 workload assessments were obtained. Overall, simulation therapists had relatively low workloads (NASA TLX range, 30-36), and physicists had relatively high workloads (NASA TLX range, 51-63). NASA TLX scores for physicians, radiation therapists, and dosimetrists ranged from 40-52. There was marked intertask/professional subgroup variation (P<.0001). Mental demand (P<.001), physical demand (P=.001), and effort (P=.006) significantly differed among professional subgroups. Typically, there were 3-5 stressors per cycle of analyzed tasks with the following distribution: interruptions (41.4%), time factors (17%), technical factors (13.6%), teamwork issues (11.6%), patient factors (9.0%), and environmental factors (7.4%). A positive association between workload and frequency of reported radiotherapy incidents by the WHO was found (r = 0.87, P value=.045). Workload level and sources of stressors vary

  3. Quantitative Assessment of Workload and Stressors in Clinical Radiation Oncology

    International Nuclear Information System (INIS)

    Mazur, Lukasz M.; Mosaly, Prithima R.; Jackson, Marianne; Chang, Sha X.; Burkhardt, Katharin Deschesne; Adams, Robert D.; Jones, Ellen L.; Hoyle, Lesley; Xu, Jing; Rockwell, John; Marks, Lawrence B.

    2012-01-01

    Purpose: Workload level and sources of stressors have been implicated as sources of error in multiple settings. We assessed workload levels and sources of stressors among radiation oncology professionals. Furthermore, we explored the potential association between workload and the frequency of reported radiotherapy incidents by the World Health Organization (WHO). Methods and Materials: Data collection was aimed at various tasks performed by 21 study participants from different radiation oncology professional subgroups (simulation therapists, radiation therapists, physicists, dosimetrists, and physicians). Workload was assessed using National Aeronautics and Space Administration Task-Load Index (NASA TLX). Sources of stressors were quantified using observational methods and segregated using a standard taxonomy. Comparisons between professional subgroups and tasks were made using analysis of variance ANOVA, multivariate ANOVA, and Duncan test. An association between workload levels (NASA TLX) and the frequency of radiotherapy incidents (WHO incidents) was explored (Pearson correlation test). Results: A total of 173 workload assessments were obtained. Overall, simulation therapists had relatively low workloads (NASA TLX range, 30-36), and physicists had relatively high workloads (NASA TLX range, 51-63). NASA TLX scores for physicians, radiation therapists, and dosimetrists ranged from 40-52. There was marked intertask/professional subgroup variation (P<.0001). Mental demand (P<.001), physical demand (P=.001), and effort (P=.006) significantly differed among professional subgroups. Typically, there were 3-5 stressors per cycle of analyzed tasks with the following distribution: interruptions (41.4%), time factors (17%), technical factors (13.6%), teamwork issues (11.6%), patient factors (9.0%), and environmental factors (7.4%). A positive association between workload and frequency of reported radiotherapy incidents by the WHO was found (r = 0.87, P value=.045

  4. Quantitative Assessment of Workload and Stressors in Clinical Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Mazur, Lukasz M., E-mail: lukasz_mazur@ncsu.edu [Department of Radiation Oncology, University of North Carolina, Chapel Hill, North Carolina (United States); Industrial Extension Service, North Carolina State University, Raleigh, North Carolina (United States); Biomedical Engineering, North Carolina State University, Raleigh, North Carolina (United States); Mosaly, Prithima R. [Industrial Extension Service, North Carolina State University, Raleigh, North Carolina (United States); Jackson, Marianne; Chang, Sha X.; Burkhardt, Katharin Deschesne; Adams, Robert D.; Jones, Ellen L.; Hoyle, Lesley [Department of Radiation Oncology, University of North Carolina, Chapel Hill, North Carolina (United States); Xu, Jing [Industrial Extension Service, North Carolina State University, Raleigh, North Carolina (United States); Rockwell, John; Marks, Lawrence B. [Department of Radiation Oncology, University of North Carolina, Chapel Hill, North Carolina (United States)

    2012-08-01

    Purpose: Workload level and sources of stressors have been implicated as sources of error in multiple settings. We assessed workload levels and sources of stressors among radiation oncology professionals. Furthermore, we explored the potential association between workload and the frequency of reported radiotherapy incidents by the World Health Organization (WHO). Methods and Materials: Data collection was aimed at various tasks performed by 21 study participants from different radiation oncology professional subgroups (simulation therapists, radiation therapists, physicists, dosimetrists, and physicians). Workload was assessed using National Aeronautics and Space Administration Task-Load Index (NASA TLX). Sources of stressors were quantified using observational methods and segregated using a standard taxonomy. Comparisons between professional subgroups and tasks were made using analysis of variance ANOVA, multivariate ANOVA, and Duncan test. An association between workload levels (NASA TLX) and the frequency of radiotherapy incidents (WHO incidents) was explored (Pearson correlation test). Results: A total of 173 workload assessments were obtained. Overall, simulation therapists had relatively low workloads (NASA TLX range, 30-36), and physicists had relatively high workloads (NASA TLX range, 51-63). NASA TLX scores for physicians, radiation therapists, and dosimetrists ranged from 40-52. There was marked intertask/professional subgroup variation (P<.0001). Mental demand (P<.001), physical demand (P=.001), and effort (P=.006) significantly differed among professional subgroups. Typically, there were 3-5 stressors per cycle of analyzed tasks with the following distribution: interruptions (41.4%), time factors (17%), technical factors (13.6%), teamwork issues (11.6%), patient factors (9.0%), and environmental factors (7.4%). A positive association between workload and frequency of reported radiotherapy incidents by the WHO was found (r = 0.87, P value=.045

  5. Scientific impact of studies published in temporarily available radiation oncology journals: a citation analysis.

    Science.gov (United States)

    Nieder, Carsten; Geinitz, Hans; Andratschke, Nicolaus H; Grosu, Anca L

    2015-01-01

    The purpose of this study was to review all articles published in two temporarily available radiation oncology journals (Radiation Oncology Investigations, Journal of Radiosurgery) in order to evaluate their scientific impact. From several potential measures of impact and relevance of research, we selected article citation rate because landmark or practice-changing research is likely to be cited frequently. The citation database Scopus was used to analyse number of citations. During the time period 1996-1999 the journal Radiation Oncology Investigations published 205 articles, which achieved a median number of 6 citations (range 0-116). However, the most frequently cited article in the first 4 volumes achieved only 23 citations. The Journal of Radiosurgery published only 31 articles, all in the year 1999, which achieved a median number of 1 citation (range 0-11). No prospective randomized studies or phase I-II collaborative group trials were published in these journals. Apparently, the Journal of Radiosurgery acquired relatively few manuscripts that were interesting and important enough to impact clinical practice. Radiation Oncology Investigations' citation pattern was better and closer related to that reported in several previous studies focusing on the field of radiation oncology. The vast majority of articles published in temporarily available radiation oncology journals had limited clinical impact and achieved few citations. Highly influential research was unlikely to be submitted during the initial phase of establishing new radiation oncology journals.

  6. Regional cancer centre demonstrates voluntary conformity with the national Radiation Oncology Practice Standards.

    Science.gov (United States)

    Manley, Stephen; Last, Andrew; Fu, Kenneth; Greenham, Stuart; Kovendy, Andrew; Shakespeare, Thomas P

    2015-06-01

    Radiation Oncology Practice Standards have been developed over the last 10 years and were published for use in Australia in 2011. Although the majority of the radiation oncology community supports the implementation of the standards, there has been no mechanism for uniform assessment or governance. North Coast Cancer Institute's public radiation oncology service is provided across three main service centres on the north coast of NSW. With a strong focus on quality management, we embraced the opportunity to demonstrate conformity with the Radiation Oncology Practice Standards. The Local Health District's Clinical Governance units were engaged to perform assessments of our conformity with the standards and this was signed off as complete on 16 December 2013. The process of demonstrating conformity with the Radiation Oncology Practice Standards has enhanced the culture of quality in our centres. We have demonstrated that self-assessment utilising trained auditors is a viable method for centres to demonstrate conformity. National implementation of the Radiation Oncology Practice Standards will benefit individual centres and the broader radiation oncology community to improve the service delivered to our patients.

  7. Regional cancer centre demonstrates voluntary conformity with the national Radiation Oncology Practice Standards

    Energy Technology Data Exchange (ETDEWEB)

    Manley, Stephen, E-mail: stephen.manley@ncahs.health.nsw.gov.au; Last, Andrew; Fu, Kenneth; Greenham, Stuart; Kovendy, Andrew; Shakespeare, Thomas P [North Coast Cancer Institute, Lismore, New South Wales (Australia)

    2015-06-15

    Radiation Oncology Practice Standards have been developed over the last 10 years and were published for use in Australia in 2011. Although the majority of the radiation oncology community supports the implementation of the standards, there has been no mechanism for uniform assessment or governance. North Coast Cancer Institute's public radiation oncology service is provided across three main service centres on the north coast of NSW. With a strong focus on quality management, we embraced the opportunity to demonstrate conformity with the Radiation Oncology Practice Standards. The Local Health District's Clinical Governance units were engaged to perform assessments of our conformity with the standards and this was signed off as complete on 16 December 2013. The process of demonstrating conformity with the Radiation Oncology Practice Standards has enhanced the culture of quality in our centres. We have demonstrated that self-assessment utilising trained auditors is a viable method for centres to demonstrate conformity. National implementation of the Radiation Oncology Practice Standards will benefit individual centres and the broader radiation oncology community to improve the service delivered to our patients.

  8. Regional cancer centre demonstrates voluntary conformity with the national Radiation Oncology Practice Standards

    International Nuclear Information System (INIS)

    Manley, Stephen; Last, Andrew; Fu, Kenneth; Greenham, Stuart; Kovendy, Andrew; Shakespeare, Thomas P

    2015-01-01

    Radiation Oncology Practice Standards have been developed over the last 10 years and were published for use in Australia in 2011. Although the majority of the radiation oncology community supports the implementation of the standards, there has been no mechanism for uniform assessment or governance. North Coast Cancer Institute's public radiation oncology service is provided across three main service centres on the north coast of NSW. With a strong focus on quality management, we embraced the opportunity to demonstrate conformity with the Radiation Oncology Practice Standards. The Local Health District's Clinical Governance units were engaged to perform assessments of our conformity with the standards and this was signed off as complete on 16 December 2013. The process of demonstrating conformity with the Radiation Oncology Practice Standards has enhanced the culture of quality in our centres. We have demonstrated that self-assessment utilising trained auditors is a viable method for centres to demonstrate conformity. National implementation of the Radiation Oncology Practice Standards will benefit individual centres and the broader radiation oncology community to improve the service delivered to our patients

  9. Radiation therapists' and radiation oncology medical physicists' perceptions of work and the working environment in Australia: a qualitative study.

    Science.gov (United States)

    Halkett, G K B; McKay, J; Hegney, D G; Breen, Lauren J; Berg, M; Ebert, M A; Davis, M; Kearvell, R

    2017-09-01

    Workforce recruitment and retention are issues in radiation oncology. The working environment is likely to have an impact on retention; however, there is a lack of research in this area. The objectives of this study were to: investigate radiation therapists' (RTs) and radiation oncology medical physicists' (ROMPs) perceptions of work and the working environment; and determine the factors that influence the ability of RTs and ROMPs to undertake their work and how these factors affect recruitment and retention. Semi-structured interviews were conducted and thematic analysis was used. Twenty-eight RTs and 21 ROMPs participated. The overarching themes were delivering care, support in work, working conditions and lifestyle. The overarching themes were mostly consistent across both groups; however, the exemplars reflected the different roles and perspectives of RTs and ROMPs. Participants described the importance they placed on treating patients and improving their lives. Working conditions were sometimes difficult with participants reporting pressure at work, large workloads and longer hours and overtime. Insufficient staff numbers impacted on the effectiveness of staff, the working environment and intentions to stay. Staff satisfaction is likely to be improved if changes are made to the working environment. We make recommendations that may assist departments to support RTs and ROMPs. © 2016 John Wiley & Sons Ltd.

  10. Application of systems and control theory-based hazard analysis to radiation oncology.

    Science.gov (United States)

    Pawlicki, Todd; Samost, Aubrey; Brown, Derek W; Manger, Ryan P; Kim, Gwe-Ya; Leveson, Nancy G

    2016-03-01

    Both humans and software are notoriously challenging to account for in traditional hazard analysis models. The purpose of this work is to investigate and demonstrate the application of a new, extended accident causality model, called systems theoretic accident model and processes (STAMP), to radiation oncology. Specifically, a hazard analysis technique based on STAMP, system-theoretic process analysis (STPA), is used to perform a hazard analysis. The STPA procedure starts with the definition of high-level accidents for radiation oncology at the medical center and the hazards leading to those accidents. From there, the hierarchical safety control structure of the radiation oncology clinic is modeled, i.e., the controls that are used to prevent accidents and provide effective treatment. Using STPA, unsafe control actions (behaviors) are identified that can lead to the hazards as well as causal scenarios that can lead to the identified unsafe control. This information can be used to eliminate or mitigate potential hazards. The STPA procedure is demonstrated on a new online adaptive cranial radiosurgery procedure that omits the CT simulation step and uses CBCT for localization, planning, and surface imaging system during treatment. The STPA procedure generated a comprehensive set of causal scenarios that are traced back to system hazards and accidents. Ten control loops were created for the new SRS procedure, which covered the areas of hospital and department management, treatment design and delivery, and vendor service. Eighty three unsafe control actions were identified as well as 472 causal scenarios that could lead to those unsafe control actions. STPA provides a method for understanding the role of management decisions and hospital operations on system safety and generating process design requirements to prevent hazards and accidents. The interaction of people, hardware, and software is highlighted. The method of STPA produces results that can be used to improve

  11. Faculty of Radiation Oncology 2012 trainee survey: perspectives on choice of specialty training and future work practice preferences.

    Science.gov (United States)

    Leung, John; Le, Hien; Turner, Sandra; Munro, Philip; Vukolova, Natalia

    2014-02-01

    interest in maintaining an element of academic practice. The large majority of respondents preferred to work in an urban department as a component of their practice after training and nearly all wanted a component of public sector practice. There were only four per cent who preferred to work only within the private sector. Job availability was a concern for 94% of trainees, which far outweighed any other concerns. Trainees in radiation oncology are generally satisfied with their choice of specialty and their training. Most trainees are interested in fellowship positions, links with academia and largely public sector work in the future. Job availability for the future is their major concern. © 2013 The Royal Australian and New Zealand College of Radiologists.

  12. Faculty of Radiation Oncology 2012 trainee survey: perspectives on choice of speciality training and future work practice preference

    International Nuclear Information System (INIS)

    Leung, John; Le, Hien; Turner, Sandra; Munro, Philip; Vukolova, Natalia

    2014-01-01

    interest in maintaining an element of academic practice. The large majority of respondents preferred to work in an urban department as a component of their practice after training and nearly all wanted a component of public sector practice. There were only four per cent who preferred to work only within the private sector. Job availability was a concern for 94% of trainees, which far outweighed any other concerns. Trainees in radiation oncology are generally satisfied with their choice of specialty and their training. Most trainees are interested in fellowship positions, links with academia and largely public sector work in the future. Job availability for the future is their major concern.

  13. Radiation oncology: what can we achieve by optimized dose delivery?

    International Nuclear Information System (INIS)

    Lawrence, T.

    2003-01-01

    Spectacular technical advances have marked the last twenty years in radiation oncology. This revolution began with CT-based planning which was followed by 3D conformal therapy. The latter approach produced two important capabilities. The most obvious was that tumors could be viewed in their true location with respect to normal tissues and treated with beams that were not in the axial plane. A second equally important advance was the development of 3D planning tools such as dose volume histograms. These tools permitted quantitative comparison of treatment plans and have supported the development of models relating normal tissue irradiation to the risk of complication. The '3D hypothesis' - that 3D treatment planning would permit higher doses of radiation to be safely delivered-has been proven. Dose escalation studies have been successfully conducted in the lung (= 100 Gy), liver (= 90 Gy), brain (= 90 Gy), and prostate (= 78 Gy). Prospective phase II and phase III trials suggest improved outcome using these higher doses for tumors in the liver and prostate compared to doses considered acceptable in the 2D era. The next technical revolution is underway, with advances in '4D' radiotherapy (accounting fully for organ motion) and in intensity-modulated radiation therapy (IMRT) to further improve the conformality and accuracy of treatment. Proton therapy will improve dose distributions still further. These improved dose distributions can be combined with more accurate tumor delineation provided by functional imaging to offer the potential for additional dose escalation without toxicity and for improved tumor control. These developments permit us to ask if we are approaching the limits of dose optimization and how (if?) research in radiation delivery should proceed

  14. ASTRO's 2007 Core Physics Curriculum for Radiation Oncology Residents

    International Nuclear Information System (INIS)

    Klein, Eric E.; Gerbi, Bruce J.; Price, Robert A.; Balter, James M.; Paliwal, Bhudatt; Hughes, Lesley; Huang, Eugene

    2007-01-01

    In 2004, American Society for Therapeutic Radiology and Oncology (ASTRO) published a curriculum for physics education. The document described a 54-hour course. In 2006, the committee reconvened to update the curriculum. The committee is composed of physicists and physicians from various residency program teaching institutions. Simultaneously, members have associations with American Association of Physicists in Medicine, ASTRO, Association of Residents in Radiation Oncology, American Board of Radiology, and American College of Radiology. Representatives from the latter two organizations are key to provide feedback between the examining organizations and ASTRO. Subjects are based on Accreditation Council for Graduate Medical Education requirements (particles and hyperthermia), whereas the majority of subjects and appropriated hours/subject were developed by consensus. The new curriculum is 55 hours, containing new subjects, redistribution of subjects with updates, and reorganization of core topics. For each subject, learning objectives are provided, and for each lecture hour, a detailed outline of material to be covered is provided. Some changes include a decrease in basic radiologic physics, addition of informatics as a subject, increase in intensity-modulated radiotherapy, and migration of some brachytherapy hours to radiopharmaceuticals. The new curriculum was approved by the ASTRO board in late 2006. It is hoped that physicists will adopt the curriculum for structuring their didactic teaching program, and simultaneously, American Board of Radiology, for its written examination. American College of Radiology uses the ASTRO curriculum for their training examination topics. In addition to the curriculum, the committee added suggested references, a glossary, and a condensed version of lectures for a Postgraduate Year 2 resident physics orientation. To ensure continued commitment to a current and relevant curriculum, subject matter will be updated again in 2 years

  15. Close to Home: Employment Outcomes for Recent Radiation Oncology Graduates

    Energy Technology Data Exchange (ETDEWEB)

    Ahmed, Awad A. [Department of Radiation Oncology, Sylvester Comprehensive Cancer Center, University of Miami Health System, Miami, Florida (United States); Holliday, Emma B. [Department of Radiation Oncology, The University of Texas M. D. Anderson Cancer Center, Houston, Texas (United States); Ileto, Jan [New York University, New York, New York (United States); Yoo, Stella K. [Department of Radiation Oncology, University of Southern California, Los Angeles, California (United States); Green, Michael [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Orman, Amber [Department of Radiation Oncology, H. Lee Moffitt Cancer Center and Research Institute, Tampa, Florida (United States); Deville, Curtiland [Department of Radiation Oncology and Molecular Radiation Sciences, Johns Hopkins University School of Medicine, Baltimore, Maryland (United States); Jagsi, Reshma [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Haffty, Bruce G. [Department of Radiation Oncology, Rutgers-Robert Wood Johnson Medical School, New Brunswick, New Jersey (United States); Wilson, Lynn D., E-mail: Lynn.wilson@yale.edu [Department of Therapeutic Radiology, Yale School of Medicine and Yale Cancer Center, New Haven, Connecticut (United States)

    2016-07-01

    Purpose: To characterize the practice type and location of radiation oncology (RO) residents graduating in 2013. Methods and Materials: Graduates completing RO residency in 2013 were identified, and for each, postgraduate practice setting (academic vs private practice) and location were identified. Characteristics of the graduates, including details regarding their institutions of medical school and residency education, were collected and analyzed. Results: Data were obtained from 146 of the 154 RO graduates from the class of 2013. Employment data were available for 142 graduates. Approximately one-third of graduates were employed in the same state as residency (36.6%), approximately two-thirds (62.0%) in the same region as residency, and nearly three-fourths (73.9%) in the same region as medical school or residency completion. Of the 66 graduates (46.5%) working in academics, 40.9% were at the same institution where they completed residency. Most trainees (82.4%) attended medical schools with RO residency programs. Conclusions: Although personal factors may attract students to train in a particular area, the location of medical school and residency experiences may influence RO graduate practice location choice. Trends in the geographic distribution of graduating radiation oncologists can help identify and better understand disparities in access to RO care. Steps to improve access to RO care may include interventions at the medical student or resident level, such as targeting students at medical schools without associated residency programs and greater resident exposure to underserved areas.

  16. Molecular Targets for Radiation Oncology in Prostate Cancer

    International Nuclear Information System (INIS)

    Wang, Tao; Languino, Lucia R.; Lian, Jane; Stein, Gary; Blute, Michael; FitzGerald, Thomas J.

    2011-01-01

    Recent selected developments of the molecular science of prostate cancer (PrCa) biology and radiation oncology are reviewed. We present potential targets for molecular integration treatment strategies with radiation therapy (RT), and highlight potential strategies for molecular treatment in combination with RT for patient care. We provide a synopsis of the information to date regarding molecular biology of PrCa, and potential integrated research strategy for improved treatment of PrCa. Many patients with early-stage disease at presentation can be treated effectively with androgen ablation treatment, surgery, or RT. However, a significant portion of men are diagnosed with advanced stage/high-risk disease and these patients progress despite curative therapeutic intervention. Unfortunately, management options for these patients are limited and are not always successful including treatment for hormone refractory disease. In this review, we focus on molecules of extracellular matrix component, apoptosis, androgen receptor, RUNX, and DNA methylation. Expanding our knowledge of the molecular biology of PrCa will permit the development of novel treatment strategies integrated with RT to improve patient outcome

  17. A quality management model for radiation oncology physics

    International Nuclear Information System (INIS)

    Sternick, E.S.

    1991-01-01

    State-of-the-art radiation physics quality programs operate in a data rich environment. Given the abundance of recordable events, any formalism that serves to identify and monitor a set of attributes correlated with quality is to be regarded as an important management tool. The hierarchical tree structure model describes one such useful planning method. Of the several different types of tree structures, one of the most appropriate for quality management is the pyramid model. In this model, the associations between an overall program objective and the intermediate steps leading to its attainment, are indicated by both horizontal and vertical connectors. The overall objective of the system under study occupies the vertex of the pyramid, while the level immediately below contains its principal components. Further subdivisions of each component occur in successively lower levels. The tree finally terminates at a base level consisting of actions or requirements that must be fulfilled in order to satisfy the overall objective. A pyramid model for a radiation oncology physics quality program is discussed in detail. (author). 21 refs., 4 figs., 6 tabs

  18. Close to Home: Employment Outcomes for Recent Radiation Oncology Graduates

    International Nuclear Information System (INIS)

    Ahmed, Awad A.; Holliday, Emma B.; Ileto, Jan; Yoo, Stella K.; Green, Michael; Orman, Amber; Deville, Curtiland; Jagsi, Reshma; Haffty, Bruce G.; Wilson, Lynn D.

    2016-01-01

    Purpose: To characterize the practice type and location of radiation oncology (RO) residents graduating in 2013. Methods and Materials: Graduates completing RO residency in 2013 were identified, and for each, postgraduate practice setting (academic vs private practice) and location were identified. Characteristics of the graduates, including details regarding their institutions of medical school and residency education, were collected and analyzed. Results: Data were obtained from 146 of the 154 RO graduates from the class of 2013. Employment data were available for 142 graduates. Approximately one-third of graduates were employed in the same state as residency (36.6%), approximately two-thirds (62.0%) in the same region as residency, and nearly three-fourths (73.9%) in the same region as medical school or residency completion. Of the 66 graduates (46.5%) working in academics, 40.9% were at the same institution where they completed residency. Most trainees (82.4%) attended medical schools with RO residency programs. Conclusions: Although personal factors may attract students to train in a particular area, the location of medical school and residency experiences may influence RO graduate practice location choice. Trends in the geographic distribution of graduating radiation oncologists can help identify and better understand disparities in access to RO care. Steps to improve access to RO care may include interventions at the medical student or resident level, such as targeting students at medical schools without associated residency programs and greater resident exposure to underserved areas.

  19. Close to Home: Employment Outcomes for Recent Radiation Oncology Graduates.

    Science.gov (United States)

    Ahmed, Awad A; Holliday, Emma B; Ileto, Jan; Yoo, Stella K; Green, Michael; Orman, Amber; Deville, Curtiland; Jagsi, Reshma; Haffty, Bruce G; Wilson, Lynn D

    2016-07-01

    To characterize the practice type and location of radiation oncology (RO) residents graduating in 2013. Graduates completing RO residency in 2013 were identified, and for each, postgraduate practice setting (academic vs private practice) and location were identified. Characteristics of the graduates, including details regarding their institutions of medical school and residency education, were collected and analyzed. Data were obtained from 146 of the 154 RO graduates from the class of 2013. Employment data were available for 142 graduates. Approximately one-third of graduates were employed in the same state as residency (36.6%), approximately two-thirds (62.0%) in the same region as residency, and nearly three-fourths (73.9%) in the same region as medical school or residency completion. Of the 66 graduates (46.5%) working in academics, 40.9% were at the same institution where they completed residency. Most trainees (82.4%) attended medical schools with RO residency programs. Although personal factors may attract students to train in a particular area, the location of medical school and residency experiences may influence RO graduate practice location choice. Trends in the geographic distribution of graduating radiation oncologists can help identify and better understand disparities in access to RO care. Steps to improve access to RO care may include interventions at the medical student or resident level, such as targeting students at medical schools without associated residency programs and greater resident exposure to underserved areas. Copyright © 2016 Elsevier Inc. All rights reserved.

  20. Multiple Authorship in Two English-Language Journals in Radiation Oncology.

    Science.gov (United States)

    Halperin, Edward C.; And Others

    1992-01-01

    A study of multiple authorship in 1,908 papers in the "International Journal of Radiation Oncology, Biology, and Physics" and "Radiotherapy and Oncology" from 1983-87 investigated patterns and trends in number of authors per article by journal, article type, country, author's institution, author gender, and order of listing of…

  1. Meeting the challenge of managed care - Part I: Radiation oncology as an important part of multi-modal care

    International Nuclear Information System (INIS)

    Rose, Christopher M.; Botnick, Leslie E.; Hinkle, Milton; Linden, Jeffrey

    1997-01-01

    Radiation Oncology is an important component in multi-modality cancer care. Managed care has defined a number of different ways that radiation oncologists can interact with the other members of the cancer team. This course will review those options. The change in health care delivery is forcing radiation oncologists to examine every aspect of how they organize themselves, deliver care, evaluate that care, and how they are reimbursed for this process. This course will attempt to examine how the pressures of the new paradigms of health care delivery; managed care and outcomes research are impacting upon radiation therapy practice, and what radiation oncologists can do to maintain patient care standards. I. Introduction: A. Managed Care: What it is and where it is going 1. PPO's 2. HMO's 3. POS plans 4. Carve-outs B. Outcomes Research: What it can and cannot do 1. Patterns of care and SEER 2. Rand 3. ''Surrogate outcomes:'' patient satisfaction, quality of life indicators II. Moving from QA and CQI and Benchmarking A. Radiation Oncologists cannot take anything for granted B. Using analytical tools to evaluate all aspects of the radiation oncology practice. 1. Capital Purchases 2. Operational Aspects III Evaluating Staffing Needs A. What traditional jobs in the department should stay? B. Is the cross-training seen in the rest of the hospital appropriate in radiation oncology C. Outsourcing and multi-department organization as ways to improve efficiency D. What about physician extenders? E. What residents, newly trained radiation oncologists, and physician-practice managers must acknowledge to each other IV. Evaluating Technology A. See second and third talks in this series B. Improving efficiency: how does this help when one is not at capacity C. Increasing throughput D. Decreasing cost V. Informatics A. See second and third talks in this series B. What should one expect the computer to do for you C. Some personal observations VI. Gains from Share Services A. Should

  2. SU-A-210-01: Why Should We Learn Radiation Oncology Billing?

    International Nuclear Information System (INIS)

    Wu, H.

    2015-01-01

    The purpose of this student annual meeting is to address topics that are becoming more relevant to medical physicists, but are not frequently addressed, especially for students and trainees just entering the field. The talk is divided into two parts: medical billing and regulations. Hsinshun Wu – Why should we learn radiation oncology billing? Many medical physicists do not like to be involved with medical billing or coding during their career. They believe billing is not their responsibility and sometimes they even refuse to participate in the billing process if given the chance. This presentation will talk about a physicist’s long career and share his own experience that knowing medical billing is not only important and necessary for every young medical physicist, but that good billing knowledge could provide a valuable contribution to his/her medical physics development. Learning Objectives: The audience will learn the basic definition of Current Procedural Terminology (CPT) codes performed in a Radiation Oncology Department. Understand the differences between hospital coding and physician-based or freestanding coding. Apply proper CPT coding for each Radiation Oncology procedure. Each procedure with its specific CPT code will be discussed in detail. The talk will focus on the process of care and use of actual workflow to understand each CPT code. Example coding of a typical Radiation Oncology procedure. Special procedure coding such as brachytherapy, proton therapy, radiosurgery, and SBRT. Maryann Abogunde – Medical physics opportunities at the Nuclear Regulatory Commission (NRC) The NRC’s responsibilities include the regulation of medical uses of byproduct (radioactive) materials and oversight of medical use end-users (licensees) through a combination of regulatory requirements, licensing, safety oversight including inspection and enforcement, operational experience evaluation, and regulatory support activities. This presentation will explore the

  3. SU-A-210-01: Why Should We Learn Radiation Oncology Billing?

    Energy Technology Data Exchange (ETDEWEB)

    Wu, H. [Willis-Knighton Medical Center (United States)

    2015-06-15

    The purpose of this student annual meeting is to address topics that are becoming more relevant to medical physicists, but are not frequently addressed, especially for students and trainees just entering the field. The talk is divided into two parts: medical billing and regulations. Hsinshun Wu – Why should we learn radiation oncology billing? Many medical physicists do not like to be involved with medical billing or coding during their career. They believe billing is not their responsibility and sometimes they even refuse to participate in the billing process if given the chance. This presentation will talk about a physicist’s long career and share his own experience that knowing medical billing is not only important and necessary for every young medical physicist, but that good billing knowledge could provide a valuable contribution to his/her medical physics development. Learning Objectives: The audience will learn the basic definition of Current Procedural Terminology (CPT) codes performed in a Radiation Oncology Department. Understand the differences between hospital coding and physician-based or freestanding coding. Apply proper CPT coding for each Radiation Oncology procedure. Each procedure with its specific CPT code will be discussed in detail. The talk will focus on the process of care and use of actual workflow to understand each CPT code. Example coding of a typical Radiation Oncology procedure. Special procedure coding such as brachytherapy, proton therapy, radiosurgery, and SBRT. Maryann Abogunde – Medical physics opportunities at the Nuclear Regulatory Commission (NRC) The NRC’s responsibilities include the regulation of medical uses of byproduct (radioactive) materials and oversight of medical use end-users (licensees) through a combination of regulatory requirements, licensing, safety oversight including inspection and enforcement, operational experience evaluation, and regulatory support activities. This presentation will explore the

  4. Prospective evaluation through questionnaires of the emotional status of cancer patients in the waiting rooms of a department of oncology

    OpenAIRE

    Roberta Resega; Sheila Piva; Annalisa Bramati; Christian Lurati; Nicla La Verde; Marco Riva; Marina Chiara Garassino; Anna Moretti; Claudio Mencacci; Valter Torri; Gabriella Farina; Maria Chiara Dazzani

    2016-01-01

    Objective: The aim of this study is to better identify the prevailing emotions and feelings of cancer patients during their stay in waiting rooms in a department of oncology. Methods: In July 2014, patients in the waiting rooms of our Department of Oncology were asked to fill out dedicated questionnaires. Patients had to choose sentences that best described their feelings, thoughts and experiences; this part was differentiated according to the waiting rooms (Consultation Rooms versus Day H...

  5. WE-G-9A-01: Radiation Oncology Outcomes Informatics

    International Nuclear Information System (INIS)

    Mayo, C; Miller, R; Sloan, J; Wu, Q; Howell, R

    2014-01-01

    The construction of databases and support software to enable routine and systematic aggregation, analysis and reporting of patient outcomes data is emerging as an important area. “How have results for our patients been affected by the improvements we have made in our practice and in the technologies we use?” To answer this type of fundamental question about the overall pattern of efficacy observed, it is necessary to systematically gather and analyze data on all patients treated within a clinic. Clinical trials answer, in great depth and detail, questions about outcomes for the subsets of patients enrolled in a given trial. However, routine aggregation and analysis of key treatment parameter data and outcomes information for all patients is necessary to recognize emergent patterns that would be of interest from a public health or practice perspective and could better inform design of clinical trials or the evolution of best practice principals. To address these questions, Radiation Oncology outcomes databases need to be constructed to enable combination essential data from a broad group of data types including: diagnosis and staging, dose volume histogram metrics, patient reported outcomes, toxicity metrics, performance status, treatment plan parameters, demographics, DICOM data and demographics. Developing viable solutions to automate aggregation and analysis of this data requires multidisciplinary efforts to define nomenclatures, modify clinical processes and develop software and database tools requires detailed understanding of both clinical and technical issues. This session will cover the developing area of Radiation Oncology Outcomes Informatics. Learning Objectives: Audience will be able to speak to the technical requirements (software, database, web services) which must be considered in designing an outcomes database. Audience will be able to understand the content and the role of patient reported outcomes as compared to traditional toxicity measures

  6. WE-G-9A-01: Radiation Oncology Outcomes Informatics

    Energy Technology Data Exchange (ETDEWEB)

    Mayo, C; Miller, R; Sloan, J [Mayo Clinic, Rochester, MN (United States); Wu, Q [Duke University Medical Center, Durham, NC (United States); Howell, R [UT MD Anderson Cancer Center, Houston, TX (United States)

    2014-06-15

    The construction of databases and support software to enable routine and systematic aggregation, analysis and reporting of patient outcomes data is emerging as an important area. “How have results for our patients been affected by the improvements we have made in our practice and in the technologies we use?” To answer this type of fundamental question about the overall pattern of efficacy observed, it is necessary to systematically gather and analyze data on all patients treated within a clinic. Clinical trials answer, in great depth and detail, questions about outcomes for the subsets of patients enrolled in a given trial. However, routine aggregation and analysis of key treatment parameter data and outcomes information for all patients is necessary to recognize emergent patterns that would be of interest from a public health or practice perspective and could better inform design of clinical trials or the evolution of best practice principals. To address these questions, Radiation Oncology outcomes databases need to be constructed to enable combination essential data from a broad group of data types including: diagnosis and staging, dose volume histogram metrics, patient reported outcomes, toxicity metrics, performance status, treatment plan parameters, demographics, DICOM data and demographics. Developing viable solutions to automate aggregation and analysis of this data requires multidisciplinary efforts to define nomenclatures, modify clinical processes and develop software and database tools requires detailed understanding of both clinical and technical issues. This session will cover the developing area of Radiation Oncology Outcomes Informatics. Learning Objectives: Audience will be able to speak to the technical requirements (software, database, web services) which must be considered in designing an outcomes database. Audience will be able to understand the content and the role of patient reported outcomes as compared to traditional toxicity measures

  7. Survey of sexual educational needs in radiation oncology patients

    International Nuclear Information System (INIS)

    Chen, L.; Sweeney, P.; Wallace, G.; Neish, P.; Vijayakumar, S.

    1997-01-01

    Purpose: To assess the knowledge of and need for education about sexuality in oncology patients treated with radiation therapy. Methods and Materials: Patients who received radiation therapy for any disease site were given a self-assessment survey to complete to determine their opinions on sexuality and needs for sexual education. The surveys were given to patients on follow-up visit seen approximately 6 months to 2 years after radiation therapy. All patients were diagnosed with a malignancy and asked to participate on a voluntary basis; confidentiality was ensured by excluding any identifying patient information on the survey form. Respondents were polled with a survey that consisted of 17 questions about their sexual activity. Questions were broadly categorized into the following: definition of sexual activity, frequency of sexual activity prior to and after diagnosis and treatment of cancer, perception of sexual attractiveness, sexual satisfaction in the relationship, patient perception of partner's sexual satisfaction in the relationship, educational needs with regard to sexuality after therapy for cancer, and demographic information. Results: All patients were over age 18, and received radiation therapy as part of the treatment. Patients with all disease sites were included in the survey, regardless of stage or diagnosis. A total of 28 patients completed the survey form, which was approved by our institutional review board. Forty-three percent of patients felt that the cancer diagnosis or treatment effect was the cause of not engaging in sexual intercourse. Fifty percent reported not having the same sexual desire as before the diagnosis of cancer, while 46% reported having the same sexual desire as prior to the diagnosis of cancer. Forty-six percent felt less attractive than before the diagnosis of cancer, while 43% felt the same as before diagnosis. Thirty-six percent of patients received no information with regards to sexuality and cancer, while 18% received

  8. Development of radiation oncology learning system combined with multi-institutional radiotherapy database (ROGAD)

    Energy Technology Data Exchange (ETDEWEB)

    Takemura, Akihiro; Iinuma, Masahiro; Kou, Hiroko [Kanazawa Univ. (Japan). School of Medicine; Harauchi, Hajime; Inamura, Kiyonari

    1999-09-01

    We have constructed and are operating a multi-institutional radiotherapy database ROGAD (Radiation Oncology Greater Area Database) since 1992. One of it's purpose is 'to optimize individual radiotherapy plans'. We developed Radiation oncology learning system combined with ROGAD' which conforms to that purpose. Several medical doctors evaluated our system. According to those evaluations, we are now confident that our system is able to contribute to improvement of radiotherapy results. Our final target is to generate a good cyclic relationship among three components: radiotherapy results according to ''Radiation oncology learning system combined with ROGAD.'; The growth of ROGAD; and radiation oncology learning system. (author)

  9. A syllabus for the education and training of radiation oncology nurses

    International Nuclear Information System (INIS)

    2009-01-01

    A dramatic rise in cancer incidence across the developing world is stretching already limited resources and equipment. Shortages of qualified staff and equipment are growing constraints to treating cancer efficiently. More than 5000 radiotherapy machines are presently needed to help patients fight cancer, yet the entire developing world has only about 2200 such machines. Experts predict a long term crisis in managing cancer, with an estimated five million new patients requiring radiotherapy every year. Meeting the challenge is not simply a matter of providing appropriate equipment. There must be sufficient trained and knowledgeable staff with clinical and medical physics expertise to deliver a safe and effective radiation dose. Appropriate facilities and radiation protection infrastructure for monitoring and regulatory control are needed. Cancer treatment must be carried out in a comprehensive context of prevention, early diagnosis and palliative care. In the early stages of development of a radiotherapy department or unit, the staffing needs of radiotherapy services should also be specifically and carefully addressed. To make radiotherapy available to all patients who need it, human resources should be urgently expanded globally, along with the rational acquisition of additional equipment. The recommended staffing - for a basic radiotherapy facility with 1 teletherapy machine, simulator and high dose rate brachytherapy (HDR) - should be: 5 radiation oncologists, 4 medical physicists, 7-8 radiotherapy technologists (RTTs), 3 oncology nurses and 1 maintenance engineer. Where possible, training should be undertaken in centres with patient populations, equipment and training programmes relevant to the needs of the country. Radiotherapy staff should also be required to obtain a qualification adequate for registration in their own country. The human resources listed above could treat on average about 1000 patients per year by extending operations to a minimum of 12

  10. A syllabus for the education and training of radiation oncology nurses

    International Nuclear Information System (INIS)

    2008-01-01

    A dramatic rise in cancer incidence across the developing world is stretching already limited resources and equipment. Shortages of qualified staff and equipment are growing constraints to treating cancer efficiently. More than 5000 radiotherapy machines are presently needed to help patients fight cancer, yet the entire developing world has only about 2200 such machines. Experts predict a long term crisis in managing cancer, with an estimated five million new patients requiring radiotherapy every year. Meeting the challenge is not simply a matter of providing appropriate equipment. There must be sufficient trained and knowledgeable staff with clinical and medical physics expertise to deliver a safe and effective radiation dose. Appropriate facilities and radiation protection infrastructure for monitoring and regulatory control are needed. Cancer treatment must be carried out in a comprehensive context of prevention, early diagnosis and palliative care. In the early stages of development of a radiotherapy department or unit, the staffing needs of radiotherapy services should also be specifically and carefully addressed. To make radiotherapy available to all patients who need it, human resources should be urgently expanded globally, along with the rational acquisition of additional equipment. The recommended staffing - for a basic radiotherapy facility with 1 teletherapy machine, simulator and high dose rate brachytherapy (HDR) - should be: 5 radiation oncologists, 4 medical physicists, 7-8 radiotherapy technologists (RTTs), 3 oncology nurses and 1 maintenance engineer. Where possible, training should be undertaken in centres with patient populations, equipment and training programmes relevant to the needs of the country. Radiotherapy staff should also be required to obtain a qualification adequate for registration in their own country. The human resources listed above could treat on average about 1000 patients per year by extending operations to a minimum of 12

  11. Special report: results of the 2000-2002 association of residents in radiation oncology (arro) surveys

    International Nuclear Information System (INIS)

    Jagsi, Reshma; Chronowski, Gregory M.; Buck, David A.; Kang, Song; Palermo, James

    2004-01-01

    Between 2000 and 2002, the Association of Residents in Radiation Oncology (ARRO) conducted its 18th, 19th, and 20th annual surveys of all residents training in radiation oncology in the United States. This report summarizes these results. The demographic characteristics of residents in training between 2000 and 2002 are detailed, as are issues regarding the quality of training and career choices of residents entering practice

  12. The situation of radiation oncology patients' relatives. A stocktaking

    International Nuclear Information System (INIS)

    Momm, Felix; Lingg, Sabine; Adebahr, Sonja; Grosu, Anca-Ligia; Xander, Carola; Becker, Gerhild

    2010-01-01

    Background and Purpose: Recent studies have shown a very high importance of relatives in decisions about medical interventions. Therefore, the situation of this group was investigated in the sense of a stocktaking by interviewing the closest relatives of radiotherapy patients. Interviewed Persons and Methods: In a defined span of time (6 weeks), a total of 470 relatives (evaluable: n = 287, 61%) of radiotherapy patients were interviewed by a newly developed questionnaire about their contentment with their inclusion in the therapy course. Further, they gave information about specific needs of relatives as well as proposals for direct improvements in the context of a radiation therapy. Results: In total, the relatives were satisfied with their inclusion in the radiotherapy course and with the patient care. As an example, more than 95% of the relatives agreed with the statement ''Here in the hospital my ill relative is cared for well.'' Nevertheless, direct possibilities for improvements were found in the interdisciplinary information about oncologic topics and in the organization of the therapy course. Conclusion: In the stocktaking the situation of radiotherapy patients' relatives was generally satisfactory. Further improvements for the future can be expected mainly from interdisciplinary cancer centers having the best suppositions to care for the relatives, if necessary. Structures known from palliative care can be used as a model. (orig.)

  13. Beyond the Standard Curriculum: A Review of Available Opportunities for Medical Students to Prepare for a Career in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Agarwal, Ankit; DeNunzio, Nicholas J.; Ahuja, Divya; Hirsch, Ariel E., E-mail: Ariel.hirsch@bmc.org

    2014-01-01

    Purpose: To review currently available opportunities for medical students to supplement their standard medical education to prepare for a career in radiation oncology. Methods and Materials: Google and PubMed were used to identify existing clinical, health policy, and research programs for medical students in radiation oncology. In addition, results publicly available by the National Resident Matching Program were used to explore opportunities that successful radiation oncology applicants pursued during their medical education, including obtaining additional graduate degrees. Results: Medical students can pursue a wide variety of opportunities before entering radiation oncology. Several national specialty societies, such as the American Society for Radiation Oncology and the Radiological Society of North America, offer summer internships for medical students interested in radiation oncology. In 2011, 30% of allopathic senior medical students in the United States who matched into radiation oncology had an additional graduate degree, including PhD, MPH, MBA, and MA degrees. Some medical schools are beginning to further integrate dedicated education in radiation oncology into the standard 4-year medical curriculum. Conclusions: To the authors' knowledge, this is the first comprehensive review of available opportunities for medical students interested in radiation oncology. Early exposure to radiation oncology and additional educational training beyond the standard medical curriculum have the potential to create more successful radiation oncology applicants and practicing radiation oncologists while also promoting the growth of the field. We hope this review can serve as guide to radiation oncology applicants and mentors as well as encourage discussion regarding initiatives in radiation oncology opportunities for medical students.

  14. Beyond the standard curriculum: a review of available opportunities for medical students to prepare for a career in radiation oncology.

    Science.gov (United States)

    Agarwal, Ankit; DeNunzio, Nicholas J; Ahuja, Divya; Hirsch, Ariel E

    2014-01-01

    To review currently available opportunities for medical students to supplement their standard medical education to prepare for a career in radiation oncology. Google and PubMed were used to identify existing clinical, health policy, and research programs for medical students in radiation oncology. In addition, results publicly available by the National Resident Matching Program were used to explore opportunities that successful radiation oncology applicants pursued during their medical education, including obtaining additional graduate degrees. Medical students can pursue a wide variety of opportunities before entering radiation oncology. Several national specialty societies, such as the American Society for Radiation Oncology and the Radiological Society of North America, offer summer internships for medical students interested in radiation oncology. In 2011, 30% of allopathic senior medical students in the United States who matched into radiation oncology had an additional graduate degree, including PhD, MPH, MBA, and MA degrees. Some medical schools are beginning to further integrate dedicated education in radiation oncology into the standard 4-year medical curriculum. To the authors' knowledge, this is the first comprehensive review of available opportunities for medical students interested in radiation oncology. Early exposure to radiation oncology and additional educational training beyond the standard medical curriculum have the potential to create more successful radiation oncology applicants and practicing radiation oncologists while also promoting the growth of the field. We hope this review can serve as guide to radiation oncology applicants and mentors as well as encourage discussion regarding initiatives in radiation oncology opportunities for medical students. Copyright © 2014 Elsevier Inc. All rights reserved.

  15. Beyond the Standard Curriculum: A Review of Available Opportunities for Medical Students to Prepare for a Career in Radiation Oncology

    International Nuclear Information System (INIS)

    Agarwal, Ankit; DeNunzio, Nicholas J.; Ahuja, Divya; Hirsch, Ariel E.

    2014-01-01

    Purpose: To review currently available opportunities for medical students to supplement their standard medical education to prepare for a career in radiation oncology. Methods and Materials: Google and PubMed were used to identify existing clinical, health policy, and research programs for medical students in radiation oncology. In addition, results publicly available by the National Resident Matching Program were used to explore opportunities that successful radiation oncology applicants pursued during their medical education, including obtaining additional graduate degrees. Results: Medical students can pursue a wide variety of opportunities before entering radiation oncology. Several national specialty societies, such as the American Society for Radiation Oncology and the Radiological Society of North America, offer summer internships for medical students interested in radiation oncology. In 2011, 30% of allopathic senior medical students in the United States who matched into radiation oncology had an additional graduate degree, including PhD, MPH, MBA, and MA degrees. Some medical schools are beginning to further integrate dedicated education in radiation oncology into the standard 4-year medical curriculum. Conclusions: To the authors' knowledge, this is the first comprehensive review of available opportunities for medical students interested in radiation oncology. Early exposure to radiation oncology and additional educational training beyond the standard medical curriculum have the potential to create more successful radiation oncology applicants and practicing radiation oncologists while also promoting the growth of the field. We hope this review can serve as guide to radiation oncology applicants and mentors as well as encourage discussion regarding initiatives in radiation oncology opportunities for medical students

  16. ASTRO's Advances in Radiation Oncology: Success to date and future plans

    Directory of Open Access Journals (Sweden)

    Robert C. Miller, MD, MBA, FASTRO

    2017-07-01

    Full Text Available ASTRO's Advances in Radiation Oncology was launched as a new, peer-reviewed scientific journal in December 2015. More than 200 manuscripts have been submitted and 97 accepted for publication as of May 2017. As Advances enters its second year of publication, we have chosen to highlight subjects that will transform the way we practice radiation oncology in special issues or ongoing series: immunotherapy, biomedical analytics, and social media. A teaching case report contest for North American radiation oncology residents will be launched at American Society of Radiation Oncology 2017 to encourage participation in scientific publication by trainees early in their careers. Recognizing our social mission, Advances will also begin a series of articles devoted to highlighting the growing disparities in access to radiation oncology services in vulnerable populations in North America. We wish to encourage the American Society of Radiation Oncology membership to continue its support of the journal through high-quality manuscript submission, participation in the peer review process, and highlighting important manuscripts through sharing on social media.

  17. Detailed prospective peer review in a community radiation oncology clinic.

    Science.gov (United States)

    Mitchell, James D; Chesnut, Thomas J; Eastham, David V; Demandante, Carlo N; Hoopes, David J

    In 2012, we instituted detailed prospective peer review of new cases. We present the outcomes of peer review on patient management and time required for peer review. Peer review rounds were held 3 to 4 days weekly and required 2 physicians to review pertinent information from the electronic medical record and treatment planning system. Eight aspects were reviewed for each case: 1) workup and staging; 2) treatment intent and prescription; 3) position, immobilization, and simulation; 4) motion assessment and management; 5) target contours; 6) normal tissue contours; 7) target dosimetry; and 8) normal tissue dosimetry. Cases were marked as, "Meets standard of care," "Variation," or "Major deviation." Changes in treatment plan were noted. As our process evolved, we recorded the time spent reviewing each case. From 2012 to 2014, we collected peer review data on 442 of 465 (95%) radiation therapy patients treated in our hospital-based clinic. Overall, 91 (20.6%) of the cases were marked as having a variation, and 3 (0.7%) as major deviation. Forty-two (9.5%) of the cases were altered after peer review. An overall peer review score of "Variation" or "Major deviation" was highly associated with a change in treatment plan (P peer review. Indicators on position, immobilization, simulation, target contours, target dosimetry, motion management, normal tissue contours, and normal tissue dosimetry were significantly associated with a change in treatment plan. The mean time spent on each case was 7 minutes. Prospective peer review is feasible in a community radiation oncology practice. Our process led to changes in 9.5% of cases. Peer review should focus on technical factors such as target contours and dosimetry. Peer review required 7 minutes per case. Published by Elsevier Inc.

  18. Do Patients Feel Well Informed in a Radiation Oncology Service?

    Science.gov (United States)

    Jimenez-Jimenez, Esther; Mateos, Pedro; Ortiz, Irene; Aymar, Neus; Vidal, Meritxell; Roncero, Raquel; Pardo, Jose; Soto, Carmen; Fuentes, Concepción; Sabater, Sebastià

    2018-04-01

    Information received by cancer patients has gained importance in recent decades. The aim of this study was to evaluate the perception of information received by oncological patients in a radiotherapy department and to measure the importance of the other information sources. A cross-sectional study was conducted, evaluating patients who received radiotherapy. All the patients were asked two questionnaires: the EORTC QLQ-INFO26 module evaluating their satisfaction with received information, and a questionnaire analyzing other sources of information search. One hundred patients between 27 and 84 years were enrolled. Breast cancer (26 %) was the commonest cancer. Patients felt better informed about the medical tests and secondly about the performed treatment. The younger patients were those who were more satisfied with the information received and patients with no formal education felt less satisfied, with statistically significant differences. Patients did not seek external information; at the most, they asked relatives and other people with cancer. Patients were satisfied with the received information, although a high percentage would like more information. In general, patients did not search for external information sources. Age and educational level seem to influence in the satisfaction with the received information.

  19. Evaluation of high-fidelity simulation training in radiation oncology using an outcomes logic model

    International Nuclear Information System (INIS)

    Giuliani, Meredith; Gillan, Caitlin; Wong, Olive; Harnett, Nicole; Milne, Emily; Moseley, Doug; Thompson, Robert; Catton, Pamela; Bissonnette, Jean-Pierre

    2014-01-01

    To evaluate the feasibility and educational value of high-fidelity, interprofessional team-based simulation in radiation oncology. The simulation event was conducted in a radiation oncology department during a non-clinical day. It involved 5 simulation scenarios that were run over three 105 minute timeslots in a single day. High-acuity, low-frequency clinical situations were selected and included HDR brachytherapy emergency, 4D CT artifact management, pediatric emergency clinical mark-up, electron scalp trial set-up and a cone beam CT misregistration incident. A purposive sample of a minimum of 20 trainees was required to assess recruitment feasibility. A faculty radiation oncologist (RO), medical physicist (MP) or radiation therapist (RTT), facilitated each case. Participants completed a pre event survey of demographic data and motivation for participation. A post event survey collected perceptions of familiarity with the clinical content, comfort with interprofessional practice, and event satisfaction, scored on a 1–10 scale in terms of clinical knowledge, clinical decision making, clinical skills, exposure to other trainees and interprofessional communication. Means and standard deviations were calculated. Twenty-one trainees participated including 6 ROs (29%), 6 MPs (29%), and 9 RTTs (43%). All 12 cases (100%) were completed within the allocated 105 minutes. Nine faculty facilitators, (3MP, 2 RO, 4 RTTs) were required for 405 minutes each. Additional costs associated with this event were 154 hours to build the high fidelity scenarios, 2 standardized patients (SPs) for a total of 15.5 hours, and consumables.The mean (±SD) educational value score reported by participants with respect to clinical knowledge was 8.9 (1.1), clinical decision making 8.9 (1.3), clinical skills 8.9 (1.1), exposure to other trainees 9.1 (2.3) and interprofessional communication 9.1 (1.0). Fifteen (71%) participants reported the cases were of an appropriate complexity. The importance

  20. The history and evolution of radiotherapy and radiation oncology in Austria

    International Nuclear Information System (INIS)

    Kogelnik, H. Dieter

    1996-01-01

    Austria has a longstanding and eventful history in the field of radiotherapy and radiation oncology. The founder of radiotherapy, Leopold Freund, began his well-documented first therapeutic irradiation on November 24, 1896, in Vienna. He also wrote the first textbook of radiotherapy in 1903. Further outstanding Viennese pioneers in the fields of radiotherapy, radiobiology, radiation physics, and diagnostic radiology include Gottwald Schwarz, Robert Kienboeck, and Guido Holzknecht. Because many of the leading Austrian radiologists had to emigrate in 1938, irreparable damage occurred at that time for the medical speciality of radiology. After World War II, the recovery in the field of radiotherapy and radiation oncology started in Austria in the early sixties. Eleven radiotherapy centers have been established since that time, and an independent society for radio-oncology, radiobiology, and medical radiophysics was founded in 1984. Finally, in March 1994, radiotherapy-radio-oncology became a separate clinical speciality

  1. The American Society for Radiation Oncology’s 2010 Core Physics Curriculum for Radiation Oncology Residents

    International Nuclear Information System (INIS)

    Xiao Ying; De Amorim Bernstein, Karen; Chetty, Indrin J.; Eifel, Patricia; Hughes, Lesley; Klein, Eric E.; McDermott, Patrick; Prisciandaro, Joann; Paliwal, Bhudatt; Price, Robert A.; Werner-Wasik, Maria; Palta, Jatinder R.

    2011-01-01

    Purpose: In 2004, the American Society for Radiation Oncology (ASTRO) published its first physics education curriculum for residents, which was updated in 2007. A committee composed of physicists and physicians from various residency program teaching institutions was reconvened again to update the curriculum in 2009. Methods and Materials: Members of this committee have associations with ASTRO, the American Association of Physicists in Medicine, the Association of Residents in Radiation Oncology, the American Board of Radiology (ABR), and the American College of Radiology. Members reviewed and updated assigned subjects from the last curriculum. The updated curriculum was carefully reviewed by a representative from the ABR and other physics and clinical experts. Results: The new curriculum resulted in a recommended 56-h course, excluding initial orientation. Learning objectives are provided for each subject area, and a detailed outline of material to be covered is given for each lecture hour. Some recent changes in the curriculum include the addition of Radiation Incidents and Bioterrorism Response Training as a subject and updates that reflect new treatment techniques and modalities in a number of core subjects. The new curriculum was approved by the ASTRO board in April 2010. We anticipate that physicists will use this curriculum for structuring their teaching programs, and subsequently the ABR will adopt this educational program for its written examination. Currently, the American College of Radiology uses the ASTRO curriculum for their training examination topics. In addition to the curriculum, the committee updated suggested references and the glossary. Conclusions: The ASTRO physics education curriculum for radiation oncology residents has been updated. To ensure continued commitment to a current and relevant curriculum, the subject matter will be updated again in 2 years.

  2. Report of China's innovation increase and research growth in radiation oncology.

    Science.gov (United States)

    Zhu, Hongcheng; Yang, Xi; Qin, Qin; Bian, Kangqi; Zhang, Chi; Liu, Jia; Cheng, Hongyan; Sun, Xinchen

    2014-06-01

    To investigate the research status of radiation oncology in China through survey of literature in international radiation oncology journals and retrospectively compare the outputs of radiation oncology articles of the three major regions of China-Mainland (ML), Taiwan (TW) and Hong Kong (HK). Radiation oncology journals were selected from "oncology" and "radiology, nuclear & medical image" category from Science Citation Index Expand (SCIE). Articles from the ML, TW and HK were retrieved from MEDLINE. The number of total articles, clinical trials, case reports, impact factors (IF), institutions and articles published in each journals were conducted for quantity and quality comparisons. A total 818 articles from 13 radiation oncology journals were searched, of which 427 are from ML, 259 from TW, and 132 from HK. Ninety-seven clinical trials and 5 case reports are reported in China. Accumulated IF of articles from ML (1,417.11) was much higher than that of TW (1,003.093) and HK (544.711), while the average IF of articles from ML is the lowest. The total number of articles from China especially ML increased significantly in the last decade. The number of articles published from the ML has exceeded those from TW and HK. However, the quality of articles from TW and HK is better than that from ML.

  3. American Association of Physicists in Medicine Task Group 263: Standardizing Nomenclatures in Radiation Oncology.

    Science.gov (United States)

    Mayo, Charles S; Moran, Jean M; Bosch, Walter; Xiao, Ying; McNutt, Todd; Popple, Richard; Michalski, Jeff; Feng, Mary; Marks, Lawrence B; Fuller, Clifton D; Yorke, Ellen; Palta, Jatinder; Gabriel, Peter E; Molineu, Andrea; Matuszak, Martha M; Covington, Elizabeth; Masi, Kathryn; Richardson, Susan L; Ritter, Timothy; Morgas, Tomasz; Flampouri, Stella; Santanam, Lakshmi; Moore, Joseph A; Purdie, Thomas G; Miller, Robert C; Hurkmans, Coen; Adams, Judy; Jackie Wu, Qing-Rong; Fox, Colleen J; Siochi, Ramon Alfredo; Brown, Norman L; Verbakel, Wilko; Archambault, Yves; Chmura, Steven J; Dekker, Andre L; Eagle, Don G; Fitzgerald, Thomas J; Hong, Theodore; Kapoor, Rishabh; Lansing, Beth; Jolly, Shruti; Napolitano, Mary E; Percy, James; Rose, Mark S; Siddiqui, Salim; Schadt, Christof; Simon, William E; Straube, William L; St James, Sara T; Ulin, Kenneth; Yom, Sue S; Yock, Torunn I

    2018-03-15

    A substantial barrier to the single- and multi-institutional aggregation of data to supporting clinical trials, practice quality improvement efforts, and development of big data analytics resource systems is the lack of standardized nomenclatures for expressing dosimetric data. To address this issue, the American Association of Physicists in Medicine (AAPM) Task Group 263 was charged with providing nomenclature guidelines and values in radiation oncology for use in clinical trials, data-pooling initiatives, population-based studies, and routine clinical care by standardizing: (1) structure names across image processing and treatment planning system platforms; (2) nomenclature for dosimetric data (eg, dose-volume histogram [DVH]-based metrics); (3) templates for clinical trial groups and users of an initial subset of software platforms to facilitate adoption of the standards; (4) formalism for nomenclature schema, which can accommodate the addition of other structures defined in the future. A multisociety, multidisciplinary, multinational group of 57 members representing stake holders ranging from large academic centers to community clinics and vendors was assembled, including physicists, physicians, dosimetrists, and vendors. The stakeholder groups represented in the membership included the AAPM, American Society for Radiation Oncology (ASTRO), NRG Oncology, European Society for Radiation Oncology (ESTRO), Radiation Therapy Oncology Group (RTOG), Children's Oncology Group (COG), Integrating Healthcare Enterprise in Radiation Oncology (IHE-RO), and Digital Imaging and Communications in Medicine working group (DICOM WG); A nomenclature system for target and organ at risk volumes and DVH nomenclature was developed and piloted to demonstrate viability across a range of clinics and within the framework of clinical trials. The final report was approved by AAPM in October 2017. The approval process included review by 8 AAPM committees, with additional review by ASTRO

  4. An Assessment of the Current US Radiation Oncology Workforce: Methodology and Global Results of the American Society for Radiation Oncology 2012 Workforce Study

    Energy Technology Data Exchange (ETDEWEB)

    Vichare, Anushree; Washington, Raynard; Patton, Caroline; Arnone, Anna [ASTRO, Fairfax, Virginia (United States); Olsen, Christine [Massachusetts General Hospital, Boston, Massachusetts, (United States); Fung, Claire Y. [Commonwealth Newburyport Cancer Center, Newburyport, Massachusetts (United States); Hopkins, Shane [William R. Bliss Cancer Center, Ames, Iowa (United States); Pohar, Surjeet, E-mail: spohar@netzero.net [Indiana University Health Cancer Center East, Indiana University, Indianapolis, Indiana (United States)

    2013-12-01

    Purpose: To determine the characteristics, needs, and concerns of the current radiation oncology workforce, evaluate best practices and opportunities for improving quality and safety, and assess what we can predict about the future workforce. Methods and Materials: An online survey was distributed to 35,204 respondents from all segments of the radiation oncology workforce, including radiation oncologists, residents, medical dosimetrists, radiation therapists, medical physicists, nurse practitioners, nurses, physician assistants, and practice managers/administrators. The survey was disseminated by the American Society for Radiation Oncology (ASTRO) together with specialty societies representing other workforce segments. An overview of the methods and global results is presented in this paper. Results: A total of 6765 completed surveys were received, a response rate of 19%, and the final analysis included 5257 respondents. Three-quarters of the radiation oncologists, residents, and physicists who responded were male, in contrast to the other segments in which two-thirds or more were female. The majority of respondents (58%) indicated they were hospital-based, whereas 40% practiced in a free-standing/satellite clinic and 2% in another setting. Among the practices represented in the survey, 21.5% were academic, 25.2% were hospital, and 53.3% were private. A perceived oversupply of professionals relative to demand was reported by the physicist, dosimetrist, and radiation therapist segments. An undersupply was perceived by physician's assistants, nurse practitioners, and nurses. The supply of radiation oncologists and residents was considered balanced. Conclusions: This survey was unique as it attempted to comprehensively assess the radiation oncology workforce by directly surveying each segment. The results suggest there is potential to improve the diversity of the workforce and optimize the supply of the workforce segments. The survey also provides a benchmark for

  5. An Assessment of the Current US Radiation Oncology Workforce: Methodology and Global Results of the American Society for Radiation Oncology 2012 Workforce Study

    International Nuclear Information System (INIS)

    Vichare, Anushree; Washington, Raynard; Patton, Caroline; Arnone, Anna; Olsen, Christine; Fung, Claire Y.; Hopkins, Shane; Pohar, Surjeet

    2013-01-01

    Purpose: To determine the characteristics, needs, and concerns of the current radiation oncology workforce, evaluate best practices and opportunities for improving quality and safety, and assess what we can predict about the future workforce. Methods and Materials: An online survey was distributed to 35,204 respondents from all segments of the radiation oncology workforce, including radiation oncologists, residents, medical dosimetrists, radiation therapists, medical physicists, nurse practitioners, nurses, physician assistants, and practice managers/administrators. The survey was disseminated by the American Society for Radiation Oncology (ASTRO) together with specialty societies representing other workforce segments. An overview of the methods and global results is presented in this paper. Results: A total of 6765 completed surveys were received, a response rate of 19%, and the final analysis included 5257 respondents. Three-quarters of the radiation oncologists, residents, and physicists who responded were male, in contrast to the other segments in which two-thirds or more were female. The majority of respondents (58%) indicated they were hospital-based, whereas 40% practiced in a free-standing/satellite clinic and 2% in another setting. Among the practices represented in the survey, 21.5% were academic, 25.2% were hospital, and 53.3% were private. A perceived oversupply of professionals relative to demand was reported by the physicist, dosimetrist, and radiation therapist segments. An undersupply was perceived by physician's assistants, nurse practitioners, and nurses. The supply of radiation oncologists and residents was considered balanced. Conclusions: This survey was unique as it attempted to comprehensively assess the radiation oncology workforce by directly surveying each segment. The results suggest there is potential to improve the diversity of the workforce and optimize the supply of the workforce segments. The survey also provides a benchmark for

  6. SU-E-T-222: How to Define and Manage Quality Metrics in Radiation Oncology.

    Science.gov (United States)

    Harrison, A; Cooper, K; DeGregorio, N; Doyle, L; Yu, Y

    2012-06-01

    Since the 2001 IOM Report Crossing the Quality Chasm: A New Health System for the 21st Century, the need to provide quality metrics in health care has increased. Quality metrics have yet to be defined for the field of radiation oncology. This study represents one institutes initial efforts defining and measuring quality metrics using our electronic medical record and verify system(EMR) as a primary data collection tool. This effort began by selecting meaningful quality metrics rooted in the IOM definition of quality (safe, timely, efficient, effective, equitable and patient-centered care) that were also measurable targets based on current data input and workflow. Elekta MOSAIQ 2.30.04D1 was used to generate reports on the number of Special Physics Consults(SPC) charged as a surrogate for treatment complexity, daily patient time in department(DTP) as a measure of efficiency and timeliness, and time from CT-simulation to first LINAC appointment(STL). The number of IMRT QAs delivered in the department was also analyzed to assess complexity. Although initial MOSAIQ reports were easily generated, the data needed to be assessed and adjusted for outliers. Patients with delays outside of radiation oncology such as chemotherapy or surgery were excluded from STL data. We found an average STL of six days for all CT-simulated patients and an average DTP of 52 minutes total time, with 23 minutes in the LINAC vault. Annually, 7.3% of all patient require additional physics support indicated by SPC. Utilizing our EMR, an entire year's worth of useful data characterizing our clinical experience was analyzed in less than one day. Having baseline quality metrics is necessary to improve patient care. Future plans include dissecting this data into more specific categories such as IMRT DTP, workflow timing following CT-simulation, beam-on hours, chart review outcomes, and dosimetric quality indicators. © 2012 American Association of Physicists in Medicine.

  7. American Society of Radiation Oncology Recommendations for Documenting Intensity-Modulated Radiation Therapy Treatments

    International Nuclear Information System (INIS)

    Holmes, Timothy; Das, Rupak; Low, Daniel; Yin Fangfang; Balter, James; Palta, Jatinder; Eifel, Patricia

    2009-01-01

    Despite the widespread use of intensity-modulated radiation therapy (IMRT) for approximately a decade, a lack of adequate guidelines for documenting these treatments persists. Proper IMRT treatment documentation is necessary for accurate reconstruction of prior treatments when a patient presents with a marginal recurrence. This is especially crucial when the follow-up care is managed at a second treatment facility not involved in the initial IMRT treatment. To address this issue, an American Society for Radiation Oncology (ASTRO) workgroup within the American ASTRO Radiation Physics Committee was formed at the request of the ASTRO Research Council to develop a set of recommendations for documenting IMRT treatments. This document provides a set of comprehensive recommendations for documenting IMRT treatments, as well as image-guidance procedures, with example forms provided.

  8. First Author Research Productivity of United States Radiation Oncology Residents: 2002-2007

    International Nuclear Information System (INIS)

    Morgan, Peter B.; Sopka, Dennis M.; Kathpal, Madeera; Haynes, Jeffrey C.; Lally, Brian E.; Li, Linna

    2009-01-01

    Purpose: Participation in investigative research is a required element of radiation oncology residency in the United States. Our purpose was to quantify the first author research productivity of recent U.S. radiation oncology residents during their residency training. Methods and Materials: We performed a computer-based search of PubMed and a manual review of the proceedings of the annual meetings of the American Society for Therapeutic Radiology and Oncology to identify all publications and presented abstracts with a radiation oncology resident as the first author between 2002 and 2007. Results: Of 1,098 residents trained at 81 programs, 50% published ≥1 article (range, 0-9), and 53% presented ≥1 abstract (range, 0-3) at an American Society for Therapeutic Radiology and Oncology annual meeting. The national average was 1.01 articles published and 1.09 abstracts presented per resident during 4 years of training. Of 678 articles published, 82% represented original research and 18% were review articles. Residents contributed 15% of all abstracts at American Society for Therapeutic Radiology and Oncology annual meetings, and the resident contribution to orally presented abstracts increased from 12% to 21% during the study period. Individuals training at programs with >6 residents produced roughly twice as many articles and abstracts. Holman Research Pathway residents produced double the national average of articles and abstracts. Conclusion: Although variability exists among individuals and among training programs, U.S. radiation oncology residents routinely participate in investigative research suitable for publication or presentation at a scientific meeting. These data provide national research benchmarks that can assist current and future radiation oncology residents and training programs in their self-assessment and research planning.

  9. Gender Trends in Radiation Oncology in the United States: A 30-Year Analysis

    Energy Technology Data Exchange (ETDEWEB)

    Ahmed, Awad A. [Temple University School of Medicine, Philadelphia, Pennsylvania (United States); Egleston, Brian [Department of Biostatistics, Fox Chase Cancer Center, Philadelphia, Pennsylvania (United States); Holliday, Emma [Department of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Eastwick, Gary [Temple University School of Medicine, Philadelphia, Pennsylvania (United States); Takita, Cristiane [Department of Radiation Oncology, University of Miami Miller School of Medicine, Miami, Florida (United States); Jagsi, Reshma, E-mail: rjagsi@med.umich.edu [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States)

    2014-01-01

    Purpose: Although considerable research exists regarding the role of women in the medical profession in the United States, little work has described the participation of women in academic radiation oncology. We examined women's participation in authorship of radiation oncology literature, a visible and influential activity that merits specific attention. Methods and Materials: We examined the gender of first and senior US physician-authors of articles published in the Red Journal in 1980, 1990, 2000, 2004, 2010, and 2012. The significance of trends over time was evaluated using logistic regression. Results were compared with female representation in journals of general medicine and other major medical specialties. Findings were also placed in the context of trends in the representation of women among radiation oncology faculty and residents over the past 3 decades, using Association of American Medical Colleges data. Results: The proportion of women among Red Journal first authors increased from 13.4% in 1980 to 29.7% in 2012, and the proportion among senior authors increased from 3.2% to 22.6%. The proportion of women among radiation oncology full-time faculty increased from 11% to 26.7% from 1980 to 2012. The proportion of women among radiation oncology residents increased from 27.1% to 33.3% from 1980 to 2010. Conclusions: Female first and senior authorship in the Red Journal has increased significantly, as has women's participation among full-time faculty, but women remain underrepresented among radiation oncology residents compared with their representation in the medical student body. Understanding such trends is necessary to develop appropriately targeted interventions to improve gender equity in radiation oncology.

  10. GENDER TRENDS IN RADIATION ONCOLOGY IN THE UNITED STATES: A 30 YEAR ANALYSIS

    Science.gov (United States)

    Ahmed, Awad A; Egleston, Brian; Holliday, Emma; Eastwick, Gary; Takita, Cristiane; Jagsi, Reshma

    2013-01-01

    Purpose/Objective Although considerable research exists regarding the role of women in the medical profession in the United States, little work has described the participation of women in academic radiation oncology. We examined women’s participation in authorship of radiation oncology literature, a visible and influential activity that merits specific attention. Methods and Materials We examined the gender of first and senior U.S. physician-authors of articles published in the Red Journal in 1980, 1990, 2000, 2004, 2010 and 2012. The significance of trends over time was evaluated using logistic regression. Results were compared to female representation in journals of general medicine and other major medical specialties. Findings were also placed in the context of trends in the representation of women among radiation oncology faculty and residents over the last three decades, using AAMC data. Results The proportion of women among Red Journal first authors increased from 13.4% in 1980 to 29.7% in 2012, and the proportion among senior authors increased from 3.2% to 22.6%. The proportion of women among radiation oncology full-time faculty increased from 11% to 26.7% from 1980 to 2012. The proportion of women among radiation oncology residents increased from 27.1% to 33.3% from 1980 to 2010. Conclusion Female first and senior authorship in the Red Journal has increased significantly, as has women’s participation among full-time faculty, but women remain under-represented among radiation oncology residents as compared to their representation in the medical student body. Understanding such trends is necessary to develop appropriately targeted interventions to improve gender equity in radiation oncology. PMID:24189127

  11. Gender Trends in Radiation Oncology in the United States: A 30-Year Analysis

    Energy Technology Data Exchange (ETDEWEB)

    Ahmed, Awad A. [Temple University School of Medicine, Philadelphia, Pennsylvania (United States); Egleston, Brian [Department of Biostatistics, Fox Chase Cancer Center, Philadelphia, Pennsylvania (United States); Holliday, Emma [Department of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Eastwick, Gary [Temple University School of Medicine, Philadelphia, Pennsylvania (United States); Takita, Cristiane [Department of Radiation Oncology, University of Miami Miller School of Medicine, Miami, Florida (United States); Jagsi, Reshma [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States)

    2014-01-01

    Purpose: Although considerable research exists regarding the role of women in the medical profession in the United States, little work has described the participation of women in academic radiation oncology. We examined women's participation in authorship of radiation oncology literature, a visible and influential activity that merits specific attention. Methods and Materials: We examined the gender of first and senior US physician-authors of articles published in the Red Journal in 1980, 1990, 2000, 2004, 2010, and 2012. The significance of trends over time was evaluated using logistic regression. Results were compared with female representation in journals of general medicine and other major medical specialties. Findings were also placed in the context of trends in the representation of women among radiation oncology faculty and residents over the past 3 decades, using Association of American Medical Colleges data. Results: The proportion of women among Red Journal first authors increased from 13.4% in 1980 to 29.7% in 2012, and the proportion among senior authors increased from 3.2% to 22.6%. The proportion of women among radiation oncology full-time faculty increased from 11% to 26.7% from 1980 to 2012. The proportion of women among radiation oncology residents increased from 27.1% to 33.3% from 1980 to 2010. Conclusions: Female first and senior authorship in the Red Journal has increased significantly, as has women's participation among full-time faculty, but women remain underrepresented among radiation oncology residents compared with their representation in the medical student body. Understanding such trends is necessary to develop appropriately targeted interventions to improve gender equity in radiation oncology.

  12. Gender trends in radiation oncology in the United States: a 30-year analysis.

    Science.gov (United States)

    Ahmed, Awad A; Egleston, Brian; Holliday, Emma; Eastwick, Gary; Takita, Cristiane; Jagsi, Reshma

    2014-01-01

    Although considerable research exists regarding the role of women in the medical profession in the United States, little work has described the participation of women in academic radiation oncology. We examined women's participation in authorship of radiation oncology literature, a visible and influential activity that merits specific attention. We examined the gender of first and senior US physician-authors of articles published in the Red Journal in 1980, 1990, 2000, 2004, 2010, and 2012. The significance of trends over time was evaluated using logistic regression. Results were compared with female representation in journals of general medicine and other major medical specialties. Findings were also placed in the context of trends in the representation of women among radiation oncology faculty and residents over the past 3 decades, using Association of American Medical Colleges data. The proportion of women among Red Journal first authors increased from 13.4% in 1980 to 29.7% in 2012, and the proportion among senior authors increased from 3.2% to 22.6%. The proportion of women among radiation oncology full-time faculty increased from 11% to 26.7% from 1980 to 2012. The proportion of women among radiation oncology residents increased from 27.1% to 33.3% from 1980 to 2010. Female first and senior authorship in the Red Journal has increased significantly, as has women's participation among full-time faculty, but women remain underrepresented among radiation oncology residents compared with their representation in the medical student body. Understanding such trends is necessary to develop appropriately targeted interventions to improve gender equity in radiation oncology. Copyright © 2014 Elsevier Inc. All rights reserved.

  13. Gender Trends in Radiation Oncology in the United States: A 30-Year Analysis

    International Nuclear Information System (INIS)

    Ahmed, Awad A.; Egleston, Brian; Holliday, Emma; Eastwick, Gary; Takita, Cristiane; Jagsi, Reshma

    2014-01-01

    Purpose: Although considerable research exists regarding the role of women in the medical profession in the United States, little work has described the participation of women in academic radiation oncology. We examined women's participation in authorship of radiation oncology literature, a visible and influential activity that merits specific attention. Methods and Materials: We examined the gender of first and senior US physician-authors of articles published in the Red Journal in 1980, 1990, 2000, 2004, 2010, and 2012. The significance of trends over time was evaluated using logistic regression. Results were compared with female representation in journals of general medicine and other major medical specialties. Findings were also placed in the context of trends in the representation of women among radiation oncology faculty and residents over the past 3 decades, using Association of American Medical Colleges data. Results: The proportion of women among Red Journal first authors increased from 13.4% in 1980 to 29.7% in 2012, and the proportion among senior authors increased from 3.2% to 22.6%. The proportion of women among radiation oncology full-time faculty increased from 11% to 26.7% from 1980 to 2012. The proportion of women among radiation oncology residents increased from 27.1% to 33.3% from 1980 to 2010. Conclusions: Female first and senior authorship in the Red Journal has increased significantly, as has women's participation among full-time faculty, but women remain underrepresented among radiation oncology residents compared with their representation in the medical student body. Understanding such trends is necessary to develop appropriately targeted interventions to improve gender equity in radiation oncology

  14. Radiation Oncology and Online Patient Education Materials: Deviating From NIH and AMA Recommendations.

    Science.gov (United States)

    Prabhu, Arpan V; Hansberry, David R; Agarwal, Nitin; Clump, David A; Heron, Dwight E

    2016-11-01

    Physicians encourage patients to be informed about their health care options, but much of the online health care-related resources can be beneficial only if patients are capable of comprehending it. This study's aim was to assess the readability level of online patient education resources for radiation oncology to conclude whether they meet the general public's health literacy needs as determined by the guidelines of the United States National Institutes of Health (NIH) and the American Medical Association (AMA). Radiation oncology-related internet-based patient education materials were downloaded from 5 major professional websites (American Society for Radiation Oncology, American Association of Physicists in Medicine, American Brachytherapy Society, RadiologyInfo.org, and Radiation Therapy Oncology Group). Additional patient education documents were downloaded by searching for key radiation oncology phrases using Google. A total of 135 articles were downloaded and assessed for their readability level using 10 quantitative readability scales that are widely accepted in the medical literature. When all 10 assessment tools for readability were taken into account, the 135 online patient education articles were written at an average grade level of 13.7 ± 2.0. One hundred nine of the 135 articles (80.7%) required a high school graduate's comprehension level (12th-grade level or higher). Only 1 of the 135 articles (0.74%) met the AMA and NIH recommendations for patient education resources to be written between the third-grade and seventh-grade levels. Radiation oncology websites have patient education material written at an educational level above the NIH and AMA recommendations; as a result, average American patients may not be able to fully understand them. Rewriting radiation oncology patient education resources would likely contribute to the patients' understanding of their health and treatment options, making each physician-patient interaction more productive

  15. American College of Radiology In-Training Examination for Residents in Radiation Oncology (2004-2007)

    International Nuclear Information System (INIS)

    Paulino, Arnold C.; Kurtz, Elizabeth

    2008-01-01

    Purpose: To review the results of the recent American College of Radiology (ACR) in-training examinations in radiation oncology and to provide information regarding the examination changes in recent years. Methods and Materials: A retrospective review of the 2004 to 2007 ACR in-training examination was undertaken. Results: The number of residents taking the in-training examination increased from 2004 to 2007, compatible with the increase in the number of radiation oncology residents in the United States and Canada. The number of questions decreased from approximately 510 in 2004 and 2005, to 405 in 2006 and 360 in 2007, most of these changes were in the clinical oncology section. Although the in-training examination showed construct validity with resident performance improving with each year of additional clinical oncology training, it did so only until Level 3 for biology and physics. Several changes have been made to the examination process, including allowing residents to keep the examination booklet for self-study, posting of the answer key and rationales to questions on the ACR Website, and providing hard copies to residency training directors. In addition, all questions are now A type or multiple choice questions with one best answer, similar to the American Board of Radiology written examination for radiation oncology. Conclusion: Several efforts by the ACR have been made in recent years to make the examination an educational tool for radiation oncology residents and residency directors

  16. Education and Training Needs in Radiation Oncology in India: Opportunities for Indo–US Collaborations

    Energy Technology Data Exchange (ETDEWEB)

    Grover, Surbhi, E-mail: Surbhi.grover@uphs.upenn.edu [Department of Radiation Oncology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania (United States); Chadha, Manjeet [Mount Sinai Beth Israel Health System, Icahn School of Medicine, New York, New York (United States); Rengan, Ramesh [Department of Radiation Oncology, University of Washington, Seattle, Washington (United States); Williams, Tim R. [Department of Radiation Oncology, Lynn Cancer Institute, Boca Raton Regional Hospital, Boca Raton, Florida (United States); Morris, Zachary S. [Department of Human Oncology, University of Wisconsin School of Medicine and Public Health, Seattle, Washington (United States); Morgan, David A.L. [Breast Services, Sherwood Forest Hospitals NHS Trust, Nottinghamshire (United Kingdom); Tripuraneni, Prabhakar [Department of Radiation Oncology, Scripps Green Hospital, La Jolla, California (United States); Hu, Kenneth [Department of Radiation Oncology, NYU Lagone Medical Center, New York, New York (United States); Viswanathan, Akila N. [Department of Radiation Oncology, Brigham and Women' s Hospital/Dana-Farber Cancer Institute, Boston, Massachusetts (United States)

    2015-12-01

    Purpose: To conduct a survey of radiation oncologists in India, to better understand specific educational needs of radiation oncology in India and define areas of collaboration with US institutions. Methods and Materials: A 20-question survey was distributed to members of the Association of Indian Radiation Oncologists and the Indian Brachytherapy Society between November 2013 and May 2014. Results: We received a total of 132 responses. Over 50% of the physicians treat more than 200 patients per day, use 2-dimensional or 3-dimensional treatment planning techniques, and approximately 50% use image guided techniques. For education needs, most respondents agreed that further education in intensity modulated radiation therapy, image guided radiation therapy, stereotactic radiation therapy, biostatistics, and research methods for medical residents would be useful areas of collaboration with institutions in the United States. Other areas of collaboration include developing a structured training module for nursing, physics training, and developing a second-opinion clinic for difficult cases with faculty in the United States. Conclusion: Various areas of potential collaboration in radiation oncology education were identified through this survey. These include the following: establishing education programs focused on current technology, facilitating exchange programs for trainees in India to the United States, promoting training in research methods, establishing training modules for physicists and oncology nurses, and creating an Indo–US. Tumor Board. It would require collaboration between the Association of Indian Radiation Oncologists and the American Society for Radiation Oncology to develop these educational initiatives.

  17. Education and Training Needs in Radiation Oncology in India: Opportunities for Indo–US Collaborations

    International Nuclear Information System (INIS)

    Grover, Surbhi; Chadha, Manjeet; Rengan, Ramesh; Williams, Tim R.; Morris, Zachary S.; Morgan, David A.L.; Tripuraneni, Prabhakar; Hu, Kenneth; Viswanathan, Akila N.

    2015-01-01

    Purpose: To conduct a survey of radiation oncologists in India, to better understand specific educational needs of radiation oncology in India and define areas of collaboration with US institutions. Methods and Materials: A 20-question survey was distributed to members of the Association of Indian Radiation Oncologists and the Indian Brachytherapy Society between November 2013 and May 2014. Results: We received a total of 132 responses. Over 50% of the physicians treat more than 200 patients per day, use 2-dimensional or 3-dimensional treatment planning techniques, and approximately 50% use image guided techniques. For education needs, most respondents agreed that further education in intensity modulated radiation therapy, image guided radiation therapy, stereotactic radiation therapy, biostatistics, and research methods for medical residents would be useful areas of collaboration with institutions in the United States. Other areas of collaboration include developing a structured training module for nursing, physics training, and developing a second-opinion clinic for difficult cases with faculty in the United States. Conclusion: Various areas of potential collaboration in radiation oncology education were identified through this survey. These include the following: establishing education programs focused on current technology, facilitating exchange programs for trainees in India to the United States, promoting training in research methods, establishing training modules for physicists and oncology nurses, and creating an Indo–US. Tumor Board. It would require collaboration between the Association of Indian Radiation Oncologists and the American Society for Radiation Oncology to develop these educational initiatives.

  18. Education and Training Needs in Radiation Oncology in India: Opportunities for Indo-US Collaborations.

    Science.gov (United States)

    Grover, Surbhi; Chadha, Manjeet; Rengan, Ramesh; Williams, Tim R; Morris, Zachary S; Morgan, David A L; Tripuraneni, Prabhakar; Hu, Kenneth; Viswanathan, Akila N

    2015-12-01

    To conduct a survey of radiation oncologists in India, to better understand specific educational needs of radiation oncology in India and define areas of collaboration with US institutions. A 20-question survey was distributed to members of the Association of Indian Radiation Oncologists and the Indian Brachytherapy Society between November 2013 and May 2014. We received a total of 132 responses. Over 50% of the physicians treat more than 200 patients per day, use 2-dimensional or 3-dimensional treatment planning techniques, and approximately 50% use image guided techniques. For education needs, most respondents agreed that further education in intensity modulated radiation therapy, image guided radiation therapy, stereotactic radiation therapy, biostatistics, and research methods for medical residents would be useful areas of collaboration with institutions in the United States. Other areas of collaboration include developing a structured training module for nursing, physics training, and developing a second-opinion clinic for difficult cases with faculty in the United States. Various areas of potential collaboration in radiation oncology education were identified through this survey. These include the following: establishing education programs focused on current technology, facilitating exchange programs for trainees in India to the United States, promoting training in research methods, establishing training modules for physicists and oncology nurses, and creating an Indo-US. Tumor Board. It would require collaboration between the Association of Indian Radiation Oncologists and the American Society for Radiation Oncology to develop these educational initiatives. Copyright © 2015 Elsevier Inc. All rights reserved.

  19. Radiation oncology training in France: demography, analysis of motivations of the young specialists, evaluation of the training

    International Nuclear Information System (INIS)

    Kantor, G.; Kantor, G.; Gerard, G.P.; Kantor, G.; Bey, P.; Huguet, F.; Toledano, A.; Lafond, C.; Quero, L.; Servagi, S.

    2005-01-01

    During the 5 past national courses organised by the French society of radiation oncology (SFRO), three different types of survey were performed to analyse demography, motivations and quality of training of the young specialists. During the 5 past years, 50 radiation oncologists were training for the whole country (about 15 per year were graduated). A recent increase the number of young specialists is observed with a total number of 50 in 2000 to 75 in 2005. Nevertheless, the number of young specialists is dramatically insufficient and exposes for the future to an important demographic crisis. Analysis of motivations of choice for radiation oncology confirms the influence of a practical stage of oncology during the second cycle of the medical studies for 60% of the young specialists. Analysis of practical and theoretical training was performed according to the point of view and living experiences of the students. On the other hand, informations from teachers were less complete. Some needs are emphasised as: 1) the quality of the follow during the training (importance of the recent implementation of a logbook); 2) importance of theoretical and practical training at the radiotherapy department: 3) help and incentive for research and scientific publication. (author)

  20. Improving patient safety in the radiation oncology setting through crew resource management.

    Science.gov (United States)

    Sundararaman, Srinath; Babbo, Angela E; Brown, John A; Doss, Richard

    2014-01-01

    This paper demonstrates how the communication patterns and protocol rigors of a methodology called crew resource management (CRM) can be adapted to a radiation oncology environment to create a culture of patient safety. CRM training was introduced to our comprehensive radiation oncology department in the autumn of 2009. With 34 full-time equivalent staff, we see 100-125 patients daily on 2 hospital campuses. We were assisted by a consulting group with considerable experience in helping hospitals incorporate CRM principles and practices. Implementation steps included developing change initiative skills for key leaders, providing training in teamwork and communications, creating site-specific tools for safety and efficiency, and collecting data to document results. Our goals were to improve patient safety, teamwork, communication, and efficiency through the use of tools we developed that emphasized teamwork and communication, cross-checking, and routinizing specific protocols. Our CRM plan relies on the following 4 pillars: patient identification methods; "pause for the cause"; enabling all staff to halt treatment and question decisions; and daily morning meetings. We discuss some of the hurdles to change we encountered. Our safety record has improved. Our near-miss rate before CRM implementation averaged 11 per month; our near-miss rate currently averages 1.2 per month. In the 5 years prior to CRM implementation, we experienced 1 treatment deviation per year, although none rose to the level of "mis-administration." Since implementing CRM, our current patient treatment setup and delivery process has eliminated all treatment deviations. Our practices have identified situations where ambiguity or conflicting documentation could have resulted in inappropriate treatment or treatment inefficiencies. Our staff members have developed an extraordinary sense of teamwork combined with a high degree of personal responsibility to assure patient safety and have spoken up when

  1. HMI Radiation Chemistry Department. Scientific report 1985

    International Nuclear Information System (INIS)

    1985-01-01

    Results of the R and D activities of the Radiation Chemistry Department, Hahn-Meitner-Institut, are reported, primarily dealing with the following subjects: a) Interface processes and energy conversion; b) Pulsed radiolysis and kinematics; c) Insulating materials and polymers. Activities belonging to group (a) above include the development of photosensitive materials for energy conversion, photovoltaic solar cells, light-induced hydrogen liberation, and inclusion reactions, model experiments studying photoactive interfaces, rapid kinematic measurements at interfaces after laser-induced excitation, surface preparation of amorphous silicon and its effects on electronic properties, photochemical reactions and catalysts. Work performed in group (b) above included studies into various chemical reactions involving radicals, and on interactions between atoms, ions, molecules and molecular clusters induced by low-energy collisions. Group (c) above all performed studies into the physical and chemical elementary processes induced by high-energy radiation, light and UV light, especially in electronegative gases. Further activities in this group included photochemical and radiation chemical investigations on polymers. The report lists publications and lectures prepared by H.M.I. members and guest scientists in the year 1985. (RB) [de

  2. Defining a Leader Role curriculum for radiation oncology: A global Delphi consensus study

    NARCIS (Netherlands)

    Turner, Sandra; Seel, Matthew; Trotter, Theresa; Giuliani, Meredith; Benstead, Kim; Eriksen, Jesper G.; Poortmans, Philip; Verfaillie, Christine; Westerveld, Henrike; Cross, Shamira; Chan, Ming-Ka; Shaw, Timothy

    2017-01-01

    The need for radiation oncologists and other radiation oncology (RO) professionals to lead quality improvement activities and contribute to shaping the future of our specialty is self-evident. Leadership knowledge, skills and behaviours, like other competencies, can be learned (Blumenthal et al.,

  3. Postgraduate Education in Radiation Oncology in Low- and Middle-income Countries

    DEFF Research Database (Denmark)

    Eriksen, J. G.

    2017-01-01

    Radiation therapy is one of the most cost-effective ways to treat cancer patients on both a curative and palliative basis in low- and middle-income countries (LMICs). Despite this, the gap in radiation oncology capacity is enormous and is even increasing due to a rapid rise in the incidence...

  4. TH-D-204-00: The Pursuit of Radiation Oncology Performance Excellence

    International Nuclear Information System (INIS)

    2016-01-01

    The Malcolm Baldrige National Quality Improvement Act was signed into law in 1987 to advance U.S. business competitiveness and economic growth. Administered by the National Institute of Standards and Technology NIST, the Act created the Baldrige National Quality Program, now renamed the Baldrige Performance Excellence Program. The comprehensive analytical approaches referred to as the Baldrige Healthcare Criteria, are very well suited for the evaluation and sustainable improvement of radiation oncology management and operations. A multidisciplinary self-assessment approach is used for radiotherapy program evaluation and development in order to generate a fact based knowledge driven system for improving quality of care, increasing patient satisfaction, building employee engagement, and boosting organizational innovation. The methodology also provides a valuable framework for benchmarking an individual radiation oncology practice against guidelines defined by accreditation and professional organizations and regulatory agencies. Learning Objectives: To gain knowledge of the Baldrige Performance Excellence Program as it relates to Radiation Oncology. To appreciate the value of a multidisciplinary self-assessment approach in the pursuit of Radiation Oncology quality care, patient satisfaction, and workforce commitment. To acquire a set of useful measurement tools with which an individual Radiation Oncology practice can benchmark its performance against guidelines defined by accreditation and professional organizations and regulatory agencies.

  5. TH-D-204-01: The Pursuit of Radiation Oncology Performance Excellence

    International Nuclear Information System (INIS)

    Sternick, E.

    2016-01-01

    The Malcolm Baldrige National Quality Improvement Act was signed into law in 1987 to advance U.S. business competitiveness and economic growth. Administered by the National Institute of Standards and Technology NIST, the Act created the Baldrige National Quality Program, now renamed the Baldrige Performance Excellence Program. The comprehensive analytical approaches referred to as the Baldrige Healthcare Criteria, are very well suited for the evaluation and sustainable improvement of radiation oncology management and operations. A multidisciplinary self-assessment approach is used for radiotherapy program evaluation and development in order to generate a fact based knowledge driven system for improving quality of care, increasing patient satisfaction, building employee engagement, and boosting organizational innovation. The methodology also provides a valuable framework for benchmarking an individual radiation oncology practice against guidelines defined by accreditation and professional organizations and regulatory agencies. Learning Objectives: To gain knowledge of the Baldrige Performance Excellence Program as it relates to Radiation Oncology. To appreciate the value of a multidisciplinary self-assessment approach in the pursuit of Radiation Oncology quality care, patient satisfaction, and workforce commitment. To acquire a set of useful measurement tools with which an individual Radiation Oncology practice can benchmark its performance against guidelines defined by accreditation and professional organizations and regulatory agencies.

  6. TH-D-204-01: The Pursuit of Radiation Oncology Performance Excellence

    Energy Technology Data Exchange (ETDEWEB)

    Sternick, E. [The Warren Alpert Medical School of Brown Univ., Providence, RI (United States)

    2016-06-15

    The Malcolm Baldrige National Quality Improvement Act was signed into law in 1987 to advance U.S. business competitiveness and economic growth. Administered by the National Institute of Standards and Technology NIST, the Act created the Baldrige National Quality Program, now renamed the Baldrige Performance Excellence Program. The comprehensive analytical approaches referred to as the Baldrige Healthcare Criteria, are very well suited for the evaluation and sustainable improvement of radiation oncology management and operations. A multidisciplinary self-assessment approach is used for radiotherapy program evaluation and development in order to generate a fact based knowledge driven system for improving quality of care, increasing patient satisfaction, building employee engagement, and boosting organizational innovation. The methodology also provides a valuable framework for benchmarking an individual radiation oncology practice against guidelines defined by accreditation and professional organizations and regulatory agencies. Learning Objectives: To gain knowledge of the Baldrige Performance Excellence Program as it relates to Radiation Oncology. To appreciate the value of a multidisciplinary self-assessment approach in the pursuit of Radiation Oncology quality care, patient satisfaction, and workforce commitment. To acquire a set of useful measurement tools with which an individual Radiation Oncology practice can benchmark its performance against guidelines defined by accreditation and professional organizations and regulatory agencies.

  7. TH-D-204-00: The Pursuit of Radiation Oncology Performance Excellence

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2016-06-15

    The Malcolm Baldrige National Quality Improvement Act was signed into law in 1987 to advance U.S. business competitiveness and economic growth. Administered by the National Institute of Standards and Technology NIST, the Act created the Baldrige National Quality Program, now renamed the Baldrige Performance Excellence Program. The comprehensive analytical approaches referred to as the Baldrige Healthcare Criteria, are very well suited for the evaluation and sustainable improvement of radiation oncology management and operations. A multidisciplinary self-assessment approach is used for radiotherapy program evaluation and development in order to generate a fact based knowledge driven system for improving quality of care, increasing patient satisfaction, building employee engagement, and boosting organizational innovation. The methodology also provides a valuable framework for benchmarking an individual radiation oncology practice against guidelines defined by accreditation and professional organizations and regulatory agencies. Learning Objectives: To gain knowledge of the Baldrige Performance Excellence Program as it relates to Radiation Oncology. To appreciate the value of a multidisciplinary self-assessment approach in the pursuit of Radiation Oncology quality care, patient satisfaction, and workforce commitment. To acquire a set of useful measurement tools with which an individual Radiation Oncology practice can benchmark its performance against guidelines defined by accreditation and professional organizations and regulatory agencies.

  8. Japanese structure survey of radiation oncology in 2007 with special reference to designated cancer care hospitals

    International Nuclear Information System (INIS)

    Numasaki, Hodaka; Shibuya, Hitoshi; Nishio, Masamichi

    2011-01-01

    Background and Purpose: The structure of radiation oncology in designated cancer care hospitals in Japan was investigated in terms of equipment, personnel, patient load, and geographic distribution. The effect of changes in the health care policy in Japan on radiotherapy structure was also examined. Material and Methods: The Japanese Society of Therapeutic Radiology and Oncology surveyed the national structure of radiation oncology in 2007. The structures of 349 designated cancer care hospitals and 372 other radiotherapy facilities were compared. Results: Respective findings for equipment and personnel at designated cancer care hospitals and other facilities included the following: linear accelerators/facility: 1.3 and 1.0; annual patients/linear accelerator: 296.5 and 175.0; and annual patient load/full-time equivalent radiation oncologist was 237.0 and 273.3, respectively. Geographically, the number of designated cancer care hospitals was associated with population size. Conclusion: The structure of radiation oncology in Japan in terms of equipment, especially for designated cancer care hospitals, was as mature as that in European countries and the United States, even though the medical costs in relation to GDP in Japan are lower. There is still a shortage of manpower. The survey data proved to be important to fully understand the radiation oncology medical care system in Japan. (orig.)

  9. Input of Psychosocial Information During Multidisciplinary Team Meetings at Medical Oncology Departments: Protocol for an Observational Study.

    Science.gov (United States)

    Horlait, Melissa; Van Belle, Simon; Leys, Mark

    2018-02-26

    Multidisciplinary team meetings (MDTMs) have become standard practice in oncology and gained the status of the key decision-making forum for cancer patient management. The current literature provides evidence that MDTMs are achieving their intended objectives but there are also indications to question the positive impact of MDTMs in oncology settings. For cancer management to be patient-centered, it is crucial that medical information as well as psychosocial aspects-such as the patients' living situation, possible family problems, patients' mental state, and patients' perceptions and values or preferences towards treatment or care-are considered and discussed during MDTMs. Previous studies demonstrate that failure to account for patients' psychosocial information has a negative impact on the implementation of the treatment recommendations formulated during MDTMs. Few empirical studies have demonstrated the predominant role of physicians during MDTMs, leading to the phenomenon that medical information is shared almost exclusively at the expense of psychosocial information. However, more in-depth insight on the underlying reasons why MDTMs fail to take into account psychosocial information of cancer patients is needed. This paper presents a research protocol for a cross-sectional observational study that will focus on exploring the barriers to considering psychosocial information during MDTMs at medical oncology departments. This protocol encompasses a cross-sectional comparative case study of MDTMs at medical oncology departments in Flanders, Belgium. MDTMs from various oncology subspecialties at inpatient medical oncology departments in multiple hospitals (academic as well as general hospitals) are compared. The observations focus on the "multidisciplinary oncology consultation" (MOC), a formally regulated and financed type of MDTM in Belgian oncology since 2003. Data are collected through nonparticipant observations of MOC-meetings. Observational data are

  10. Current Status and Recommendations for the Future of Research, Teaching, and Testing in the Biological Sciences of Radiation Oncology: Report of the American Society for Radiation Oncology Cancer Biology/Radiation Biology Task Force, Executive Summary

    Energy Technology Data Exchange (ETDEWEB)

    Wallner, Paul E., E-mail: pwallner@theabr.org [21st Century Oncology, LLC, and the American Board of Radiology, Bethesda, Maryland (United States); Anscher, Mitchell S. [Department of Radiation Oncology, Virginia Commonwealth University, Richmond, Virginia (United States); Barker, Christopher A. [Department of Radiation Oncology, Memorial Sloan-Kettering Cancer Center, New York, New York (United States); Bassetti, Michael [Department of Human Oncology, University of Wisconsin Carbone Cancer Center, Madison, Wisconsin (United States); Bristow, Robert G. [Departments of Radiation Oncology and Medical Biophysics, Princess Margaret Cancer Center/University of Toronto, Toronto, Ontario (Canada); Cha, Yong I. [Department of Radiation Oncology, Norton Cancer Center, Louisville, Kentucky (United States); Dicker, Adam P. [Department of Radiation Oncology, Thomas Jefferson University, Philadelphia, Pennsylvania (United States); Formenti, Silvia C. [Department of Radiation Oncology, New York University, New York, New York (United States); Graves, Edward E. [Departments of Radiation Oncology and Radiology, Stanford University, Stanford, California (United States); Hahn, Stephen M. [Department of Radiation Oncology, University of Pennsylvania (United States); Hei, Tom K. [Center for Radiation Research, Columbia University, New York, New York (United States); Kimmelman, Alec C. [Department of Radiation Oncology, Dana-Farber Cancer Institute, Boston, Massachusetts (United States); Kirsch, David G. [Department of Radiation Oncology, Duke University, Durham, North Carolina (United States); Kozak, Kevin R. [Department of Human Oncology, University of Wisconsin (United States); Lawrence, Theodore S. [Department of Radiation Oncology, University of Michigan (United States); Marples, Brian [Department of Radiation Oncology, Oakland University, Oakland, California (United States); and others

    2014-01-01

    In early 2011, a dialogue was initiated within the Board of Directors (BOD) of the American Society for Radiation Oncology (ASTRO) regarding the future of the basic sciences of the specialty, primarily focused on the current state and potential future direction of basic research within radiation oncology. After consideration of the complexity of the issues involved and the precise nature of the undertaking, in August 2011, the BOD empanelled a Cancer Biology/Radiation Biology Task Force (TF). The TF was charged with developing an accurate snapshot of the current state of basic (preclinical) research in radiation oncology from the perspective of relevance to the modern clinical practice of radiation oncology as well as the education of our trainees and attending physicians in the biological sciences. The TF was further charged with making suggestions as to critical areas of biological basic research investigation that might be most likely to maintain and build further the scientific foundation and vitality of radiation oncology as an independent and vibrant medical specialty. It was not within the scope of service of the TF to consider the quality of ongoing research efforts within the broader radiation oncology space, to presume to consider their future potential, or to discourage in any way the investigators committed to areas of interest other than those targeted. The TF charge specifically precluded consideration of research issues related to technology, physics, or clinical investigations. This document represents an Executive Summary of the Task Force report.

  11. Undergraduate cancer education in Spain: The debate, the opportunities and the initiatives of the University Forum of the Spanish Society of Radiation Oncology (SEOR).

    Science.gov (United States)

    Lara, Pedro; Calvo, Felipe A; Guedea, Ferran; Bilbao, Pedro; Biete, Alberto

    2013-11-09

    Most medical schools in Spain (80%) offer undergraduate training in oncology. This education is highly variable in terms of content (theory and practical training), number of credits, and the medical specialty and departmental affiliation of the professors. Much of this variability is due to university traditions in the configuration of credits and programmes, and also to the structure of the hospital-based practical training. Undergraduate medical students deserve a more coherent and modern approach to education with a strong emphasis on clinical practice. Oncology is an interdisciplinary science that requires the input of professors from multiple specialties to provide the primary body of knowledge and skills needed to obtain both a theoretical and clinical understanding of cancer. Clinical skills should be a key focus due to their importance in the current model of integrated medical management and care. Clinical radiation oncology is a traditional and comprehensive hospital-based platform for undergraduate education in oncology. In Spain, a significant number (n = 80) of radiation oncology specialists have a contractual relationship to teach university courses. Most Spanish universities (80%) have a radiation oncologist on staff, some of whom are department chairs and many others are full professors who have been hired and promoted under competitive conditions of evaluation as established by the National Agency for Quality Evaluation. The Spanish Society of Radiation Oncology (SEOR) has identified new opportunities to improve undergraduate education in oncology. In this article, we discuss proposals related to theoretical (20 items) and practical clinical training (9 items). We also describe the SEOR University Forum, which is an initiative to develop a strategic plan to implement and organize cancer education at the undergraduate level in an interdisciplinary teaching spirit and with a strong contribution from radiation oncologists.

  12. Patient-centered image and data management in radiation oncology

    International Nuclear Information System (INIS)

    Steil, Volker; Schneider, Frank; Kuepper, Beate; Wenz, Frederik; Lohr, Frank; Weisser, Gerald

    2009-01-01

    Background: recent changes in the radiotherapy (RT) workflow through the introduction of complex treatment paradigms such as intensity-modulated radiotherapy (IMRT) and, recently, image-guided radiotherapy (IGRT) with their increase in data traffic for different data classes have mandated efforts to further integrate electronic data management for RT departments in a patient- and treatment-course-centered fashion. Methods: workflow in an RT department is multidimensional and multidirectional and consists of at least five different data classes (RT/machine data, patient-related documents such as reports and letters, progress notes, DICOM (Digital Imaging and Communications in Medicine) image data, and non-DICOM image data). Data has to be handled in the framework of adaptive feedback loops with increasing frequency. This is in contrast to a radiology department where mainly DICOM image data and reports have to be widely accessible but are dealt with in a mainly unidirectional manner. When compared to a diagnostic Radiology Information System (RIS)/Picture Archiving and Communication System (PACS), additional legal requirements have to be conformed to when an integrated electronic RT data management system is installed. Among these are extended storage periods, documentation of treatment plan approval by physicians and physicist, documentation of informed consent, etc. Conclusion: since the transition to a paper- and filmless environment in medicine and especially m radiation ''neology is unavoidable this review discusses these issues and suggests a possible hardware and organizational architecture of an RT department information system under control of a Hospital Information System (HIS), based on combined features of genuine RT Record and Verify (R and V) Systems, PACS, and Electronic Medical Records (EMR). (orig.)

  13. Complementary and alternative medicine in radiation oncology. Survey of patients' attitudes

    International Nuclear Information System (INIS)

    Lettner, Sabrina; Kessel, Kerstin A.; Combs, Stephanie E.

    2017-01-01

    Complementary and alternative medicine (CAM) are gaining in importance, but objective data are mostly missing. However, in previous trials, methods such as acupuncture showed significant advantages compared to standard therapies. Thus, the aim was to evaluate most frequently used methods, their significance and the general acceptance amongst cancer patients undergoing radiotherapy (RT). A questionnaire of 18 questions based on the categorical classification released by the National Centre for Complementary and Integrative Health was developed. From April to September 2015, all patients undergoing RT at the Department of Radiation Oncology, Technical University of Munich, completed the survey. Changes in attitude towards CAM were evaluated using the questionnaire after RT during the first follow-up visit (n = 31). Of 634 patients, 333 answered the questionnaire (52.5%). Of all participants, 26.4% used CAM parallel to RT. Before RT, a total of 39.3% had already used complementary medicine. The most frequently applied methods during therapy were vitamins/minerals, food supplements, physiotherapy/manual medicine, and homeopathy. The majority (71.5%) did not use any complementary treatment, mostly stating that CAM was not offered to them (73.5%). The most common reasons for use were to improve the immune system (48%), to reduce side effects (43.8%), and to not miss an opportunity (37.8%). Treatment integrated into the individual therapy concept, e.g. regular acupuncture, would be used by 63.7% of RT patients. In comparison to other studies, usage of CAM parallel to RT in our department is considered to be low. Acceptance amongst patients is present, as treatment integrated into the individual oncology therapy would be used by about two-third of patients. (orig.) [de

  14. Complementary and alternative medicine in radiation oncology : Survey of patients' attitudes.

    Science.gov (United States)

    Lettner, Sabrina; Kessel, Kerstin A; Combs, Stephanie E

    2017-05-01

    Complementary and alternative medicine (CAM) are gaining in importance, but objective data are mostly missing. However, in previous trials, methods such as acupuncture showed significant advantages compared to standard therapies. Thus, the aim was to evaluate most frequently used methods, their significance and the general acceptance amongst cancer patients undergoing radiotherapy (RT). A questionnaire of 18 questions based on the categorical classification released by the National Centre for Complementary and Integrative Health was developed. From April to September 2015, all patients undergoing RT at the Department of Radiation Oncology, Technical University of Munich, completed the survey. Changes in attitude towards CAM were evaluated using the questionnaire after RT during the first follow-up visit (n = 31). Of 634 patients, 333 answered the questionnaire (52.5%). Of all participants, 26.4% used CAM parallel to RT. Before RT, a total of 39.3% had already used complementary medicine. The most frequently applied methods during therapy were vitamins/minerals, food supplements, physiotherapy/manual medicine, and homeopathy. The majority (71.5%) did not use any complementary treatment, mostly stating that CAM was not offered to them (73.5%). The most common reasons for use were to improve the immune system (48%), to reduce side effects (43.8%), and to not miss an opportunity (37.8%). Treatment integrated into the individual therapy concept, e.g. regular acupuncture, would be used by 63.7% of RT patients. In comparison to other studies, usage of CAM parallel to RT in our department is considered to be low. Acceptance amongst patients is present, as treatment integrated into the individual oncology therapy would be used by about two-third of patients.

  15. Radiation Oncology and Online Patient Education Materials: Deviating From NIH and AMA Recommendations

    International Nuclear Information System (INIS)

    Prabhu, Arpan V.; Hansberry, David R.; Agarwal, Nitin; Clump, David A.; Heron, Dwight E.

    2016-01-01

    Purpose: Physicians encourage patients to be informed about their health care options, but much of the online health care–related resources can be beneficial only if patients are capable of comprehending it. This study's aim was to assess the readability level of online patient education resources for radiation oncology to conclude whether they meet the general public's health literacy needs as determined by the guidelines of the United States National Institutes of Health (NIH) and the American Medical Association (AMA). Methods: Radiation oncology–related internet-based patient education materials were downloaded from 5 major professional websites (American Society for Radiation Oncology, American Association of Physicists in Medicine, American Brachytherapy Society, (RadiologyInfo.org), and Radiation Therapy Oncology Group). Additional patient education documents were downloaded by searching for key radiation oncology phrases using Google. A total of 135 articles were downloaded and assessed for their readability level using 10 quantitative readability scales that are widely accepted in the medical literature. Results: When all 10 assessment tools for readability were taken into account, the 135 online patient education articles were written at an average grade level of 13.7 ± 2.0. One hundred nine of the 135 articles (80.7%) required a high school graduate's comprehension level (12th-grade level or higher). Only 1 of the 135 articles (0.74%) met the AMA and NIH recommendations for patient education resources to be written between the third-grade and seventh-grade levels. Conclusion: Radiation oncology websites have patient education material written at an educational level above the NIH and AMA recommendations; as a result, average American patients may not be able to fully understand them. Rewriting radiation oncology patient education resources would likely contribute to the patients' understanding of their health and treatment options, making each

  16. Radiation Oncology and Online Patient Education Materials: Deviating From NIH and AMA Recommendations

    Energy Technology Data Exchange (ETDEWEB)

    Prabhu, Arpan V. [Department of Radiation Oncology, University of Pittsburgh Cancer Institute, Pittsburgh, Pennsylvania (United States); Hansberry, David R. [Department of Radiology, Thomas Jefferson University Hospitals, Philadelphia, Pennsylvania (United States); Agarwal, Nitin [Department of Neurological Surgery, University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania (United States); Clump, David A. [Department of Radiation Oncology, University of Pittsburgh Cancer Institute, Pittsburgh, Pennsylvania (United States); Heron, Dwight E., E-mail: herond2@upmc.edu [Department of Radiation Oncology, University of Pittsburgh Cancer Institute, Pittsburgh, Pennsylvania (United States); Department of Otolaryngology, Head and Neck Surgery, University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania (United States)

    2016-11-01

    Purpose: Physicians encourage patients to be informed about their health care options, but much of the online health care–related resources can be beneficial only if patients are capable of comprehending it. This study's aim was to assess the readability level of online patient education resources for radiation oncology to conclude whether they meet the general public's health literacy needs as determined by the guidelines of the United States National Institutes of Health (NIH) and the American Medical Association (AMA). Methods: Radiation oncology–related internet-based patient education materials were downloaded from 5 major professional websites (American Society for Radiation Oncology, American Association of Physicists in Medicine, American Brachytherapy Society, (RadiologyInfo.org), and Radiation Therapy Oncology Group). Additional patient education documents were downloaded by searching for key radiation oncology phrases using Google. A total of 135 articles were downloaded and assessed for their readability level using 10 quantitative readability scales that are widely accepted in the medical literature. Results: When all 10 assessment tools for readability were taken into account, the 135 online patient education articles were written at an average grade level of 13.7 ± 2.0. One hundred nine of the 135 articles (80.7%) required a high school graduate's comprehension level (12th-grade level or higher). Only 1 of the 135 articles (0.74%) met the AMA and NIH recommendations for patient education resources to be written between the third-grade and seventh-grade levels. Conclusion: Radiation oncology websites have patient education material written at an educational level above the NIH and AMA recommendations; as a result, average American patients may not be able to fully understand them. Rewriting radiation oncology patient education resources would likely contribute to the patients' understanding of their health and treatment

  17. The psychosocial work environment among physicians employed at Danish oncology departments in 2009. A nationwide cross-sectional study.

    Science.gov (United States)

    Andreassen, Christian Nicolaj; Eriksen, Jesper Grau

    2013-01-01

    Working as a physician at an oncology department has some distinctive characteristics that may lead to a stressful work environment. The present study was conducted to provide a nationwide description of the work conditions of all oncologists in Denmark. By comparing the results of the present study with those of a similar study carried out in 2006, the aim was furthermore to elucidate changes in the psychosocial work environment over time. From May to September 2009, 330 physicians employed at six oncology centres and seven community based oncology departments were invited to participate in a survey based on the short version of the COPSOQ II questionnaire. The results were compared with data from a representative section of Danish employees and with data from the 2006 survey. Two hundred and twenty of the 330 invited physicians returned the questionnaire (response rate 67%). Concerning the aspects quantitative demands, work pace, emotional demands, influence, burnout and stress, the oncologists reported worse work conditions than the average Danish employee. However, with regard to possibilities for development, meaning of work and commitment to workplace, the oncologists reported better work conditions. Between 2006 and 2009, substantial improvement was seen concerning several of the assessed work environment aspects within the group of young physicians at the oncology centres. Though substantial improvement of the work conditions has been achieved between 2006 and 2009, certain aspects of the psychosocial work environment at Danish oncology departments still require attention.

  18. Energy Department radiation rhetoric, actions at odds

    International Nuclear Information System (INIS)

    Lobsenz, G.

    1994-01-01

    Only months after Energy Secretary Hazel O'Leary pledged that DOE would open-quotes come cleanclose quotes about past radiation abuses, the department is refusing to release individual exposure records of former workers at its heavily contaminated Fernald uranium plant. At the same time O'Leary was flying around the country to tout a new era of openness at the department, top DOE officials in January told attorneys representing the Fernald workers that individual exposure records would not be forthcoming. While agreeing to provide general health data, DOE specifically refused to disclose the names of the workers involved or their specific exposure histories at the plant, citing privacy concerns. The workers' attorneys contend the privacy concerns are spurious since every former Fernald worker contacted about possible overexposure has waived the privacy privilege and authorized DOE to release his or her records. The attorneys also note that DOE under the Bush administration released worker exposure information related to its Hanford, Wash., plant after the government and outside attorneys agreed to a protective order that assured privacy rights were not violated. The Fernald workers' attorneys maintain DOE is refusing to disclose the names of the workers to ensure that no additional workers are contacted by the attorneys and told about their possible overexposure - and the pending litigation seeking compensation for the alleged injuries. And as DOE remains silent, the attorneys say, the former Fernald workers are going without medical treatment for any possible radiation-related ailments they may have suffered as a result of working at the plant

  19. The development of a provincial radiation oncology service: the first year report and its implications for future developments

    International Nuclear Information System (INIS)

    Byram, D.; Joseph, D.; Bulmer, M.

    1996-01-01

    This study compares the actual first year's workload of a new radiation oncology department with that predicted, and assesses the impact of the differences, and their implications for future similar developments. The treatment records and diaries for the Geelong Hospital Radiation Oncology Department were reviewed after the first 12 months of operation. Statistics relating to the number of patients seen, number treated, diagnosis, etc., were evaluated and compared to the original estimates based upon population statistics and likely referral rates. Nine hundred and seven new patients were seen in this period, and from them 718 courses of treatment were initiated. One hundred and eighty-nine cases (20% of referrals) were seen but not treated. A further 102 treatment courses (14% of total) were initiated upon patients who had previously been irradiated. Forty-six per cent of patients were managed by 10 fractions or fewer, and a further 23% by 25 or more fractions. Eighty per cent of patients were managed by one or two fields. Electrons were used in only 14% of cases. Further calculations suggested a further possible 441 cases of referral could be expected, based upon current population statistics. Referral rates for radiation oncology are highly dependent on a number of factors. As a result, estimates of referrals and hence the size of a department required for a given population vary widely. In considering the development of units outside of major cities it is suggested that referrals are likely to be on the high side of estimates and a minimum two-machine unit is essential to cover the given workload. 5 refs., 6 tabs

  20. Broadband teleconsultation: new educational tool for radiation oncology

    International Nuclear Information System (INIS)

    Van Rhoon, G.; Kanis, B.; Zandbergen, H.; Nowak, P.; Nijdam, W.; Levendag, P.; Schuurman, J.G.

    2004-01-01

    The clinical implementation of conformal radiotherapy, e.g. tumour irradiation in 3-dimensions with very tight margins, has resulted in an additional demand for quality assurance. Within the Erasmus MC this was achieved by the inauguration of a monodisciplinary treatment plan viewing board: a daily meeting of radiation oncologists, radiation technologists and medical physicists who's approval of the patients treatment plan is mandatory to initiate the actual treatment. As the Erasmus MC is located in two parts of Rotterdam, serious inefficiency (minimal twice 30 minutes time-loss per person per day) was encountered, caused by the travelling from persons from the auxiliary location to the main departments location. The problem was solved with the installation of a telemedicine connection between both locations making the travelling superfluous. The teleconsulting functionality is obtained by 'middleware technology' which delivers a software level between presentation and the Internet. The telemedicine connection requires 20 Mbit/s. It provides instant projection of the medical images to the participants present in both teleconsulting rooms with maintaining the original high resolution of the shared images. The participants can view themselves, have audio connection and can interactively decide what applications are shared and with whom. Since the successful implementation of the local connection further applications were initiated to provide experts consultations and a so-called 'electronic second opinion outward clinic' to medical professionals in regional hospitals and even to the Netherlands Antilles. Future expansion is directed at the organisation of image guided classrooms. (author)

  1. Results of the 2004 Association of Residents in Radiation Oncology (ARRO) Survey

    International Nuclear Information System (INIS)

    Patel, Shilpen; Jagsi, Reshma; Wilson, John; Frank, Steven; Thakkar, Vipul V.; Hansen, Eric K.

    2006-01-01

    Purpose: The aim of this study was to document adequacy of training, career plans after residency, use of the in-service examination, and motivation for choice of radiation oncology as a specialty. Methods and Materials: In 2004, the Association of Residents in Radiation Oncology (ARRO) conducted a nationwide survey of all radiation oncology residents in the United States. Results: The survey was returned by 297 residents (response rate, 54%). Of the respondents, 29% were female and 71% male. The most popular career choice was joining an established private practice (38%), followed by a permanent academic career (29%). Residents for whom a permanent academic career was not their first choice were asked whether improvements in certain areas would have led them to be more likely to pursue an academic career. The most commonly chosen factors that would have had a strong or moderate influence included higher salary (81%), choice of geographic location (76%), faculty encouragement (68%), and less time commitment (68%). Of respondents in the first 3 years of training, 78% believed that they had received adequate training to proceed to the next level of training. Of those in their fourth year of training, 75% believed that they had received adequate training to enter practice. Conclusions: Multiple factors affect the educational environment of physicians in training. Data describing concerns unique to resident physicians in radiation oncology are limited. The current survey was designed to explore a variety of issues confronting radiation oncology residents. Training programs and the Residency Review Committee should consider these results when developing new policies to improve the educational experiences of residents in radiation oncology

  2. Considerations for Observational Research Using Large Data Sets in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Jagsi, Reshma, E-mail: rjagsi@med.umich.edu [Department of Radiation Oncology, University of Michigan, Ann Arbor, Michigan (United States); Bekelman, Justin E. [Departments of Radiation Oncology and Medical Ethics and Health Policy, University of Pennsylvania Perelman School of Medicine, Philadelphia, Pennsylvania (United States); Chen, Aileen [Department of Radiation Oncology, Harvard Medical School, Boston, Massachusetts (United States); Chen, Ronald C. [Department of Radiation Oncology, University of North Carolina at Chapel Hill School of Medicine, Chapel Hill, North Carolina (United States); Hoffman, Karen [Department of Radiation Oncology, Division of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Tina Shih, Ya-Chen [Department of Medicine, Section of Hospital Medicine, The University of Chicago, Chicago, Illinois (United States); Smith, Benjamin D. [Department of Radiation Oncology, Division of Radiation Oncology, and Department of Health Services Research, The University of Texas MD Anderson Cancer Center, Houston, Texas (United States); Yu, James B. [Yale School of Medicine, New Haven, Connecticut (United States)

    2014-09-01

    The radiation oncology community has witnessed growing interest in observational research conducted using large-scale data sources such as registries and claims-based data sets. With the growing emphasis on observational analyses in health care, the radiation oncology community must possess a sophisticated understanding of the methodological considerations of such studies in order to evaluate evidence appropriately to guide practice and policy. Because observational research has unique features that distinguish it from clinical trials and other forms of traditional radiation oncology research, the International Journal of Radiation Oncology, Biology, Physics assembled a panel of experts in health services research to provide a concise and well-referenced review, intended to be informative for the lay reader, as well as for scholars who wish to embark on such research without prior experience. This review begins by discussing the types of research questions relevant to radiation oncology that large-scale databases may help illuminate. It then describes major potential data sources for such endeavors, including information regarding access and insights regarding the strengths and limitations of each. Finally, it provides guidance regarding the analytical challenges that observational studies must confront, along with discussion of the techniques that have been developed to help minimize the impact of certain common analytical issues in observational analysis. Features characterizing a well-designed observational study include clearly defined research questions, careful selection of an appropriate data source, consultation with investigators with relevant methodological expertise, inclusion of sensitivity analyses, caution not to overinterpret small but significant differences, and recognition of limitations when trying to evaluate causality. This review concludes that carefully designed and executed studies using observational data that possess these qualities hold

  3. Considerations for Observational Research Using Large Data Sets in Radiation Oncology

    International Nuclear Information System (INIS)

    Jagsi, Reshma; Bekelman, Justin E.; Chen, Aileen; Chen, Ronald C.; Hoffman, Karen; Tina Shih, Ya-Chen; Smith, Benjamin D.; Yu, James B.

    2014-01-01

    The radiation oncology community has witnessed growing interest in observational research conducted using large-scale data sources such as registries and claims-based data sets. With the growing emphasis on observational analyses in health care, the radiation oncology community must possess a sophisticated understanding of the methodological considerations of such studies in order to evaluate evidence appropriately to guide practice and policy. Because observational research has unique features that distinguish it from clinical trials and other forms of traditional radiation oncology research, the International Journal of Radiation Oncology, Biology, Physics assembled a panel of experts in health services research to provide a concise and well-referenced review, intended to be informative for the lay reader, as well as for scholars who wish to embark on such research without prior experience. This review begins by discussing the types of research questions relevant to radiation oncology that large-scale databases may help illuminate. It then describes major potential data sources for such endeavors, including information regarding access and insights regarding the strengths and limitations of each. Finally, it provides guidance regarding the analytical challenges that observational studies must confront, along with discussion of the techniques that have been developed to help minimize the impact of certain common analytical issues in observational analysis. Features characterizing a well-designed observational study include clearly defined research questions, careful selection of an appropriate data source, consultation with investigators with relevant methodological expertise, inclusion of sensitivity analyses, caution not to overinterpret small but significant differences, and recognition of limitations when trying to evaluate causality. This review concludes that carefully designed and executed studies using observational data that possess these qualities hold

  4. An evaluation of a paediatric radiation oncology teaching programme incorporating a SCORPIO teaching model.

    Science.gov (United States)

    Ahern, Verity; Klein, Linda; Bentvelzen, Adam; Garlan, Karen; Jeffery, Heather

    2011-04-01

    Many radiation oncology registrars have no exposure to paediatrics during their training. To address this, the Paediatric Special Interest Group of the Royal Australian and New Zealand College of Radiologists has convened a biennial teaching course since 1997. The 2009 course incorporated the use of a Structured, Clinical, Objective-Referenced, Problem-orientated, Integrated and Organized (SCORPIO) teaching model for small group tutorials. This study evaluates whether the paediatric radiation oncology curriculum can be adapted to the SCORPIO teaching model and to evaluate the revised course from the registrars' perspective. Teaching and learning resources included a pre-course reading list, a lecture series programme and a SCORPIO workshop. Three evaluation instruments were developed: an overall Course Evaluation Survey for all participants, a SCORPIO Workshop Survey for registrars and a Teacher's SCORPIO Workshop Survey. Forty-five radiation oncology registrars, 14 radiation therapists and five paediatric oncology registrars attended. Seventy-three per cent (47/64) of all participants completed the Course Evaluation Survey and 95% (38/40) of registrars completed the SCORPIO Workshop Survey. All teachers completed the Teacher's SCORPIO Survey (10/10). The overall educational experience was rated as good or excellent by 93% (43/47) of respondents. Ratings of satisfaction with lecture sessions were predominantly good or excellent. Registrars gave the SCORPIO workshop high ratings on each of 10 aspects of quality, with 82% allocating an excellent rating overall for the SCORPIO activity. Both registrars and teachers recommended more time for the SCORPIO stations. The 2009 course met the educational needs of the radiation oncology registrars and the SCORPIO workshop was a highly valued educational component. © 2011 The Authors. Journal of Medical Imaging and Radiation Oncology © 2011 The Royal Australian and New Zealand College of Radiologists.

  5. Radiation Oncology Terminology Linker: A Step Towards a Linked Data Knowledge Base.

    Science.gov (United States)

    Lustberg, Tim; van Soest, Johan; Fick, Peter; Fijten, Rianne; Hendriks, Tim; Puts, Sander; Dekker, Andre

    2018-01-01

    Performing image feature extraction in radiation oncology is often dependent on the organ and tumor delineations provided by clinical staff. These delineation names are free text DICOM metadata fields resulting in undefined information, which requires effort to use in large-scale image feature extraction efforts. In this work we present a scale-able solution to overcome these naming convention challenges with a REST service using Semantic Web technology to convert this information to linked data. As a proof of concept an open source software is used to compute radiation oncology image features. The results of this work can be found in a public Bitbucket repository.

  6. Evaluation of Safety in a Radiation Oncology Setting Using Failure Mode and Effects Analysis

    International Nuclear Information System (INIS)

    Ford, Eric C.; Gaudette, Ray; Myers, Lee; Vanderver, Bruce; Engineer, Lilly; Zellars, Richard; Song, Danny Y.; Wong, John; DeWeese, Theodore L.

    2009-01-01

    Purpose: Failure mode and effects analysis (FMEA) is a widely used tool for prospectively evaluating safety and reliability. We report our experiences in applying FMEA in the setting of radiation oncology. Methods and Materials: We performed an FMEA analysis for our external beam radiation therapy service, which consisted of the following tasks: (1) create a visual map of the process, (2) identify possible failure modes; assign risk probability numbers (RPN) to each failure mode based on tabulated scores for the severity, frequency of occurrence, and detectability, each on a scale of 1 to 10; and (3) identify improvements that are both feasible and effective. The RPN scores can span a range of 1 to 1000, with higher scores indicating the relative importance of a given failure mode. Results: Our process map consisted of 269 different nodes. We identified 127 possible failure modes with RPN scores ranging from 2 to 160. Fifteen of the top-ranked failure modes were considered for process improvements, representing RPN scores of 75 and more. These specific improvement suggestions were incorporated into our practice with a review and implementation by each department team responsible for the process. Conclusions: The FMEA technique provides a systematic method for finding vulnerabilities in a process before they result in an error. The FMEA framework can naturally incorporate further quantification and monitoring. A general-use system for incident and near miss reporting would be useful in this regard.

  7. Oncologic imaging

    International Nuclear Information System (INIS)

    Bragg, D.G.; Rubin, P.; Youker, J.E.

    1985-01-01

    This book presents papers on nuclear medicine. Topics considered include the classification of cancers, oncologic diagnosis, brain and spinal cord neoplasms, lymph node metastases, the larynx and hypopharynx, thyroid cancer, breast cancer, esophageal cancer, bladder cancer, tumors of the skeletal system, pediatric oncology, computed tomography and radiation therapy treatment planning, and the impact of future technology on oncologic diagnosis

  8. Assessing the Value of an Optional Radiation Oncology Clinical Rotation During the Core Clerkships in Medical School

    Energy Technology Data Exchange (ETDEWEB)

    Zaorsky, Nicholas G.; Malatesta, Theresa M.; Den, Robert B.; Wuthrick, Evan; Ahn, Peter H.; Werner-Wasik, Maria; Shi, Wenyin; Dicker, Adam P.; Anne, P. Rani; Bar-Ad, Voichita [Department of Radiation Oncology, Jefferson Medical College, Kimmel Cancer Center, Thomas Jefferson University, Philadelphia, PA (United States); Showalter, Timothy N., E-mail: timothy.showalter@jeffersonhospital.org [Department of Radiation Oncology, Jefferson Medical College, Kimmel Cancer Center, Thomas Jefferson University, Philadelphia, PA (United States)

    2012-07-15

    Purpose: Few medical students are given proper clinical training in oncology, much less radiation oncology. We attempted to assess the value of adding a radiation oncology clinical rotation to the medical school curriculum. Methods and Materials: In July 2010, Jefferson Medical College began to offer a 3-week radiation oncology rotation as an elective course for third-year medical students during the core surgical clerkship. During 2010 to 2012, 52 medical students chose to enroll in this rotation. The rotation included outpatient clinics, inpatient consults, didactic sessions, and case-based presentations by the students. Tests of students' knowledge of radiation oncology were administered anonymously before and after the rotation to evaluate the educational effectiveness of the rotation. Students and radiation oncology faculty were given surveys to assess feedback about the rotation. Results: The students' prerotation test scores had an average of 64% (95% confidence interval [CI], 61-66%). The postrotation test scores improved to an average of 82% (95% CI, 80-83%; 18% absolute improvement). In examination question analysis, scores improved in clinical oncology from 63% to 79%, in radiobiology from 70% to 77%, and in medical physics from 62% to 88%. Improvements in all sections but radiobiology were statistically significant. Students rated the usefulness of the rotation as 8.1 (scale 1-9; 95% CI, 7.3-9.0), their understanding of radiation oncology as a result of the rotation as 8.8 (95% CI, 8.5-9.1), and their recommendation of the rotation to a classmate as 8.2 (95% CI, 7.6-9.0). Conclusions: Integrating a radiation oncology clinical rotation into the medical school curriculum improves student knowledge of radiation oncology, including aspects of clinical oncology, radiobiology, and medical physics. The rotation is appreciated by both students and faculty.

  9. Assessing the Value of an Optional Radiation Oncology Clinical Rotation During the Core Clerkships in Medical School

    International Nuclear Information System (INIS)

    Zaorsky, Nicholas G.; Malatesta, Theresa M.; Den, Robert B.; Wuthrick, Evan; Ahn, Peter H.; Werner-Wasik, Maria; Shi, Wenyin; Dicker, Adam P.; Anne, P. Rani; Bar-Ad, Voichita; Showalter, Timothy N.

    2012-01-01

    Purpose: Few medical students are given proper clinical training in oncology, much less radiation oncology. We attempted to assess the value of adding a radiation oncology clinical rotation to the medical school curriculum. Methods and Materials: In July 2010, Jefferson Medical College began to offer a 3-week radiation oncology rotation as an elective course for third-year medical students during the core surgical clerkship. During 2010 to 2012, 52 medical students chose to enroll in this rotation. The rotation included outpatient clinics, inpatient consults, didactic sessions, and case-based presentations by the students. Tests of students’ knowledge of radiation oncology were administered anonymously before and after the rotation to evaluate the educational effectiveness of the rotation. Students and radiation oncology faculty were given surveys to assess feedback about the rotation. Results: The students’ prerotation test scores had an average of 64% (95% confidence interval [CI], 61–66%). The postrotation test scores improved to an average of 82% (95% CI, 80–83%; 18% absolute improvement). In examination question analysis, scores improved in clinical oncology from 63% to 79%, in radiobiology from 70% to 77%, and in medical physics from 62% to 88%. Improvements in all sections but radiobiology were statistically significant. Students rated the usefulness of the rotation as 8.1 (scale 1–9; 95% CI, 7.3–9.0), their understanding of radiation oncology as a result of the rotation as 8.8 (95% CI, 8.5–9.1), and their recommendation of the rotation to a classmate as 8.2 (95% CI, 7.6–9.0). Conclusions: Integrating a radiation oncology clinical rotation into the medical school curriculum improves student knowledge of radiation oncology, including aspects of clinical oncology, radiobiology, and medical physics. The rotation is appreciated by both students and faculty.

  10. Academic Career Selection and Retention in Radiation Oncology: The Joint Center for Radiation Therapy Experience

    International Nuclear Information System (INIS)

    Balboni, Tracy A.; Chen, M.-H.; Harris, Jay R.; Recht, Abram; Stevenson, Mary Ann; D'Amico, Anthony V.

    2007-01-01

    Purpose: The United States healthcare system has witnessed declining reimbursement and increasing documentation requirements for longer than 10 years. These have decreased the time available to academic faculty for teaching and mentorship. The impact of these changes on the career choices of residents is unknown. The purpose of this report was to determine whether changes have occurred during the past decade in the proportion of radiation oncology trainees from a single institution entering and staying in academic medicine. Methods and Materials: We performed a review of the resident employment experience of Harvard Joint Center for Radiation Therapy residents graduating during 13 recent consecutive years (n = 48 residents). The outcomes analyzed were the initial selection of an academic vs. nonacademic career and career changes during the first 3 years after graduation. Results: Of the 48 residents, 65% pursued an academic career immediately after graduation, and 44% remained in academics at the last follow-up, after a median of 6 years. A later graduation year was associated with a decrease in the proportion of graduates immediately entering academic medicine (odds ratio, 0.78; 95% confidence interval, 0.65-0.94). However, the retention rate at 3 years of those who did immediately enter academics increased with a later graduation year (p = 0.03). Conclusion: During a period marked by notable changes in the academic healthcare environment, the proportion of graduating Harvard Joint Center for Radiation Therapy residents pursuing academic careers has been declining; however, despite this decline, the retention rates in academia have increased

  11. Application of radiation-induced apoptosis in radiation oncology and radiation protection

    International Nuclear Information System (INIS)

    Crompton, N.E.A.; Emery, G.C.; Ozsahin, M.; Menz, R.; Knesplova, L.; Larsson, B.

    1997-01-01

    A rapid assay of the ability of lymphocytes to respond to radiation-induced damage is presented. Age and genetic dependence of radiation response have been quantified. The assay is sensitive to low doses of radiation. Its ability to assess the cytotoxic response of blood capillaries to radiation has been evaluated. (author)

  12. Authorship in Radiation Oncology: Proliferation Trends Over 30 Years

    Energy Technology Data Exchange (ETDEWEB)

    Ojerholm, Eric, E-mail: eric.ojerholm@uphs.upenn.edu; Swisher-McClure, Samuel

    2015-11-15

    Purpose: To investigate authorship trends in the radiation oncology literature. Methods and Materials: We examined the authorship credits of “original research articles” within 2 popular radiation oncology journals–International Journal of Radiation Oncology, Biology, Physics and Radiotherapy and Oncology–in 1984, 1994, 2004, and 2014. We compared the number of authors per publication during these 4 time periods using simple linear regression as a test for trend. We investigated additional author characteristics in a subset of articles. Results: A total of 2005 articles were eligible. The mean number of authors per publication rose from 4.3 in 1984 to 9.1 in 2014 (P<.001). On subset analysis of 400 articles, there was an increase in the percentage of multidisciplinary bylines (from 52% to 72%), multi-institutional bylines (from 20% to 53%), and publications with a trainee first author (from 16% to 56%) during the study period. Conclusions: The mean number of authors per publication has more than doubled over the last 30 years in the radiation oncology literature. Possible explanations include increasingly complex and collaborative research as well as honorary authorship. Explicit documentation of author contributions could help ensure that scientific work is credited according to accepted standards.

  13. R-IDEAL : A Framework for Systematic Clinical Evaluation of Technical Innovations in Radiation Oncology

    NARCIS (Netherlands)

    Verkooijen, Helena M; Kerkmeijer, LGW; Fuller, Clifton D; Huddart, Robbert; Faivre-Finn, Corinne; Verheij, Marcel; Mook, Stella; Sahgal, Arjun; Hall, Emma; Schultz, Chris

    2017-01-01

    The pace of innovation in radiation oncology is high and the window of opportunity for evaluation narrow. Financial incentives, industry pressure, and patients' demand for high-tech treatments have led to widespread implementation of innovations before, or even without, robust evidence of improved

  14. MO-AB-204-00: Interoperability in Radiation Oncology: IHE-RO Committee Update

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2016-06-15

    You’ve experienced the frustration: vendor A’s device claims to work with vendor B’s device, but the practice doesn’t match the promise. Getting devices working together is the hidden art that Radiology and Radiation Oncology staff have to master. To assist with that difficult process, the Integrating the Healthcare Enterprise (IHE) effort was established in 1998, with the coordination of the Radiological Society of North America. Integrating the Healthcare Enterprise (IHE) is a consortium of healthcare professionals and industry partners focused on improving the way computer systems interconnect and exchange information. This is done by coordinating the use of published standards like DICOM and HL7. Several clinical and operational IHE domains exist in the healthcare arena, including Radiology and Radiation Oncology. The ASTRO-sponsored IHE Radiation Oncology (IHE-RO) domain focuses on radiation oncology specific information exchange. This session will explore the IHE Radiology and IHE RO process for; IHE solicitation process for new profiles. Improving the way computer systems interconnect and exchange information in the healthcare enterprise Supporting interconnectivity descriptions and proof of adherence by vendors Testing and assuring the vendor solutions to connectivity problems. Including IHE profiles in RFPs for future software and hardware purchases. Learning Objectives: Understand IHE role in improving interoperability in health care. Understand process of profile development and implantation. Understand how vendors prove adherence to IHE RO profiles. S. Hadley, ASTRO Supported Activity.

  15. Hypoxia and tumor metabolism in radiation oncology: Targets visualized by positron emission tomography

    NARCIS (Netherlands)

    Wijsman, R.; Kaanders, J.H.A.M.; Oyen, W.J.G.; Bussink, J.

    2013-01-01

    Due to the amazing leap of technology in radiation oncology in the past few years, cancer treatment will become more individualized. Molecular imaging with PET contributed to this with its many tracers available, each of them visualizing a specific feature of a tumor and its microenvironment

  16. Investigation of the possible use of Arglabin, new antitumor medicine to prevent oncological diseases after radiation

    International Nuclear Information System (INIS)

    Shaikenov, T.; Karabalin, B.; Rakhimov, K.; Adekenov, S.

    1996-01-01

    Background: One of the heaviest effects of radiation exposure and its pollutants to the environment is a growth of oncologic diseases as a sequence of breakage of genetic body substance and transmission of Genetic load to the next generation. People of Kazakstan are anxious of the present situation with harmful effect of remaining radiation doses.Purpose of research: the examination of molecular mechanisms of action for a new drug 'Arglabin' was done with the purpose of preventing the malignant tumor occurrence for those people living on the territory of higher risk (in high radiation locations). Research work of the mechanisms of action for 'Arglabin' drug: - examination of the drug effectiveness to enzymes of prenylated proteins; - examination of the drug effectiveness on functioning the oncogene products; - examination of drug metabolism. Research work of the possibility for using 'Arglabin' to prevent oncology diseases includes: - establishment of experimental model of increased risk of oncologic disease on different groups of laboratory animals using the low-dosage radiation sphere; - examination of the drug effectiveness in oncology diseases prevention; - determination of mechanisms and the prevention's results on cancer

  17. Quality in radiotherapy: the actions of the French society for radiation oncology

    International Nuclear Information System (INIS)

    Mazeron, J.J.; Mornex, F.; Eschwege, F.; Lartigau, E.

    2009-01-01

    In response to recent accidents at external radiotherapy units, the t Minister of Health has set up an extensive programme to improve the quality and safety of this type of treatment. We give an account here of the activities carried out by the French Society of Radiation Oncology (SFRO) as part of this programme, commonly referred to as the 'road-map'. (authors)

  18. Establishing a Global Radiation Oncology Collaboration in Education (GRaCE): Objectives and priorities

    NARCIS (Netherlands)

    Turner, S.; Eriksen, J.G.; Trotter, T.; Verfaillie, C.; Benstead, K.; Giuliani, M.; Poortmans, P.; Holt, T.; Brennan, S.; Potter, R.

    2015-01-01

    Representatives from countries and regions world-wide who have implemented modern competency-based radiation- or clinical oncology curricula for training medical specialists, met to determine the feasibility and value of an ongoing international collaboration. In this forum, educational leaders from

  19. MO-AB-204-00: Interoperability in Radiation Oncology: IHE-RO Committee Update

    International Nuclear Information System (INIS)

    2016-01-01

    You’ve experienced the frustration: vendor A’s device claims to work with vendor B’s device, but the practice doesn’t match the promise. Getting devices working together is the hidden art that Radiology and Radiation Oncology staff have to master. To assist with that difficult process, the Integrating the Healthcare Enterprise (IHE) effort was established in 1998, with the coordination of the Radiological Society of North America. Integrating the Healthcare Enterprise (IHE) is a consortium of healthcare professionals and industry partners focused on improving the way computer systems interconnect and exchange information. This is done by coordinating the use of published standards like DICOM and HL7. Several clinical and operational IHE domains exist in the healthcare arena, including Radiology and Radiation Oncology. The ASTRO-sponsored IHE Radiation Oncology (IHE-RO) domain focuses on radiation oncology specific information exchange. This session will explore the IHE Radiology and IHE RO process for; IHE solicitation process for new profiles. Improving the way computer systems interconnect and exchange information in the healthcare enterprise Supporting interconnectivity descriptions and proof of adherence by vendors Testing and assuring the vendor solutions to connectivity problems. Including IHE profiles in RFPs for future software and hardware purchases. Learning Objectives: Understand IHE role in improving interoperability in health care. Understand process of profile development and implantation. Understand how vendors prove adherence to IHE RO profiles. S. Hadley, ASTRO Supported Activity

  20. Mentorship Programs in Radiation Oncology Residency Training Programs: A Critical Unmet Need

    Energy Technology Data Exchange (ETDEWEB)

    Dhami, Gurleen; Gao, Wendy; Gensheimer, Michael F. [Department of Radiation Oncology, University of Washington, Seattle, Washington (United States); Trister, Andrew D. [Sage Bionetworks, Seattle, Washington (United States); Kane, Gabrielle [Department of Radiation Oncology, University of Washington, Seattle, Washington (United States); Zeng, Jing, E-mail: jzeng13@uw.edu [Department of Radiation Oncology, University of Washington, Seattle, Washington (United States)

    2016-01-01

    Purpose: To conduct a nationwide survey to evaluate the current status of resident mentorship in radiation oncology. Methods and Materials: An anonymous electronic questionnaire was sent to all residents and recent graduates at US Accreditation Council for Graduate Medical Education–accredited radiation oncology residency programs, identified in the member directory of the Association of Residents in Radiation Oncology. Factors predictive of having a mentor and satisfaction with the mentorship experience were identified using univariate and multivariate analyses. Results: The survey response rate was 25%, with 85% of respondents reporting that mentorship plays a critical role in residency training, whereas only 53% had a current mentor. Larger programs (≥10 faculty, P=.004; and ≥10 residents, P<.001) were more likely to offer a formal mentorship program, which makes it more likely for residents to have an active mentor (88% vs 44%). Residents in a formal mentoring program reported being more satisfied with the overall mentorship experience (univariate odds ratio 8.77, P<.001; multivariate odds ratio 5, P<.001). On multivariate analysis, women were less likely to be satisfied with the mentorship experience. Conclusions: This is the first survey focusing on the status of residency mentorship in radiation oncology. Our survey highlights the unmet need for mentorship in residency programs.

  1. Current status of SCI and SCIE publications in the field of radiation oncology in Korea

    International Nuclear Information System (INIS)

    Kang, Jin Oh

    2007-01-01

    To investigate current status of SCI (Science Citation Index) and SCI Expanded publication of Korean radiation oncologists. Published SCI and SCIE articles the conditions of first author's address as 'Korea' and 'Radiation Oncology' or 'Therapeutic Radiology' were searched from Pubmed database. From 1990 to 2006, 146 SCI articles and 32 SCIE articles were published. Most frequently published journal was international Journal of Radiation Oncology Biology Physics, where 56 articles were found. Articles with 30 or more citations were only five and 10 or more citations were 26. Yonsei University, which had 57 published articles, was the top among 19 affiliations which had one or more SCI and SCIE articles. Authors with five or more articles were 9 and Seong J. of Yonsei University was the top with 19 articles. The investigations showed disappointing results. The members of Korean Society of Radiation Oncologists must consider a strategy to increase SCI and SCIE publications

  2. American Society for Radiation Oncology (ASTRO) 2012 Workforce Study: The Radiation Oncologists' and Residents' Perspectives

    Energy Technology Data Exchange (ETDEWEB)

    Pohar, Surjeet, E-mail: spohar@iuhealth.org [Indiana University Health East, Indianapolis, Indiana (United States); Fung, Claire Y. [Commonwealth Newburyport Cancer Center, Newburyport, Massachusetts (United States); Hopkins, Shane [William R. Bliss Cancer Center, Ames, Iowa (United States); Miller, Robert [Mayo Clinic, Rochester, Minnesota (United States); Azawi, Samar [VA Veteran Hospital/University of California Irvine, Newport Beach, California (United States); Arnone, Anna; Patton, Caroline [ASTRO, Fairfax, Virginia (United States); Olsen, Christine [Massachusetts General Hospital, Boston, Massachusetts (United States)

    2013-12-01

    Purpose: The American Society for Radiation Oncology (ASTRO) conducted the 2012 Radiation Oncology Workforce Survey to obtain an up-to-date picture of the workforce, assess its needs and concerns, and identify quality and safety improvement opportunities. The results pertaining to radiation oncologists (ROs) and residents (RORs) are presented here. Methods: The ASTRO Workforce Subcommittee, in collaboration with allied radiation oncology professional societies, conducted a survey study in early 2012. An online survey questionnaire was sent to all segments of the radiation oncology workforce. Respondents who were actively working were included in the analysis. This manuscript describes the data for ROs and RORs. Results: A total of 3618 ROs and 568 RORs were surveyed. The response rate for both groups was 29%, with 1047 RO and 165 ROR responses. Among ROs, the 2 most common racial groups were white (80%) and Asian (15%), and the male-to-female ratio was 2.85 (74% male). The median age of ROs was 51. ROs averaged 253.4 new patient consults in a year and 22.9 on-treatment patients. More than 86% of ROs reported being satisfied or very satisfied overall with their career. Close to half of ROs reported having burnout feelings. There was a trend toward more frequent burnout feelings with increasing numbers of new patient consults. ROs' top concerns were related to documentation, reimbursement, and patients' health insurance coverage. Ninety-five percent of ROs felt confident when implementing new technology. Fifty-one percent of ROs thought that the supply of ROs was balanced with demand, and 33% perceived an oversupply. Conclusions: This study provides a current snapshot of the 2012 radiation oncology physician workforce. There was a predominance of whites and men. Job satisfaction level was high. However a substantial fraction of ROs reported burnout feelings. Perceptions about supply and demand balance were mixed. ROs top concerns reflect areas of attention

  3. Assessment of Patient Safety Culture in an Adult Oncology Department in Saudi Arabia

    Directory of Open Access Journals (Sweden)

    Waleed Alharbi

    2018-05-01

    Full Text Available Objectives: We sought to evaluate patient safety culture across different healthcare professionals from different countries of origin working in an adult oncology department in a medical facility in Saudi Arabia. Methods: This cross-sectional survey of 130 healthcare staff (doctors, pharmacists, nurses was conducted in February 2017. We used the Hospital Survey of Patient Safety Culture (HSOPSC to examine healthcare staff perceptions of safety culture. Results: A total of 127 questionnaires were returned, yielding a response rate of 97.7%. Eight out of 12 HSOPSC composites were considered areas for improvement (percent positivity < 50.0%. Significantly different mean scores were observed across the three professional groups in all 12 HSOPSC composites. Doctors tended to rate patient safety culture significantly more positively than nurses or pharmacists. Nurses scored significantly lower than pharmacists in the majority of HSOPSC composites. No significant differences in patient safety culture composite scores were observed between Saudi/Gulf Cooperation Council (GCC and non-Saudi/GCC groups. Regression analysis showed that the frequency of reported events is predicted by feedback and communication about errors, and teamwork across units. Perception of patient safety is associated with respondents’ profession and teamwork across units. Conclusions: This study brings to the fore the assumption that all healthcare professionals have a shared understanding of patient safety. We urge healthcare leaders and policy makers to look at patient safety culture at this granular level in their contexts and use this information to develop strategies and training to improve patient safety culture.

  4. Monitoring of patients in the Oncology department of the Clinical Hospital

    International Nuclear Information System (INIS)

    De Quiroz, J.

    2010-01-01

    An important number of patients that visit the Oncology department o the Clinicas Hospital lost sight at some stage of their evolution. Our objective was to quantify the proportion of patients who are lost and describe the time spent in the service and its relationship with variables such as age, sex, origin of the patient and progress of the disease, for which we performed a descriptive observational study with an analytical component of 435 stories clinics patients with confirmed diagnosis of cancer, treated from January 2001 to December 2004, in order to have a minimum of 5 years of follow-up potential. Data were processed with Excel 2003. Patients had between 15-85 years old with a mean and median of 52 ± 14 years DS. Two hundred Seventy women and 165 were men, 232 were from the metropolitan area. The time of length of service was 0-114 months with a median of 8 and an average DS 21 months ± 27 months. As of December 2009 31 117 patients had died 36 remained in control and 282 were lost from sight. We found no relationship between age (p = 0.1) nor the state of progress of the disease at diagnosis (p = 0.21) If there were significant differences with greater probability of loss tracking men (p = 0.009) and from sites outside the metropolitan area (p = 0.04). The number of patients who are lost is very large and we must develop strategies more effective monitoring

  5. Department of Radiation and Environmental Biology - Overview

    International Nuclear Information System (INIS)

    Cebulska-Wasilewska, A.

    1999-01-01

    californium 252 neutrons from KAERI source. The third part of our effort concerns an application of different radiation sources for clinical cancer therapy. In cooperation with dr Jacek Capala we have done experiments on Medical Research Reactor in Brookhaven Laboratory. We have also introduced a COMET assay in their laboratory. This is an excellent feeling when both cooperating sides may benefit from co-operation. The year 1998 was also very attractive in the sense of many interesting visits to our Department. All of them we enjoyed a lot. We were honored to host Dr Diana Anderson from BIBRA International, Carshalton, UK. We are happy to see that her visits have become a tradition so much profitable for both our friendship and programs. The end of the year was equally touching as the beginning when X-ray machine had arrived, at the beginning of December, I won myself, a prize from the International Mutagenesis Society for the outstanding presentation; on the 3rd International Conference of Mutagenesis in Human Populations. I really respect both, working issue of the Conference ''Understanding Gene and Environmental Interactions for Disease Prevention'' and a prize itself (Five-year-subscription of International Journal of Environmental and Molecular Mutagenesis). Whoop! I am proud of myself and of the people in my Department!!. (author)

  6. Future trends in the supply and demand for radiation oncology physicists.

    Science.gov (United States)

    Mills, Michael D; Thornewill, Judah; Esterhay, Robert J

    2010-04-12

    Significant controversy surrounds the 2012 / 2014 decision announced by the Trustees of the American Board of Radiology (ABR) in October of 2007. According to the ABR, only medical physicists who are graduates of a Commission on Accreditation of Medical Physics Education Programs, Inc. (CAMPEP) accredited academic or residency program will be admitted for examination in the years 2012 and 2013. Only graduates of a CAMPEP accredited residency program will be admitted for examination beginning in the year 2014. An essential question facing the radiation oncology physics community is an estimation of supply and demand for medical physicists through the year 2020. To that end, a Demand & Supply dynamic model was created using STELLA software. Inputs into the model include: a) projected new cancer incidence and prevalence 1990-2020; b) AAPM member ages and retirement projections 1990-2020; c) number of ABR physics diplomates 1990-2009; d) number of patients per Qualified Medical Physicist from Abt Reports I (1995), II (2002) and III (2008); e) non-CAMPEP physicists trained 1990-2009 and projected through 2014; f) CAMPEP physicists trained 1993-2008 and projected through 2014; and g) working Qualified Medical Physicists in radiation oncology in the United States (1990-2007). The model indicates that the number of qualified medical physicists working in radiation oncology required to meet demand in 2020 will be 150-175 per year. Because there is some elasticity in the workforce, a portion of the work effort might be assumed by practicing medical physicists. However, the minimum number of new radiation oncology physicists (ROPs) required for the health of the profession is estimated to be 125 per year in 2020. The radiation oncology physics community should plan to build residency programs to support these numbers for the future of the profession.

  7. Ontario Radiation Oncology Residents' Needs in the First Postgraduate Year-Residents' Perspective Survey

    International Nuclear Information System (INIS)

    Szumacher, Ewa; Warner, Eiran; Zhang Liying; Kane, Gabrielle; Ackerman, Ida; Nyhof-Young, Joyce; Agboola, Olusegun; Metz, Catherine de; Rodrigues, George; Voruganti, Sachi; Rappolt, Susan

    2007-01-01

    Purpose: To assess radiation oncology residents' needs and satisfaction in their first postgraduate year (PGY-1) in the province of Ontario. Methods and Materials: Of 62 radiation oncology residents, 58 who had completed their PGY-1 and were either enrolled or had graduated in 2006 were invited to participate in a 31-item survey. The questionnaire explored PGY-1 residents' needs and satisfaction in four domains: clinical workload, faculty/learning environment, stress level, and discrimination/harassment. The Fisher's exact and Wilcoxon nonparametric tests were used to determine relationships between covariate items and summary scores. Results: Of 58 eligible residents, 44 (75%) responded. Eighty-four percent of residents felt that their ward and call duties were appropriate. More than 50% of respondents indicated that they often felt isolated from their radiation oncology program. Only 77% agreed that they received adequate feedback, and 40% received sufficient counseling regarding career planning. More than 93% of respondents thought that faculty members had contributed significantly to their learning experience. Approximately 50% of residents experienced excessive stress and inadequate time for leisure or for reading the medical literature. Less than 10% of residents indicated that they had been harassed or experienced discrimination. Eighty-three percent agreed or strongly agreed that their PGY-1 experience had been outstanding. Conclusions: Most Ontario residents were satisfied with their PGY-1 training program. More counseling by radiation oncology faculty members should be offered to help residents with career planning. The residents might also benefit from more exposure to 'radiation oncology' and an introduction to stress management strategies

  8. The Negative Impact of Stark Law Exemptions on Graduate Medical Education and Health Care Costs: The Example of Radiation Oncology

    International Nuclear Information System (INIS)

    Anscher, Mitchell S.; Anscher, Barbara M.; Bradley, Cathy J.

    2010-01-01

    Purpose: To survey radiation oncology training programs to determine the impact of ownership of radiation oncology facilities by non-radiation oncologists on these training programs and to place these findings in a health policy context based on data from the literature. Methods and Materials: A survey was designed and e-mailed to directors of all 81 U.S. radiation oncology training programs in this country. Also, the medical and health economic literature was reviewed to determine the impact that ownership of radiation oncology facilities by non-radiation oncologists may have on patient care and health care costs. Prostate cancer treatment is used to illustrate the primary findings. Results: Seventy-three percent of the surveyed programs responded. Ownership of radiation oncology facilities by non-radiation oncologists is a widespread phenomenon. More than 50% of survey respondents reported the existence of these arrangements in their communities, with a resultant reduction in patient volumes 87% of the time. Twenty-seven percent of programs in communities with these business arrangements reported a negative impact on residency training as a result of decreased referrals to their centers. Furthermore, the literature suggests that ownership of radiation oncology facilities by non-radiation oncologists is associated with both increased utilization and increased costs but is not associated with increased access to services in traditionally underserved areas. Conclusions: Ownership of radiation oncology facilities by non-radiation oncologists appears to have a negative impact on residency training by shifting patients away from training programs and into community practices. In addition, the literature supports the conclusion that self-referral results in overutilization of expensive services without benefit to patients. As a result of these findings, recommendations are made to study further how physician ownership of radiation oncology facilities influence graduate

  9. Radiation protection in radio-oncology; Strahlenschutz in der Radioonkologie

    Energy Technology Data Exchange (ETDEWEB)

    Hartz, Juliane Marie; Joost, Sophie; Hildebrandt, Guido [Universitaetsmedizin Rostock (Germany). Klinik und Poliklinik fuer Strahlentherapie

    2017-07-01

    Based on the high technical status of radiation protection the occupational exposure of radiological personnel is no more of predominant importance. No defined dose limits exist for patients in the frame of therapeutic applications in contrary to the radiological personnel. As a consequence walk-downs radiotherapeutic institutions twice the year have been initiated in order to guarantee a maximum of radiation protection for patient's treatment. An actualization of radiation protection knowledge of the radiological personnel is required.

  10. An Evaluation of Departmental Radiation Oncology Incident Reports: Anticipating a National Reporting System

    International Nuclear Information System (INIS)

    Terezakis, Stephanie A.; Harris, Kendra M.; Ford, Eric; Michalski, Jeff; DeWeese, Theodore; Santanam, Lakshmi; Mutic, Sasa; Gay, Hiram

    2013-01-01

    Purpose: Systems to ensure patient safety are of critical importance. The electronic incident reporting systems (IRS) of 2 large academic radiation oncology departments were evaluated for events that may be suitable for submission to a national reporting system (NRS). Methods and Materials: All events recorded in the combined IRS were evaluated from 2007 through 2010. Incidents were graded for potential severity using the validated French Nuclear Safety Authority (ASN) 5-point scale. These incidents were categorized into 7 groups: (1) human error, (2) software error, (3) hardware error, (4) error in communication between 2 humans, (5) error at the human-software interface, (6) error at the software-hardware interface, and (7) error at the human-hardware interface. Results: Between the 2 systems, 4407 incidents were reported. Of these events, 1507 (34%) were considered to have the potential for clinical consequences. Of these 1507 events, 149 (10%) were rated as having a potential severity of ≥2. Of these 149 events, the committee determined that 79 (53%) of these events would be submittable to a NRS of which the majority was related to human error or to the human-software interface. Conclusions: A significant number of incidents were identified in this analysis. The majority of events in this study were related to human error and to the human-software interface, further supporting the need for a NRS to facilitate field-wide learning and system improvement

  11. An Evaluation of Departmental Radiation Oncology Incident Reports: Anticipating a National Reporting System

    Energy Technology Data Exchange (ETDEWEB)

    Terezakis, Stephanie A., E-mail: stereza1@jhmi.edu [Department of Radiation Oncology and Molecular Radiation Sciences, The Johns Hopkins University School of Medicine, Baltimore, Maryland (United States); Harris, Kendra M. [Department of Radiation Oncology and Molecular Radiation Sciences, The Johns Hopkins University School of Medicine, Baltimore, Maryland (United States); Ford, Eric [Department of Radiation Oncology and Molecular Radiation Sciences, The Johns Hopkins University School of Medicine, Baltimore, Maryland (United States); Department of Radiation Oncology, University of Washington, Seattle, Washington (United States); Michalski, Jeff [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, Missouri (United States); DeWeese, Theodore [Department of Radiation Oncology and Molecular Radiation Sciences, The Johns Hopkins University School of Medicine, Baltimore, Maryland (United States); Santanam, Lakshmi; Mutic, Sasa; Gay, Hiram [Department of Radiation Oncology, Washington University School of Medicine, St. Louis, Missouri (United States)

    2013-03-15

    Purpose: Systems to ensure patient safety are of critical importance. The electronic incident reporting systems (IRS) of 2 large academic radiation oncology departments were evaluated for events that may be suitable for submission to a national reporting system (NRS). Methods and Materials: All events recorded in the combined IRS were evaluated from 2007 through 2010. Incidents were graded for potential severity using the validated French Nuclear Safety Authority (ASN) 5-point scale. These incidents were categorized into 7 groups: (1) human error, (2) software error, (3) hardware error, (4) error in communication between 2 humans, (5) error at the human-software interface, (6) error at the software-hardware interface, and (7) error at the human-hardware interface. Results: Between the 2 systems, 4407 incidents were reported. Of these events, 1507 (34%) were considered to have the potential for clinical consequences. Of these 1507 events, 149 (10%) were rated as having a potential severity of ≥2. Of these 149 events, the committee determined that 79 (53%) of these events would be submittable to a NRS of which the majority was related to human error or to the human-software interface. Conclusions: A significant number of incidents were identified in this analysis. The majority of events in this study were related to human error and to the human-software interface, further supporting the need for a NRS to facilitate field-wide learning and system improvement.

  12. Faculty of Radiation Oncology 2014 Workforce Census: a comparison of New Zealand and Australian responses.

    Science.gov (United States)

    James, Melissa; Munro, Philip M; Leung, John

    2015-04-17

    This paper outlines the key results of the Royal Australian and New Zealand College of Radiologists (RANZCR) Faculty of Radiation Oncology (FRO) 2014 workforce census, and compares the results of New Zealand and Australian responses in order to identify similarities and differences in workforce characteristics. The workforce census was conducted online in mid-2014. The census was distributed to all radiation oncologists (Fellows, life members, educational affiliates, retired) and radiation oncology trainees on the RANZCR membership database. Six weekly reminders were sent to non-respondents and all responses were aggregated for analysis. This paper addresses only consultant radiation oncologist responses. The combined response rate for New Zealand radiation oncologists was 85.7% (compared with 76% from Australian respondents). The census found that the demographic characteristics of New Zealand and Australian radiation oncologists are similar. Points of difference include (i) the role of educational affiliates in New Zealand, (ii) New Zealand radiation oncologists reporting higher hours spent at work, (iii) New Zealand radiation oncologists spending a higher proportion of time on clinical duties, (iv) A lower proportion of New Zealand radiation oncologists with higher degrees, and (v) private/ public workplace mix. A comparison by country would suggest that there are many similarities, but also some important differences that may affect workforce issues in New Zealand. Separate datasets are useful for RANZCR to better inform members, governments and other key stakeholders in each country. Separate datasets also provide a basis for comparison with future surveys to facilitate the monitoring of trends.

  13. Department of Radiation and Environmental Biology - Overview

    International Nuclear Information System (INIS)

    Cebulska-Wasilewska, A.

    2002-01-01

    Full text: The year 2001 started for us with new demanding tasks connected with participation in a new research project performed in collaboration with a excellent teams from six countries under the 5 th EU the Quality of Life Programme. The aim of the project EXPAH is to propose methods of molecular epidemiology for the risk assessment of exposure to polycyclic aromatic hydrocarbons in the air. The exploration of cause-effect relationships for carcinogenic agents will be based on the study of exogenous and endogenous influence on DNA damage in exposed population, and will determine the relationship between biomarkers of exposure, effects and susceptibility in the exposed populations. Analysis of this damage is carried out using highly specialising multidisciplinary techniques brought together by seven laboratories specialised in chemical, biochemical and biological techniques for analysing DNA damage and repair, together with access to populations exposed to environmental pollution and experience in collecting samples. In the year 2001 all the members of the department put much effort in co-organizing 12. Meeting of the Maria Sklodowska-Curie Polish Radiation Research Society. The Meeting was held in the September in Cracow and rewarded hard work of everybody with many applauding comments for the high scientific and organization level. Our parallel activities were concentrated on arrangement and preparation of the forthcoming Course on Human Monitoring for Genetic Effects proposed to us by the Alexander Hollaender Committee of the International Environmental Mutagenesis Society. The Alexander Hollaender ''HUMOGEF'' Course will concentrate on the commonly measured biomarkers (chromosome aberrations; micronuclei; DNA damage), but others (p53 protein levels; metabolic genotypes) will also be addressed. Scientists of international standing from the fields of toxicology, molecular biology, cytogenetics, mutation, and epidemiology, will present and discuss the state

  14. Making the right software choice for clinically used equipment in radiation oncology

    International Nuclear Information System (INIS)

    Vorwerk, Hilke; Zink, Klemens; Wagner, Daniela Michaela; Engenhart-Cabillic, Rita

    2014-01-01

    The customer of a new system for clinical use in radiation oncology must consider many options in order to find the optimal combination of software tools. Many commercial systems are available and each system has a large number of technical features. However an appraisal of the technical capabilities, especially the options for clinical implementations, is hardly assessable at first view. The intention of this article was to generate an assessment of the necessary functionalities for high precision radiotherapy and their integration in ROKIS (Radiation oncology clinic information system) for future customers, especially with regard to clinical applicability. Therefore we analysed the clinically required software functionalities and divided them into three categories: minimal, enhanced and optimal requirements for high conformal radiation treatment

  15. Outbreaks caused by vancomycin-resistant Enterococcus faecium in hematology and oncology departments: A systematic review

    Directory of Open Access Journals (Sweden)

    Nikos Ulrich

    2017-12-01

    Conclusion: A rational use of antibiotics in hematology and oncology units is recommended in order to reduce selection pressure on resistant pathogens such as VRE. In addition the importance of hand hygiene should be stressed to all staff whenever possible.

  16. Pelvic Normal Tissue Contouring Guidelines for Radiation Therapy: A Radiation Therapy Oncology Group Consensus Panel Atlas

    Energy Technology Data Exchange (ETDEWEB)

    Gay, Hiram A., E-mail: hgay@radonc.wustl.edu [Washington University School of Medicine, St Louis, MO (United States); Barthold, H. Joseph [Commonwealth Hematology and Oncology, Weymouth, MA (United States); Beth Israel Deaconess Medical Center, Boston, MA (Israel); O' Meara, Elizabeth [Radiation Therapy Oncology Group, Philadelphia, PA (United States); Bosch, Walter R. [Washington University School of Medicine, St Louis, MO (United States); El Naqa, Issam [Department of Radiation Oncology, McGill University Health Center, Montreal, Quebec (Canada); Al-Lozi, Rawan [Washington University School of Medicine, St Louis, MO (United States); Rosenthal, Seth A. [Radiation Oncology Centers, Radiological Associates of Sacramento, Sacramento, CA (United States); Lawton, Colleen [Department of Radiation Oncology, Medical College of Wisconsin, Milwaukee, WI (United States); Lee, W. Robert [Department of Radiation Oncology, Duke University Medical Center, Durham, NC (United States); Sandler, Howard [Cedars-Sinai Medical Center, Los Angeles, CA (United States); Zietman, Anthony [Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, MA (United States); Myerson, Robert [Washington University School of Medicine, St Louis, MO (United States); Dawson, Laura A. [Department of Radiation Oncology, Princess Margaret Hospital, University of Toronto, Toronto, Ontario (Canada); Willett, Christopher [Department of Radiation Oncology, Duke University Medical Center, Durham, NC (United States); Kachnic, Lisa A. [Department of Radiation Oncology, Boston Medical Center, Boston University School of Medicine, Boston, MA (United States); Jhingran, Anuja [Department of Radiation Oncology, University of Texas MD Anderson Cancer Center, Houston, TX (United States); Portelance, Lorraine [University of Miami, Miami, FL (United States); Ryu, Janice [Radiation Oncology Centers, Radiological Associates of Sacramento, Sacramento, CA (United States); and others

    2012-07-01

    Purpose: To define a male and female pelvic normal tissue contouring atlas for Radiation Therapy Oncology Group (RTOG) trials. Methods and Materials: One male pelvis computed tomography (CT) data set and one female pelvis CT data set were shared via the Image-Guided Therapy QA Center. A total of 16 radiation oncologists participated. The following organs at risk were contoured in both CT sets: anus, anorectum, rectum (gastrointestinal and genitourinary definitions), bowel NOS (not otherwise specified), small bowel, large bowel, and proximal femurs. The following were contoured in the male set only: bladder, prostate, seminal vesicles, and penile bulb. The following were contoured in the female set only: uterus, cervix, and ovaries. A computer program used the binomial distribution to generate 95% group consensus contours. These contours and definitions were then reviewed by the group and modified. Results: The panel achieved consensus definitions for pelvic normal tissue contouring in RTOG trials with these standardized names: Rectum, AnoRectum, SmallBowel, Colon, BowelBag, Bladder, UteroCervix, Adnexa{sub R}, Adnexa{sub L}, Prostate, SeminalVesc, PenileBulb, Femur{sub R}, and Femur{sub L}. Two additional normal structures whose purpose is to serve as targets in anal and rectal cancer were defined: AnoRectumSig and Mesorectum. Detailed target volume contouring guidelines and images are discussed. Conclusions: Consensus guidelines for pelvic normal tissue contouring were reached and are available as a CT image atlas on the RTOG Web site. This will allow uniformity in defining normal tissues for clinical trials delivering pelvic radiation and will facilitate future normal tissue complication research.

  17. The internet radiation oncology journal club - a multi-institutional collaborative education project

    International Nuclear Information System (INIS)

    Goldsmith, Brian J.; Donaldson, Sarah S.; Mendenhall, William M.; Recht, Abram; Hoppe, Richard T.; Grigsby, Perry W.; Turrisi, Andrew T.; Tepper, Joel E.; Roach, Mack; Larson, David A.; Withers, H. Rodney; Purdy, James A.

    1997-01-01

    Purpose/Objective: The high volume of literature publication in radiation oncology poses a substantial selection and reading challenge. Busy health care providers may, from time to time, fail to identify and read important papers, resulting in delays in improvement of practice standards. Residency training programs have historically used journal clubs as a solution to this education challenge. In June 1995, radiation oncologists and scientists from nine institutions began the Internet Radiation Oncology Journal Club (IROJC) - a pilot project created to improve radiation oncology education worldwide by identifying noteworthy literature and stimulating an internet-based forum for literature discussion. Materials and Methods: The IROJC is a free-of-charge, moderated e-mailing list hosted by BIOSCI - a set of electronic communication forums used by biological scientists worldwide. Eleven radiation oncologists and scientists with internationally-recognized subspecialty expertise serve as IROJC editors. Each month, editors select noteworthy contemporary literature for inclusion. Selected references, often accompanied by editorial comments, are transmitted over the internet to IROJC readers. Readers request subscription by sending an e-mail message to biosci-server at net.bio.net, with 'subscribe radoncjc' in the body of the message. A website (www.bio.net/hypermail/RADIATION-ONCOLOGY), which includes an archive of back issues, is also available. Results: By February 1997, the IROJC's email-format enrollment numbered more than 670 readers from over 14 countries, its website was browsed by an average of 25 unique readers per week, and both figures were increasing steadily. An exciting online dialogue of literature- and practice-based comments and questions had emerged with increasing readership participation. Conclusion: Our pilot experience with the IROJC project has been promising. The observed increase in enrollment, website use, and readership discourse suggests

  18. The psychosocial work environment among physicians employed at Danish oncology departments in 2009. A nationwide cross-sectional study

    DEFF Research Database (Denmark)

    Andreassen, Christian Nicolaj; Eriksen, Jesper Grau

    2013-01-01

    Working as a physician at an oncology department has some distinctive characteristics that may lead to a stressful work environment. The present study was conducted to provide a nationwide description of the work conditions of all oncologists in Denmark. By comparing the results of the present...... study with those of a similar study carried out in 2006, the aim was furthermore to elucidate changes in the psychosocial work environment over time....

  19. Methodology in use for the assessment of carcinogenic risk. II. Radiation. Oncology overview

    International Nuclear Information System (INIS)

    1983-04-01

    Oncology Overviews are a service of the International Cancer Research Data Bank (ICRDB) Program of the National Cancer Institute, intended to facilitate and promote the exchange of information between cancer scientists by keeping them aware of literature related to their research being published by other laboratories throughout the world. Each Oncology Overview represents a survey of the literature associated with a selected area of cancer research. It contains abstracts of articles which have been selected and organized by researchers associated with the field. Contents: Assessment of carcinogenic risk from environmental and occupational exposures to ionizing radiation; Assessment of carcinogenic risk from exposure to ionizing radiation used for medical diagnosis or treatment; Assessment of carcinogenic risk from exposure to ionizing radiation following nuclear bomb explosions; Comparison of risk from radiation sources with risk from nonradiation sources; Experimental studies to assess risk of carcinogenesis following exposure to ionizing radiation; Theoretical aspects of dose-response relationships in the assessment of carcinogenic risk from exposure to ionizing radiation; Public policy and standards for acceptable risk from exposure to ionizing radiation; General reviews on the assessment of risk from exposure to ionizing radiation

  20. Radiation Protection and Civil defence Department

    International Nuclear Information System (INIS)

    Gomaa, M.A.; Elshinawy, R.M.K.; Abdelfattah, A.T.

    1991-01-01

    This conference involves subjects of radiation protection, programming of civil defence, on the implementation of 1990 ICRP recommendation, thermoluminescence properties of bone equivalent calcium phosphate ceramics, potassium body burdens in occupational users of egyptian nuclear research centre, transport of radionuclides in fresh water stream, water treatment process for nuclear reactor, research activities related to internal contamination and bioassay and experience and environmental radiation monitoring in inshass. it contains of figures and tables

  1. The efficacy and usefulness of problem based learning in undergraduate medical school education of radiation oncology

    International Nuclear Information System (INIS)

    Uchino, Minako; Itazawa, Tomoko; Someya, Masanori; Nakamura, Satoaki

    2007-01-01

    The Japanese Association for Therapeutic Radiation Oncology (JASTRO) holds a seminar for medical students every summer, which has developed into a joint program with a session addressing radiation treatment planning. To clarify this topic for medical students, we have incorporated Problem Based Learning skills into the session. Not only has the students' comprehension improved but the instructors have also found this teaching experience valuable and productive in advancing their own clinical skills. Our experience suggests that the application of this Problem Based Learning session for radiation treatment planning in undergraduate medical school education has proven to be effective. (author)

  2. Data management, documentation and analysis systems in radiation oncology: a multi-institutional survey

    International Nuclear Information System (INIS)

    Kessel, Kerstin A.; Combs, Stephanie E.

    2015-01-01

    Recently, information availability has become more elaborate and widespread, and treatment decisions are based on a multitude of factors. Gathering relevant data, also referred to as Big Data, is therefore critical for reaching the best patient care, and enhancing interdisciplinary and clinical research. Combining patient data from all involved systems is essential to prepare unstructured data for analyses. This demands special coordination in data management. Our study aims to characterize current developments in German-speaking hospital departments and practices. We successfully conducted the survey with the members of the Deutsche Gesellschaft für Radioonkologie (DEGRO). A questionnaire was developed consisting of 17 questions related to data management, documentation and clinical trial analyses, reflecting the clinical topics such as basic patient information, imaging, follow-up information as well as connection of documentation tools with radiooncological treatment planning machines. A total of 44 institutions completed the online survey (University hospitals n = 17, hospitals n = 13, practices/institutes n = 14). University hospitals, community hospitals and private practices are equally equipped concerning IT infrastructure for clinical use. However, private practices have a low interest in research work. All respondents stated the biggest obstacles about introducing a documentation system into their unit lie in funding and support of the central IT departments. Only 27 % (12/44) of responsible persons are specialists for documentation and data management. Our study gives an understanding of the challenges and solutions we need to be looking at for medical data storage. In the future, inter-departmental cross-links will enable the radiation oncology community to generate large-scale analyses. The online version of this article (doi:10.1186/s13014-015-0543-0) contains supplementary material, which is available to authorized users

  3. Radiation oncology - Linking technology and biology in the treatment of cancer

    International Nuclear Information System (INIS)

    Coleman, C. Norman

    2002-01-01

    Technical advances in radiation oncology including CT-simulation, 3D-conformal and intensity-modulated radiation therapy (IMRT) delivery techniques, and brachytherapy have allowed greater treatment precision and dose escalation. The ability to intensify treatment requires the identification of the critical targets within the treatment field, recognizing the unique biology of tumor, stroma and normal tissue. Precision is technology based while accuracy is biologically based. Therefore, the intensity of IMRT will undoubtedly mean an increase in both irradiation dose and the use of biological agents, the latter considered in the broadest sense. Radiation oncology has the potential and the opportunity to provide major contributions to the linkage between molecular and functional imaging, molecular profiling and novel therapeutics for the emerging molecular targets for cancer treatment. This process of 'credentialing' of molecular targets will require multi disciplinary imaging teams, clinicians and basic scientists. Future advances will depend on the appropriate integration of biology into the training of residents, continuing post graduate education, participation in innovative clinical research and commitment to the support of basic research as an essential component of the practice of radiation oncology

  4. An evaluation of a paediatric radiation oncology teaching programme incorporating a SCORPIO teaching model

    International Nuclear Information System (INIS)

    Ahern, Verity

    2011-01-01

    Full text: Many radiation oncology registrars have no exposure to paedi atrics during their training, To address this, the Paediatric Special Interest Group of the Royal Australian and New Zealand College of Radiologists has convened a biennial teaching course since 1997. The 2009 course incorpo rated the use of a Structured, Clinical, Objective-Referenced, Problem orientated, Integrated and Organized (SCORPIO) teaching model for small group tutorials. This study evaluates whether the paediatric radiation oncol ogy curriculum can be adapted to the SCORPIO teaching model and to evaluate the revised course from the registrars' perspective. Methods: Teaching and learning resources included a pre-course reading list, a lecture series programme and a SCORPIO workshop. Three evaluation instruments were developed: an overall Course Evaluation Survey for all participants, a SCORPIO Workshop Survey for registrars and a Teacher's SCORPIO Workshop Survey. Results: Forty-five radiation oncology registrars, 14 radiation therapists and five paediatric oncology registrars attended. Seventy-three per cent (47/64) of all participants completed the Course Evaluation Survey and 95% (38/40) of registrars completed the SCORPIO Workshop Survey. All teachers com pleted the Teacher's SCORPIO Survey (10/10). The overall educational expe rience was rated as good or excellent by 93% (43/47) of respondents. Ratings of satisfaction with lecture sessions were predominantly good or excellent. Registrars gave the SCORPIO workshop high ratings on each of 10 aspects of quality, with 82% allocating an excellent rating overall for the SCORPIO activity. Both registrars and teachers recommended more time for the SCORPIO stations. Conclusions: The 2009 course met the educational needs of the radiation oncology registrars and the SCORPIO workshop was a highly valued educa tional component.

  5. SU-E-T-524: Web-Based Radiation Oncology Incident Reporting and Learning System (ROIRLS)

    International Nuclear Information System (INIS)

    Kapoor, R; Palta, J; Hagan, M; Grover, S; Malik, G

    2014-01-01

    Purpose: Describe a Web-based Radiation Oncology Incident Reporting and Learning system that has the potential to improve quality of care for radiation therapy patients. This system is an important facet of continuing effort by our community to maintain and improve safety of radiotherapy.Material and Methods: The VA National Radiation Oncology Program office has embarked on a program to electronically collect adverse events and near miss data of radiation treatment of over 25,000 veterans treated with radiotherapy annually. Software used for this program is deployed on the VAs intranet as a Website. All data entry forms (adverse event or near miss reports, work product reports) utilize standard causal, RT process step taxonomies and data dictionaries defined in AAPM and ASTRO reports on error reporting (AAPM Work Group Report on Prevention of Errors and ASTROs safety is no accident report). All reported incidents are investigated by the radiation oncology domain experts. This system encompasses the entire feedback loop of reporting an incident, analyzing it for salient details, and developing interventions to prevent it from happening again. The operational workflow is similar to that of the Aviation Safety Reporting System. This system is also synergistic with ROSIS and SAFRON. Results: The ROIRLS facilitates the collection of data that help in tracking adverse events and near misses and develop new interventions to prevent such incidents. The ROIRLS electronic infrastructure is fully integrated with each registered facility profile data thus minimizing key strokes and multiple entries by the event reporters. Conclusions: OIRLS is expected to improve the quality and safety of a broad spectrum of radiation therapy patients treated in the VA and fulfills our goal of Effecting Quality While Treating Safely The Radiation Oncology Incident Reporting and Learning System software used for this program has been developed, conceptualized and maintained by TSG Innovations

  6. SU-E-T-524: Web-Based Radiation Oncology Incident Reporting and Learning System (ROIRLS)

    Energy Technology Data Exchange (ETDEWEB)

    Kapoor, R; Palta, J; Hagan, M [Virginia Commonwealth University, Richmond, VA (United States); National Radiation Oncology Program (10P4H), Richmond, VA (United States); Grover, S; Malik, G [TSG Innovations Inc., Richmond, VA (United States)

    2014-06-01

    Purpose: Describe a Web-based Radiation Oncology Incident Reporting and Learning system that has the potential to improve quality of care for radiation therapy patients. This system is an important facet of continuing effort by our community to maintain and improve safety of radiotherapy.Material and Methods: The VA National Radiation Oncology Program office has embarked on a program to electronically collect adverse events and near miss data of radiation treatment of over 25,000 veterans treated with radiotherapy annually. Software used for this program is deployed on the VAs intranet as a Website. All data entry forms (adverse event or near miss reports, work product reports) utilize standard causal, RT process step taxonomies and data dictionaries defined in AAPM and ASTRO reports on error reporting (AAPM Work Group Report on Prevention of Errors and ASTROs safety is no accident report). All reported incidents are investigated by the radiation oncology domain experts. This system encompasses the entire feedback loop of reporting an incident, analyzing it for salient details, and developing interventions to prevent it from happening again. The operational workflow is similar to that of the Aviation Safety Reporting System. This system is also synergistic with ROSIS and SAFRON. Results: The ROIRLS facilitates the collection of data that help in tracking adverse events and near misses and develop new interventions to prevent such incidents. The ROIRLS electronic infrastructure is fully integrated with each registered facility profile data thus minimizing key strokes and multiple entries by the event reporters. Conclusions: OIRLS is expected to improve the quality and safety of a broad spectrum of radiation therapy patients treated in the VA and fulfills our goal of Effecting Quality While Treating Safely The Radiation Oncology Incident Reporting and Learning System software used for this program has been developed, conceptualized and maintained by TSG Innovations

  7. Measuring safety culture: Application of the Hospital Survey on Patient Safety Culture to radiation therapy departments worldwide.

    Science.gov (United States)

    Leonard, Sarah; O'Donovan, Anita

    Minimizing errors and improving patient safety has gained prominence worldwide in high-risk disciplines such as radiation therapy. Patient safety culture has been identified as an important factor in reducing the incidence of adverse events and improving patient safety in the health care setting. The aim of distributing the Hospital Survey on Patient Safety Culture (HSPSC) to radiation therapy departments worldwide was to assess the current status of safety culture, identify areas for improvement and areas that excel, examine factors that influence safety culture, and raise staff awareness. The safety culture in radiation therapy departments worldwide was evaluated by distributing the HSPSC. A total of 266 participants were recruited from radiation therapy departments and included radiation oncologists, radiation therapists, physicists, and dosimetrists. The positive percent scores for the 12 dimensions of the HSPSC varied from 50% to 79%. The highest composite score among the 12 dimensions was teamwork within units; the lowest composite score was handoffs and transitions. The results indicated that health care professionals in radiation therapy departments felt positively toward patient safety. The HSPSC was successfully applied to radiation therapy departments and provided valuable insight into areas of potential improvement such as teamwork across units, staffing, and handoffs and transitions. Managers and policy makers in radiation therapy may use this assessment tool for focused improvement efforts toward patient safety culture. Copyright © 2017 American Society for Radiation Oncology. Published by Elsevier Inc. All rights reserved.

  8. Trial Watch: Immunotherapy plus radiation therapy for oncological indications.

    Science.gov (United States)

    Vacchelli, Erika; Bloy, Norma; Aranda, Fernando; Buqué, Aitziber; Cremer, Isabelle; Demaria, Sandra; Eggermont, Alexander; Formenti, Silvia Chiara; Fridman, Wolf Hervé; Fucikova, Jitka; Galon, Jérôme; Spisek, Radek; Tartour, Eric; Zitvogel, Laurence; Kroemer, Guido; Galluzzi, Lorenzo

    2016-01-01

    Malignant cells succumbing to some forms of radiation therapy are particularly immunogenic and hence can initiate a therapeutically relevant adaptive immune response. This reflects the intrinsic antigenicity of malignant cells (which often synthesize a high number of potentially reactive neo-antigens) coupled with the ability of radiation therapy to boost the adjuvanticity of cell death as it stimulates the release of endogenous adjuvants from dying cells. Thus, radiation therapy has been intensively investigated for its capacity to improve the therapeutic profile of several anticancer immunotherapies, including (but not limited to) checkpoint blockers, anticancer vaccines, oncolytic viruses, Toll-like receptor (TLR) agonists, cytokines, and several small molecules with immunostimulatory effects. Here, we summarize recent preclinical and clinical advances in this field of investigation.

  9. Quality Control and Quality Assurance of Radiation Oncology

    International Nuclear Information System (INIS)

    Abaza, A.

    2016-01-01

    Radiotherapy (RT) has played important roles in cancer treatment for more than one century. The development of RT techniques allows high-dose irradiation to tumors while reducing the radiation doses delivered to surrounding normal tissues. However, RT is a complex process and involves understanding of the principles of medical physics, radiobiology, radiation safety, dosimetry, radiation treatment planning, simulation and interaction of radiation with other treatment modalities. Each step in the integrated process of RT needs quality control and quality assurance (QA) to prevent errors and to ensure that patients will receive the prescribed treatment correctly. The aim of this study is to help the radio therapists in identifying a system for QA that balances patient safety and quality with available resources. Recent advances in RT focus on the need for a systematic RT QA program that balances patient safety and quality with available resources. It is necessary to develop more formal error mitigation and process analysis methods, such as failure mode and effect analysis (FMEA), to focus available QA resources optimally on the process components. External audit programs are also effective. Additionally, Clinical trial QA has a significant role in enhancing the quality of care. The International Atomic Energy Agency (IAEA) has operated both an on-site and off-site postal dosimetry audit to improve practice and to assure the dose from RT equipment. Both postal dosimetry audit and clinical trial RTQA, especially for advanced technologies, in collaboration with global networks, will serve to enhance patient safety and quality of care

  10. Hypoxia as a Biomarker and for Personalized Radiation Oncology

    DEFF Research Database (Denmark)

    Vordermark, Dirk; Horsman, Michael R

    2016-01-01

    Tumor hypoxia is a clinically relevant cause of radiation resistance. Direct measurements of tumor oxygenation have been performed predominantly with the Eppendorf histograph and these have defined the reduced prognosis after radiotherapy in poorly oxygenated tumors, especially head-and-neck canc...

  11. The Radiation Oncology Job Market: The Economics and Policy of Workforce Regulation

    Energy Technology Data Exchange (ETDEWEB)

    Falit, Benjamin P., E-mail: bfalit2@allianceoncology.com [Pacific Cancer Institute, Wailuku, Hawaii (United States); Pan, Hubert Y.; Smith, Benjamin D. [MD Anderson Cancer Center, Houston, Texas (United States); Alexander, Brian M. [Dana Farber Cancer Institute, Boston, Massachusetts (United States); Zietman, Anthony L. [Massachusetts General Hospital, Boston, Massachusetts (United States)

    2016-11-01

    Examinations of the US radiation oncology workforce offer inconsistent conclusions, but recent data raise significant concerns about an oversupply of physicians. Despite these concerns, residency slots continue to expand at an unprecedented pace. Employed radiation oncologists and professional corporations with weak contracts or loose ties to hospital administrators would be expected to suffer the greatest harm from an oversupply. The reduced cost of labor, however, would be expected to increase profitability for equipment owners, technology vendors, and entrenched professional groups. Policymakers must recognize that the number of practicing radiation oncologists is a poor surrogate for clinical capacity. There is likely to be significant opportunity to augment capacity without increasing the number of radiation oncologists by improving clinic efficiency and offering targeted incentives for geographic redistribution. Payment policy changes significantly threaten radiation oncologists' income, which may encourage physicians to care for greater patient loads, thereby obviating more personnel. Furthermore, the implementation of alternative payment models such as Medicare's Oncology Care Model threatens to decrease both the utilization and price of radiation therapy by turning referring providers into cost-conscious consumers. Medicare funds the vast majority of graduate medical education, but the extent to which the expansion in radiation oncology residency slots has been externally funded is unclear. Excess physician capacity carries a significant risk of harm to society by suboptimally allocating intellectual resources and creating comparative shortages in other, more needed disciplines. There are practical concerns associated with a market-based solution in which medical students self-regulate according to job availability, but antitrust law would likely forbid collaborative self-regulation that purports to restrict supply. Because Congress is unlikely

  12. The Radiation Oncology Job Market: The Economics and Policy of Workforce Regulation

    International Nuclear Information System (INIS)

    Falit, Benjamin P.; Pan, Hubert Y.; Smith, Benjamin D.; Alexander, Brian M.; Zietman, Anthony L.

    2016-01-01

    Examinations of the US radiation oncology workforce offer inconsistent conclusions, but recent data raise significant concerns about an oversupply of physicians. Despite these concerns, residency slots continue to expand at an unprecedented pace. Employed radiation oncologists and professional corporations with weak contracts or loose ties to hospital administrators would be expected to suffer the greatest harm from an oversupply. The reduced cost of labor, however, would be expected to increase profitability for equipment owners, technology vendors, and entrenched professional groups. Policymakers must recognize that the number of practicing radiation oncologists is a poor surrogate for clinical capacity. There is likely to be significant opportunity to augment capacity without increasing the number of radiation oncologists by improving clinic efficiency and offering targeted incentives for geographic redistribution. Payment policy changes significantly threaten radiation oncologists' income, which may encourage physicians to care for greater patient loads, thereby obviating more personnel. Furthermore, the implementation of alternative payment models such as Medicare's Oncology Care Model threatens to decrease both the utilization and price of radiation therapy by turning referring providers into cost-conscious consumers. Medicare funds the vast majority of graduate medical education, but the extent to which the expansion in radiation oncology residency slots has been externally funded is unclear. Excess physician capacity carries a significant risk of harm to society by suboptimally allocating intellectual resources and creating comparative shortages in other, more needed disciplines. There are practical concerns associated with a market-based solution in which medical students self-regulate according to job availability, but antitrust law would likely forbid collaborative self-regulation that purports to restrict supply. Because Congress is unlikely to create

  13. Growth of the Female Professional in the Radiation Safety Department

    International Nuclear Information System (INIS)

    Yoon, J.

    2015-01-01

    Currently in Korea’s Nuclear Power Plants (KHNP), the number of the female staffs has been increased as planned construction of new NPPs. However the role of the female staffs in NPPs is still limited as before. Because there is the prejudice which the operating and the maintenance work is unsuitable for female owing to the risk of the radiation exposure and the physical weakness. So female staffs mostly belong to the supporting departments. In particular, the proportion of the female staffs is significantly higher in the radiation safety department among those. The ratio is 15% and is twice higher, whereas the total percentage of the female workers in KHNP is 8%. In the past, the women staffs in the radiation safety department were usually charge of the non-technical duties like the radiation exposure dose management and the education for radiation workers. Although the ratio of the women about that is still higher, nowadays, the role of the female workers tends to diversify to technical supports like the radiation protection and the radioactive waste management while increased the proportion of female employees. This trend is expected to continue for many years to come. Thus, in Korea’s NPPs, it is expected that many women will demonstrate their professionalism especially in the radiation safety department than any other departments. This presentation contains the detailed duty and trend about female staffs in the radiation safety department in Korea’s NPPs. (author)

  14. Factors Affecting Gender-based Experiences for Residents in Radiation Oncology

    International Nuclear Information System (INIS)

    Barry, Parul N.; Miller, Karen H.; Ziegler, Craig; Hertz, Rosanna; Hanna, Nevine; Dragun, Anthony E.

    2016-01-01

    Purpose: Although women constitute approximately half of medical school graduates, an uneven gender distribution exists among many specialties, including radiation oncology, where women fill only one third of residency positions. Although multiple social and societal factors have been theorized, a structured review of radiation oncology resident experiences has yet to be performed. Methods and Materials: An anonymous and voluntary survey was sent to 611 radiation oncology residents practicing in the United States. Residents were asked about their gender-based experiences in terms of mentorship, their professional and learning environment, and their partnerships and personal life. Results: A total of 203 participants submitted completed survey responses. Fifty-seven percent of respondents were men, and 43% were women, with a mean age of 31 years (standard deviation=3.7 years). Although residents in general value having a mentor, female residents prefer mentors of the same gender (P<.001), and noted having more difficulty finding a mentor (P=.042). Women were more likely to say that they have observed preferential treatment based on gender (P≤.001), and they were more likely to perceive gender-specific biases or obstacles in their professional and learning environment (P<.001). Women selected residency programs based on gender ratios (P<.001), and female residents preferred to see equal numbers of male and female faculty (P<.001). Women were also more likely to perceive work-related strain than their male counterparts (P<.001). Conclusions: Differences in experiences for male and female radiation oncology residents exist with regard to mentorship and in their professional and learning environment.

  15. Clinical Implications of TiGRT Algorithm for External Audit in Radiation Oncology

    OpenAIRE

    Daryoush Shahbazi-Gahrouei; Mohsen Saeb; Shahram Monadi; Iraj Jabbari

    2017-01-01

    Background: Performing audits play an important role in quality assurance program in radiation oncology. Among different algorithms, TiGRT is one of the common application software for dose calculation. This study aimed to clinical implications of TiGRT algorithm to measure dose and compared to calculated dose delivered to the patients for a variety of cases, with and without the presence of inhomogeneities and beam modifiers. Materials and Methods: Nonhomogeneous phantom as quality dose veri...

  16. Factors Affecting Gender-based Experiences for Residents in Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Barry, Parul N., E-mail: pnbarr01@louisville.edu [Department of Radiation Oncology, University of Louisville, School of Medicine, Louisville, Kentucky (United States); Miller, Karen H.; Ziegler, Craig [Department of Graduate Medical Education, University of Louisville, School of Medicine, Louisville, Kentucky (United States); Hertz, Rosanna [Departments of Women' s and Gender Studies and Sociology, Wellesley College, Wellesley, Massachusetts (United States); Hanna, Nevine [Department of Radiation Oncology, University of Utah, School of Medicine, Salt Lake City, Utah (United States); Dragun, Anthony E. [Department of Radiation Oncology, University of Louisville, School of Medicine, Louisville, Kentucky (United States)

    2016-07-01

    Purpose: Although women constitute approximately half of medical school graduates, an uneven gender distribution exists among many specialties, including radiation oncology, where women fill only one third of residency positions. Although multiple social and societal factors have been theorized, a structured review of radiation oncology resident experiences has yet to be performed. Methods and Materials: An anonymous and voluntary survey was sent to 611 radiation oncology residents practicing in the United States. Residents were asked about their gender-based experiences in terms of mentorship, their professional and learning environment, and their partnerships and personal life. Results: A total of 203 participants submitted completed survey responses. Fifty-seven percent of respondents were men, and 43% were women, with a mean age of 31 years (standard deviation=3.7 years). Although residents in general value having a mentor, female residents prefer mentors of the same gender (P<.001), and noted having more difficulty finding a mentor (P=.042). Women were more likely to say that they have observed preferential treatment based on gender (P≤.001), and they were more likely to perceive gender-specific biases or obstacles in their professional and learning environment (P<.001). Women selected residency programs based on gender ratios (P<.001), and female residents preferred to see equal numbers of male and female faculty (P<.001). Women were also more likely to perceive work-related strain than their male counterparts (P<.001). Conclusions: Differences in experiences for male and female radiation oncology residents exist with regard to mentorship and in their professional and learning environment.

  17. The state of survivorship care in radiation oncology: Results from a nationally distributed survey.

    Science.gov (United States)

    Frick, Melissa A; Rosenthal, Seth A; Vapiwala, Neha; Monzon, Brian T; Berman, Abigail T

    2018-04-18

    Survivorship care has become an increasingly critical component of oncologic care as well as a quality practice and reimbursement metric. To the authors' knowledge, the current climate of survivorship medicine in radiation oncology has not been investigated fully. An institutional review board-approved, Internet-based survey examining practices and preparedness in survivorship care was distributed to radiation oncology practices participating in the American College of Radiology Radiation Oncology Practice Accreditation program between November 2016 and January 2017. A total of 78 surveys were completed. Among these, 2 were nonphysicians, resulting in 76 evaluable responses. Radiation oncologists (ROs) frequently reported that they are the primary provider in the evaluation of late toxicities and the recurrence of primary cancer. Although approximately 68% of ROs frequently discuss plans for future care with survivors, few provide a written survivorship care plan to their patients (18%) or the patients' primary care providers (24%). Patient prognosis, disease site, and reimbursement factors often influence the provision of survivorship care. Although ROs report that several platforms offer training in survivorship medicine, the quality of these resources is variable and extensive instruction is rare. Fewer than one-half of ROs believe they are expertly trained in survivorship care. ROs play an active role within the multidisciplinary team in the cancer-related follow-up care of survivors. Investigation of barriers to the provision of survivorship care and optimization of service delivery should be pursued further. The development of high-quality, easily accessible educational programming is needed so that ROs can participate more effectively in the care of cancer survivors. Cancer 2018. © 2018 American Cancer Society. © 2018 American Cancer Society.

  18. Prospective evaluation through questionnaires of the emotional status of cancer patients in the waiting rooms of a department of oncology

    Directory of Open Access Journals (Sweden)

    Roberta Resega

    2016-07-01

    Full Text Available Objective: The aim of this study is to better identify the prevailing emotions and feelings of cancer patients during their stay in waiting rooms in a department of oncology. Methods: In July 2014, patients in the waiting rooms of our Department of Oncology were asked to fill out dedicated questionnaires. Patients had to choose sentences that best described their feelings, thoughts and experiences; this part was differentiated according to the waiting rooms (Consultation Rooms versus Day Hospital. In another section, patients were asked to choose their prevailing primary emotions: joy, fear, sadness, anger, disgust or surprise. Results: Two hundred eighty questionnaires were considered valid for statistical analysis. Regarding feelings, all patients in the Day Hospital and Consultation Rooms stated that they feel anxious (48% and 53%, respectively. By differentiating patients according to the setting, patients in the Day Hospital answered that they will face chemotherapy, thinking that it will be useful to defeat the disease (56%, and patients in Consultation Rooms answered that time in the waiting rooms goes more slowly (65%. Regarding the prevailing emotions experienced by patients, sadness was the most selected, followed by fear and surprise. Conclusions: A prevalent emotional and cognitive state while waiting is anxiety, followed by positive thoughts. Patients presented anxiety and fear independently from the setting of care. We believe that each oncologist should be aware of the degrees of fear and sadness that patients experience during an oncological examination because these emotions can have an impact on communication and understanding.

  19. The situation of radiation oncology training programs and their graduates in 1997

    International Nuclear Information System (INIS)

    Crewson, Philip E.; Sunshine, Jonathan H.; Schepps, Barbara

    1999-01-01

    Purpose: In light of concerns about the job market, the American College of Radiology (ACR) studied the employment situation of 1997 radiation oncology graduates, and the status and plans of radiation oncology training programs. Methods and Materials: In April-May 1997, and in a December follow-up, the ACR surveyed all radiation oncology residency directors about the employment situation of their 1997 residency and fellowship graduates and about their programs. Ninety-four percent of those surveyed responded. We compared findings with surveys from 1995 and 1996. Differences were assessed with p ≤ 0.05 as the test of statistical significance. Results: By six months after graduation, 98% of residency graduates and all fellowship graduates were employed. Program directors reported approximately 95% of graduates had positions that reasonably matched their training and personal employment goals. Programs have reduced beginning residency slots by 22% over the past three years, and further reductions are planned. Many observers were disappointed with fill rates in the 1997 National Match, but by the December follow-up, 96% of beginning-year residency slots were filled. Conclusion: Unemployment continues to be low, and one 'softer' indicator, the job market perceptions of residency program directors, showed improvement

  20. "Assessing the methodological quality of systematic reviews in radiation oncology: A systematic review".

    Science.gov (United States)

    Hasan, Haroon; Muhammed, Taaha; Yu, Jennifer; Taguchi, Kelsi; Samargandi, Osama A; Howard, A Fuchsia; Lo, Andrea C; Olson, Robert; Goddard, Karen

    2017-10-01

    The objective of our study was to evaluate the methodological quality of systematic reviews and meta-analyses in Radiation Oncology. A systematic literature search was conducted for all eligible systematic reviews and meta-analyses in Radiation Oncology from 1966 to 2015. Methodological characteristics were abstracted from all works that satisfied the inclusion criteria and quality was assessed using the critical appraisal tool, AMSTAR. Regression analyses were performed to determine factors associated with a higher score of quality. Following exclusion based on a priori criteria, 410 studies (157 systematic reviews and 253 meta-analyses) satisfied the inclusion criteria. Meta-analyses were found to be of fair to good quality while systematic reviews were found to be of less than fair quality. Factors associated with higher scores of quality in the multivariable analysis were including primary studies consisting of randomized control trials, performing a meta-analysis, and applying a recommended guideline related to establishing a systematic review protocol and/or reporting. Systematic reviews and meta-analyses may introduce a high risk of bias if applied to inform decision-making based on AMSTAR. We recommend that decision-makers in Radiation Oncology scrutinize the methodological quality of systematic reviews and meta-analyses prior to assessing their utility to inform evidence-based medicine and researchers adhere to methodological standards outlined in validated guidelines when embarking on a systematic review. Copyright © 2017 Elsevier Ltd. All rights reserved.

  1. Analysis of the payment rates and classification of services on radiation oncology

    International Nuclear Information System (INIS)

    Shin, K. H.; Shin, H. S.; Pyo, H. R.; Lee, K. C.; Lee, Y. T.; Myoung, H. B.; Yeom, Y. K.

    1997-01-01

    The main purpose of this study is to develop new payment rates for services of radiation oncology, considering costs of treating patients. A survey of forty hospitals has been conducted in order to analyze the costs of treating patients. Before conducting the survey, we evaluated and reclassified the individual service items currently using as payments units on the fee-for-service reimbursement system. This study embodies the analysis of replies received from the twenty four hospitals. The survey contains information about the hospitals' costs of 1995 for the reclassified service items on radiation oncology. After we adjust the hospital costs by the operating rate of medical equipment, we compare the adjusted costs with the current payment rates of individual services. The current payment rates were 5.05-6.58 times lower than the adjusted costs in treatment planning services, 2.22 times lower in block making service, 1.57-2.86 times lower in external beam irradiation services, 3.82-5.01 times lower in intracavitary and interstitial irradiation and 1.12-2.55 times lower in total body irradiation. We could conclude that the current payment system on radiation oncology does not only reflect the costs of treating patients appropriately but also classify the service items correctly. For an example, when the appropriate costs and classification are applied to TBI, the payment rates of TBI should be increased five times more than current level. (author)

  2. International Conference on Advances in Radiation Oncology (ICARO). Book of extended synopses

    International Nuclear Information System (INIS)

    2009-01-01

    The major theme of the ICARO meeting was to review technological advances in radiation oncology and its application in routine clinical practice, especially in mid- and low-income countries. A major goal of the conference was to educate clinicians on the challenges of new technology in terms of assessing cost benefits, staffing, education, and Quality Assurance (QA), as these issues are frequently not properly considered when decisions are made to purchase new technologies. The main objectives of the conference were: - To exchange information on the current advances in the field among leading experts; - To define future challenges and directions in the clinical use of radiotherapy; - To explore the applications of improved imaging tools in treatment planning; - To review the current status of evidence based recommendations for the treatment of common cancers. - To review the current role and future potential of technological and molecular /biological innovations in radiation oncology. This conference is of interest to individuals involved in the application of new technologies in radiation oncology. In particular, the conference attempted to put technological developments into the perspective of the priorities of low and middle-income countries. Each of the 150 papers in this Book of Extended Synopses has been indexed separately

  3. Internal qualification and credentialing of radiation oncology physicists to perform patient special procedures

    Directory of Open Access Journals (Sweden)

    Michael D Mills

    2014-01-01

    Full Text Available In the arena of radiation oncology special procedures, medical physicists are often the focus professionals for implementation and administration of advanced and complex technologies. One of the most vexing and challenging aspects of managing complexity concerns the ongoing internal qualification and credentialing of radiation oncology physicists to perform patient special procedures. To demonstrate ongoing qualification, a physicist must a document initial training and successful completion of competencies to implement and perform this procedure, b demonstrate familiarity with all aspects of the commissioning and quality assurance process, c demonstrate continuing education respecting this procedure, d demonstrate the peer-reviewed completion of a minimum number of patient special procedures during a specified time span, and e demonstrate satisfactory overall progress toward maintenance of specialty board certification. In many respects, this information complement is similar to that required by an accredited residency program in therapy physics. In this investigation, we report on the design of a management tool to qualify staff radiation oncology physicists to deliver patient procedures.

  4. The Evolving Role of Regional Radiation Oncology Societies in Resident Education.

    Science.gov (United States)

    Mattes, Malcolm D

    2015-09-01

    The goal of this study is to develop insight into how a regional radiation oncology organization like the New York Roentgen Society (NYRS) can best assist in the education and development of residents. From April to June 2012, an electronic survey was sent to all 41 post-graduate year 2-4 radiation oncology residents in the New York metropolitan area. Questions were formatted using Likert scales (ranging from 1 to 5), and the Friedman and Wilcoxon signed-rank tests were used to compare the mean ratings of each answer option. Surveys were completed by 34 residents (response rate 83 %). The three highest rated features that residents hope to get out of their membership in the NYRS included "networking" (mean 4.21), "career mentoring" (mean 4.18), and "education" (mean 4.15), all of which were rated significantly higher (p networking, career mentoring, and clinical educational content (particularly as it relates to boards review) from their regional radiation oncology society. These findings may be applicable to similar organizations in other cities, as a guide for future programming.

  5. Establishing a Global Radiation Oncology Collaboration in Education (GRaCE): Objectives and priorities.

    Science.gov (United States)

    Turner, Sandra; Eriksen, Jesper G; Trotter, Theresa; Verfaillie, Christine; Benstead, Kim; Giuliani, Meredith; Poortmans, Philip; Holt, Tanya; Brennan, Sean; Pötter, Richard

    2015-10-01

    Representatives from countries and regions world-wide who have implemented modern competency-based radiation- or clinical oncology curricula for training medical specialists, met to determine the feasibility and value of an ongoing international collaboration. In this forum, educational leaders from the ESTRO School, encompassing many European countries adopting the ESTRO Core Curriculum, and clinician educators from Canada, Denmark, the United Kingdom, Australia and New Zealand considered the training and educational arrangements within their jurisdictions, identifying similarities and challenges between programs. Common areas of educational interest and need were defined, which included development of new competency statements and assessment tools, and the application of the latter. The group concluded that such an international cooperation, which might expand to include others with similar goals, would provide a valuable vehicle to ensure training program currency, through sharing of resources and expertise, and enhance high quality radiation oncology education. Potential projects for the Global Radiation Oncology Collaboration in Education (GRaCE) were agreed upon, as was a strategy designed to maintain momentum. This paper describes the rationale for establishing this collaboration, presents a comparative view of training in the jurisdictions represented, and reports early goals and priorities. Copyright © 2015 Elsevier Ireland Ltd. All rights reserved.

  6. Program director and chief resident perspectives on the educational environment of US radiation oncology programs.

    Science.gov (United States)

    Berriochoa, Camille; Weller, Michael; Berry, Danielle; Reddy, Chandana A; Koyfman, Shlomo; Tendulkar, Rahul

    Our goals were toexamine the educational approachesused at radiation oncology residency programs nationwide andto evaluate program director(PD) and chief resident (CR) perceptions of their educational environment. We distributed a survey regarding curricular structure via email toall identified US radiation oncology residency PDs and CRs. Pearson χ 2 test was used toevaluate whether differences existed between answers provided by the 2 study populations. The survey was disseminated to 200 individuals in 85 US residency programs: 49/85PDs(58%)and 74/115 (64%)CRs responded. More than one-half of PDs and CRs report that attending physicians discussed management, reviewed contours, and conducted mock oral board examinations with the residents. At nearly 50% of programs, the majority of teaching conferences use a lecture-based approach, whereas only 20% reported predominant utilization of the Socratic method. However, both PDs (63%) and CRs (49%) reported that Socratic teaching is more effective than didactic lectures (16% and 20%, respectively), with the remainder responding that they are equally effective. Teaching sessions were reported to be resident-led ≥75% of the time by 50% of CRs versus 18% of PDs (P = .002). Significantly more CRs than PDs felt that faculty-led teaching conferences were more effective than resident-led conferences (62% vs 26%, respectively; P Socratic-based teaching conferences. Increased communication between PDs and CRs can better align perceptions with educational goals. Copyright © 2016 American Society for Radiation Oncology. Published by Elsevier Inc. All rights reserved.

  7. International Conference on Advances in Radiation Oncology (ICARO): outcomes of an IAEA meeting.

    Science.gov (United States)

    Salminen, Eeva K; Kiel, Krystyna; Ibbott, Geoffrey S; Joiner, Michael C; Rosenblatt, Eduardo; Zubizarreta, Eduardo; Wondergem, Jan; Meghzifene, Ahmed

    2011-02-04

    The IAEA held the International Conference on Advances in Radiation Oncology (ICARO) in Vienna on 27-29 April 2009. The Conference dealt with the issues and requirements posed by the transition from conventional radiotherapy to advanced modern technologies, including staffing, training, treatment planning and delivery, quality assurance (QA) and the optimal use of available resources. The current role of advanced technologies (defined as 3-dimensional and/or image guided treatment with photons or particles) in current clinical practice and future scenarios were discussed.ICARO was organized by the IAEA at the request of the Member States and co-sponsored and supported by other international organizations to assess advances in technologies in radiation oncology in the face of economic challenges that most countries confront. Participants submitted research contributions, which were reviewed by a scientific committee and presented via 46 lectures and 103 posters. There were 327 participants from 70 Member States as well as participants from industry and government. The ICARO meeting provided an independent forum for the interaction of participants from developed and developing countries on current and developing issues related to radiation oncology.

  8. International Conference on Advances in Radiation Oncology (ICARO: Outcomes of an IAEA Meeting

    Directory of Open Access Journals (Sweden)

    Wondergem Jan

    2011-02-01

    Full Text Available Abstract The IAEA held the International Conference on Advances in Radiation Oncology (ICARO in Vienna on 27-29 April 2009. The Conference dealt with the issues and requirements posed by the transition from conventional radiotherapy to advanced modern technologies, including staffing, training, treatment planning and delivery, quality assurance (QA and the optimal use of available resources. The current role of advanced technologies (defined as 3-dimensional and/or image guided treatment with photons or particles in current clinical practice and future scenarios were discussed. ICARO was organized by the IAEA at the request of the Member States and co-sponsored and supported by other international organizations to assess advances in technologies in radiation oncology in the face of economic challenges that most countries confront. Participants submitted research contributions, which were reviewed by a scientific committee and presented via 46 lectures and 103 posters. There were 327 participants from 70 Member States as well as participants from industry and government. The ICARO meeting provided an independent forum for the interaction of participants from developed and developing countries on current and developing issues related to radiation oncology.

  9. Lack of Prognostic Impact of Adjuvant Radiation on Oncologic Outcomes in Elderly Women with Breast Cancer.

    Science.gov (United States)

    Omidvari, Shapour; Talei, Abdolrasoul; Tahmasebi, Sedigheh; Moaddabshoar, Leila; Dayani, Maliheh; Mosalaei, Ahmad; Ahmadloo, Niloofar; Ansari, Mansour; Mohammadianpanah, Mohammad

    2015-01-01

    Radiotherapy plays an important role as adjuvant treatment in locally advanced breast cancer and in those patients who have undergone breast-conserving surgery. This study aimed to investigate the prognostic impact of adjuvant radiation on oncologic outcomes in elderly women with breast cancer. In this retrospective study, we reviewed and analyzed the characteristics, treatment outcome and survival of elderly women (aged ≥ 60 years) with breast cancer who were treated and followed-up between 1993 and 2014. The median follow up for the surviving patients was 38 (range 3-207) months. One hundred and seventy-eight patients with a median age of 74 (range 60-95) years were enrolled in the study. Of the total, 60 patients received postoperative adjuvant radiation (radiation group) and the remaining 118 did not (control group). Patients in the radiation group were significantly younger than those in the control group (P value=0.004). In addition, patients in radiation group had higher node stage (P value<0.001) and disease stage (P=0.003) and tended to have higher tumor grade (P=0.031) and received more frequent (P value <0.001) adjuvant and neoadjuvant chemotherapy compared to those in the control group. There was no statistically significant difference between two groups regarding the local control, disease-free survival and overall survival rates. In this study, we did not find a prognostic impact for adjuvant radiation on oncologic outcomes in elderly women with breast cancer.

  10. WE-B-BRD-00: MRI for Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2015-06-15

    The use of MRI in radiation therapy is rapidly increasing. Applications vary from the MRI simulator, to the MRI fused with CT, and to the integrated MRI+RT system. Compared with the standard MRI QA, a broader scope of QA features has to be defined in order to maximize the benefits of using MRI in radiation therapy. These QA features include geometric fidelity, image registration, motion management, cross-system alignment, and hardware interference. Advanced MRI techniques require a specific type of QA, as they are being widely used in radiation therapy planning, dose calculations, post-implant dosimetry, and prognoses. A vigorous and adaptive QA program is crucial to defining the responsibility of the entire radiation therapy group and detecting deviations from the performance of high-quality treatment. As a drastic departure from CT simulation, MRI simulation requires changes in the work flow of treatment planning and image guidance. MRI guided radiotherapy platforms are being developed and commercialized to take the advantage of the advance in knowledge, technology and clinical experience. This symposium will from an educational perspective discuss the scope and specific issues related to MRI guided radiotherapy. Learning Objectives: Understand the difference between a standard and a radiotherapy-specific MRI QA program. Understand the effects of MRI artifacts (geometric distortion and motion) on radiotherapy. Understand advanced MRI techniques (ultrashort echo, fast MRI including dynamic MRI and 4DMRI, diffusion, perfusion, and MRS) and related QA. Understand the methods to prepare MRI for treatment planning (electron density assignment, multimodality image registration, segmentation and motion management). Current status of MRI guided treatment platforms. Dr. Jihong Wang has a research grant with Elekta-MRL project. Dr. Ke Sheng receives research grants from Varian Medical systems.

  11. Department of Radiation and Environmental Biology - Overview

    International Nuclear Information System (INIS)

    Cebulska-Wasilewska, A.

    2001-01-01

    Full text: In the year 2000 we completed our study of the genotoxic influence of occupational exposure to pesticides on human cells, and their susceptibility to radiation in particular. Examining blood samples from four countries: Greece, Hungary, Poland and Spain we found that exposure to pesticides usually resulted in an increased susceptibility to the UV-C radiation, although statistical significance could only be concluded for inhabitants of Poland. In Spain, exposure to pesticides was proved to impair the lymphocyte DNA repair capability, while for the Polish group this repair capability appeared enhanced in people exposed to pesticides (see the research reports below). The possible influence of lifestyle or particular diet on the observed national differences would probably be worth analyzing. We also investigate the biological effectiveness of therapeutic beams (neutrons and X-rays). Experimental part of such study, concerning neutrons of different mean energies, is over and the results are now being processed. Our work covers hot issues of environmental and radiation biology making us research partners to many domestic and foreign scientific institutions. Our proficiency in the field is also reflected by membership in various expert boards (e.g. evaluating research applications for the Fifth EU Framework Programme for RTD and Demonstration Activities in the field 'Environment and Health', lecturing in the 2000 NATO IOS Life Science Books). We have entered the 5 th EU Programme Scheme within the EXPAH project starting January 1, 2001. (author)

  12. WE-H-BRB-03: Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success

    Energy Technology Data Exchange (ETDEWEB)

    McNutt, T. [Johns Hopkins University (United States)

    2016-06-15

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  13. WE-H-BRB-02: Where Do We Stand in the Applications of Big Data in Radiation Oncology?

    International Nuclear Information System (INIS)

    Xing, L.

    2016-01-01

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  14. WE-H-BRB-03: Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success

    International Nuclear Information System (INIS)

    McNutt, T.

    2016-01-01

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  15. WE-H-BRB-02: Where Do We Stand in the Applications of Big Data in Radiation Oncology?

    Energy Technology Data Exchange (ETDEWEB)

    Xing, L. [Stanford University School of Medicine (United States)

    2016-06-15

    Big Data in Radiation Oncology: (1) Overview of the NIH 2015 Big Data Workshop, (2) Where do we stand in the applications of big data in radiation oncology?, and (3) Learning Health Systems for Radiation Oncology: Needs and Challenges for Future Success The overriding goal of this trio panel of presentations is to improve awareness of the wide ranging opportunities for big data impact on patient quality care and enhancing potential for research and collaboration opportunities with NIH and a host of new big data initiatives. This presentation will also summarize the Big Data workshop that was held at the NIH Campus on August 13–14, 2015 and sponsored by AAPM, ASTRO, and NIH. The workshop included discussion of current Big Data cancer registry initiatives, safety and incident reporting systems, and other strategies that will have the greatest impact on radiation oncology research, quality assurance, safety, and outcomes analysis. Learning Objectives: To discuss current and future sources of big data for use in radiation oncology research To optimize our current data collection by adopting new strategies from outside radiation oncology To determine what new knowledge big data can provide for clinical decision support for personalized medicine L. Xing, NIH/NCI Google Inc.

  16. Development of a Quality and Safety Competency Curriculum for Radiation Oncology Residency: An International Delphi Study

    International Nuclear Information System (INIS)

    Adleman, Jenna; Gillan, Caitlin; Caissie, Amanda; Davis, Carol-Anne; Liszewski, Brian; McNiven, Andrea; Giuliani, Meredith

    2017-01-01

    Purpose: To develop an entry-to-practice quality and safety competency profile for radiation oncology residency. Methods and Materials: A comprehensive list of potential quality and safety competency items was generated from public and professional resources and interprofessional focus groups. Redundant or out-of-scope items were eliminated through investigator consensus. Remaining items were subjected to an international 2-round modified Delphi process involving experts in radiation oncology, radiation therapy, and medical physics. During Round 1, each item was scored independently on a 9-point Likert scale indicating appropriateness for inclusion in the competency profile. Items indistinctly ranked for inclusion or exclusion were re-evaluated through web conference discussion and reranked in Round 2. Results: An initial 1211 items were compiled from 32 international sources and distilled to 105 unique potential quality and safety competency items. Fifteen of the 50 invited experts participated in round 1: 10 radiation oncologists, 4 radiation therapists, and 1 medical physicist from 13 centers in 5 countries. Round 1 rankings resulted in 80 items included, 1 item excluded, and 24 items indeterminate. Two areas emerged more prominently within the latter group: change management and human factors. Web conference with 5 participants resulted in 9 of these 24 items edited for content or clarity. In Round 2, 12 participants rescored all indeterminate items resulting in 10 items ranked for inclusion. The final 90 enabling competency items were organized into thematic groups consisting of 18 key competencies under headings adapted from Deming's System of Profound Knowledge. Conclusions: This quality and safety competency profile may inform minimum training standards for radiation oncology residency programs.

  17. Development of a Quality and Safety Competency Curriculum for Radiation Oncology Residency: An International Delphi Study

    Energy Technology Data Exchange (ETDEWEB)

    Adleman, Jenna [Department of Radiation Oncology, University of Toronto, Toronto, Ontario (Canada); Gillan, Caitlin [Department of Radiation Oncology, University of Toronto, Toronto, Ontario (Canada); Radiation Medicine Program, Princess Margaret Cancer Centre, Toronto, Ontario (Canada); Caissie, Amanda [Department of Radiation Oncology, Dalhousie University, Halifax, Nova Scotia (Canada); Saint John Regional Hospital, Saint John, New Brunswick (Canada); Davis, Carol-Anne [Department of Radiation Oncology, Dalhousie University, Halifax, Nova Scotia (Canada); Nova Scotia Cancer Centre, Halifax, Nova Scotia (Canada); Liszewski, Brian [Odette Cancer Centre, Sunnybrook Health Sciences Centre, Toronto, Ontario (Canada); McNiven, Andrea [Department of Radiation Oncology, University of Toronto, Toronto, Ontario (Canada); Radiation Medicine Program, Princess Margaret Cancer Centre, Toronto, Ontario (Canada); Giuliani, Meredith, E-mail: Meredith.Giuliani@rmp.uhn.ca [Department of Radiation Oncology, University of Toronto, Toronto, Ontario (Canada); Radiation Medicine Program, Princess Margaret Cancer Centre, Toronto, Ontario (Canada)

    2017-06-01

    Purpose: To develop an entry-to-practice quality and safety competency profile for radiation oncology residency. Methods and Materials: A comprehensive list of potential quality and safety competency items was generated from public and professional resources and interprofessional focus groups. Redundant or out-of-scope items were eliminated through investigator consensus. Remaining items were subjected to an international 2-round modified Delphi process involving experts in radiation oncology, radiation therapy, and medical physics. During Round 1, each item was scored independently on a 9-point Likert scale indicating appropriateness for inclusion in the competency profile. Items indistinctly ranked for inclusion or exclusion were re-evaluated through web conference discussion and reranked in Round 2. Results: An initial 1211 items were compiled from 32 international sources and distilled to 105 unique potential quality and safety competency items. Fifteen of the 50 invited experts participated in round 1: 10 radiation oncologists, 4 radiation therapists, and 1 medical physicist from 13 centers in 5 countries. Round 1 rankings resulted in 80 items included, 1 item excluded, and 24 items indeterminate. Two areas emerged more prominently within the latter group: change management and human factors. Web conference with 5 participants resulted in 9 of these 24 items edited for content or clarity. In Round 2, 12 participants rescored all indeterminate items resulting in 10 items ranked for inclusion. The final 90 enabling competency items were organized into thematic groups consisting of 18 key competencies under headings adapted from Deming's System of Profound Knowledge. Conclusions: This quality and safety competency profile may inform minimum training standards for radiation oncology residency programs.

  18. Radiation doses to personnel in clinics for gynecologic oncology

    International Nuclear Information System (INIS)

    Forsberg, B.; Spanne, P.

    1985-01-01

    Radium or Cesium is used for radiotherapy of gynecologic cancer at six clinics in Sweden. This report gives a survey of the radiation doses the personnel is exposed to. The measurement were performed using TL-dosimeters. The dose equivalents for different parts of the body at specific working moments was deduced as well as the effective dose equivalent and the collective dose equivalent. 1983 the total collective dose equivalent for the six clinics was 1.3 manSv, which corresponds to 3.9 manmSv/g equivalent mass of Radium used at the treatments. (With 11 tables and 10 figures) (L.E.)

  19. The role of radiation therapy in childhood acute leukemia. A review from the viewpoint of basic and clinical radiation oncology

    International Nuclear Information System (INIS)

    Nozaki, Miwako

    2003-01-01

    Radiation therapy has been playing important roles in the treatment of childhood acute leukemia since the 1970s. The first is the preventive cranial irradiation for central nervous system therapy in acute lymphoblastic leukemia. The second is the total body irradiation as conditioning before bone marrow transplantation for children with acute myeloid leukemia in first remission and with acute lymphoblastic leukemia in second remission. Although some late effects have been reported, a part of them could be overcome by technical improvement in radiation and salvage therapy. Radiation therapy for children might have a successful outcome on a delicate balance between efficiencies and potential late toxicities. The role of radiation therapy for childhood acute leukemia was reviewed from the standpoint of basic and clinical radiation oncology in this paper. (author)

  20. Radiation terrorism: what society needs from the radiobiology-radiation protection and radiation oncology communities

    Energy Technology Data Exchange (ETDEWEB)

    Coleman, C Norman [Office of Preparedness and Emergency Response, Office of the Assistant Secretary for Preparedness and Response, Department of Health and Human Services, Washington, DC (United States); Parker, Gerald W [Office of the Assistant Secretary for Preparedness and Response, Department of Health and Human Services, Washington, DC (United States)

    2009-06-01

    Society's and individuals' concerns about the adverse effects from radiation are logically amplified many times when radiological terrorism is considered. The spectrum of events include industrial sabotage, the use of an explosive or non-explosive radiological dispersal device, the placement of a radiological exposure device in a public facility and the use of an improvised nuclear device. The consequences of an event relate to the physical and medical damage of the event itself, the financial impact, and the acute and long-term medical consequences, including fear of radiation-induced cancer. The magnitude of a state-sponsored nuclear event is so great that limited detailed response planning had been done in the past, as compared to the work now ongoing. Planning is done on the basis of scenario modelling. Medical response planning includes medical triage, distribution of victims to care by experienced physicians, developing medical countermeasures to mitigate or treat radiation injury, counselling and appropriately following exposed or potentially exposed people, and helping the local community develop confidence in their own response plan. Optimal response must be based on the best available science. This requires scientists who can define, prioritise and address the gaps in knowledge with the range of expertise from basic physics to biology to translational research to systems expertise to response planning to healthcare policy to communications. Not only are there unique needs and career opportunities, but there is also the opportunity for individuals to serve their communities and country with education regarding radiation effects and by formulating scientifically based government policy.

  1. Radiation terrorism: what society needs from the radiobiology-radiation protection and radiation oncology communities

    International Nuclear Information System (INIS)

    Coleman, C Norman; Parker, Gerald W

    2009-01-01

    Society's and individuals' concerns about the adverse effects from radiation are logically amplified many times when radiological terrorism is considered. The spectrum of events include industrial sabotage, the use of an explosive or non-explosive radiological dispersal device, the placement of a radiological exposure device in a public facility and the use of an improvised nuclear device. The consequences of an event relate to the physical and medical damage of the event itself, the financial impact, and the acute and long-term medical consequences, including fear of radiation-induced cancer. The magnitude of a state-sponsored nuclear event is so great that limited detailed response planning had been done in the past, as compared to the work now ongoing. Planning is done on the basis of scenario modelling. Medical response planning includes medical triage, distribution of victims to care by experienced physicians, developing medical countermeasures to mitigate or treat radiation injury, counselling and appropriately following exposed or potentially exposed people, and helping the local community develop confidence in their own response plan. Optimal response must be based on the best available science. This requires scientists who can define, prioritise and address the gaps in knowledge with the range of expertise from basic physics to biology to translational research to systems expertise to response planning to healthcare policy to communications. Not only are there unique needs and career opportunities, but there is also the opportunity for individuals to serve their communities and country with education regarding radiation effects and by formulating scientifically based government policy.

  2. Sociodemographic analysis of patients in radiation therapy oncology group clinical trials

    International Nuclear Information System (INIS)

    Chamberlain, Robert M.; Winter, Kathryn A.; Vijayakumar, Srinivasan; Porter, Arthur T.; Roach, M.; Streeter, Oscar; Cox, James D.; Bondy, Melissa L.

    1998-01-01

    Purpose: To assess the degree to which the sociodemographic characteristics of patients enrolled in Radiation Therapy Oncology Group (RTOG) clinical trails are representative of the general population. Methods and Materials: Sociodemographic data were collected on 4016 patients entered in 33 open RTOG studies between July 1991 and June 1994. The data analyzed included educational attainment, age, gender, and race. For comparison, we obtained similar data from the U.S. Department of Census. We also compared our RTOG data with Surveillance Epidemiology and End Results (SEER) data for patients who received radiation therapy, to determine how RTOG patients compared with cancer patients in general, and with patients with cancers at sites typically treated with radiotherapy. Results: Overall, the sociodemographic characteristics of patients entered in RTOG trials were similar to those of the Census data. We found that, in every age group of African-American men and at nearly every level of educational attainment, the proportion of RTOG trial participants mirrored the proportion in the census data. Significant differences were noted only in the youngest category of African-American men, where the RTOG accrues more in the lower educational categories and fewer with college experience. For African-American women, we found a similar pattern in every age group and at each level of educational attainment. As with men, RTOG trials accrued a considerably larger proportion of younger, less educated African-American women than the census reported. Using SEER for comparison, the RTOG enrolled proportionately more African-American men to trials all cancer sites combined, and for prostate and head and neck cancer. In head and neck trials, the RTOG enrolled nearly twice as many African-American men than would be predicted by SEER data. In lung cancer trials, RTOG underrepresented African-American men significantly; however, there was no difference for brain cancer trials. There were

  3. Workflow Enhancement (WE) Improves Safety in Radiation Oncology: Putting the WE and Team Together

    International Nuclear Information System (INIS)

    Chao, Samuel T.; Meier, Tim; Hugebeck, Brian; Reddy, Chandana A.; Godley, Andrew; Kolar, Matt; Suh, John H.

    2014-01-01

    Purpose: To review the impact of a workflow enhancement (WE) team in reducing treatment errors that reach patients within radiation oncology. Methods and Materials: It was determined that flaws in our workflow and processes resulted in errors reaching the patient. The process improvement team (PIT) was developed in 2010 to reduce errors and was later modified in 2012 into the current WE team. Workflow issues and solutions were discussed in PIT and WE team meetings. Due to tensions within PIT that resulted in employee dissatisfaction, there was a 6-month hiatus between the end of PIT and initiation of the renamed/redesigned WE team. In addition to the PIT/WE team forms, the department had separate incident forms to document treatment errors reaching the patient. These incident forms are rapidly reviewed and monitored by our departmental and institutional quality and safety groups, reflecting how seriously these forms are treated. The number of these incident forms was compared before and after instituting the WE team. Results: When PIT was disbanded, a number of errors seemed to occur in succession, requiring reinstitution and redesign of this team, rebranded the WE team. Interestingly, the number of incident forms per patient visits did not change when comparing 6 months during the PIT, 6 months during the hiatus, and the first 6 months after instituting the WE team (P=.85). However, 6 to 12 months after instituting the WE team, the number of incident forms per patient visits decreased (P=.028). After the WE team, employee satisfaction and commitment to quality increased as demonstrated by Gallup surveys, suggesting a correlation to the WE team. Conclusions: A team focused on addressing workflow and improving processes can reduce the number of errors reaching the patient. Time is necessary before a reduction in errors reaching patients will be seen

  4. Workflow Enhancement (WE) Improves Safety in Radiation Oncology: Putting the WE and Team Together

    Energy Technology Data Exchange (ETDEWEB)

    Chao, Samuel T., E-mail: chaos@ccf.org [Department of Radiation Oncology, Taussig Cancer Institute, Cleveland Clinic, Cleveland, Ohio (United States); Rose Ella Burkhardt Brain Tumor and Neuro-oncology Center, Cleveland Clinic, Cleveland, Ohio (United States); Meier, Tim; Hugebeck, Brian; Reddy, Chandana A.; Godley, Andrew; Kolar, Matt [Department of Radiation Oncology, Taussig Cancer Institute, Cleveland Clinic, Cleveland, Ohio (United States); Suh, John H. [Department of Radiation Oncology, Taussig Cancer Institute, Cleveland Clinic, Cleveland, Ohio (United States); Rose Ella Burkhardt Brain Tumor and Neuro-oncology Center, Cleveland Clinic, Cleveland, Ohio (United States)

    2014-07-15

    Purpose: To review the impact of a workflow enhancement (WE) team in reducing treatment errors that reach patients within radiation oncology. Methods and Materials: It was determined that flaws in our workflow and processes resulted in errors reaching the patient. The process improvement team (PIT) was developed in 2010 to reduce errors and was later modified in 2012 into the current WE team. Workflow issues and solutions were discussed in PIT and WE team meetings. Due to tensions within PIT that resulted in employee dissatisfaction, there was a 6-month hiatus between the end of PIT and initiation of the renamed/redesigned WE team. In addition to the PIT/WE team forms, the department had separate incident forms to document treatment errors reaching the patient. These incident forms are rapidly reviewed and monitored by our departmental and institutional quality and safety groups, reflecting how seriously these forms are treated. The number of these incident forms was compared before and after instituting the WE team. Results: When PIT was disbanded, a number of errors seemed to occur in succession, requiring reinstitution and redesign of this team, rebranded the WE team. Interestingly, the number of incident forms per patient visits did not change when comparing 6 months during the PIT, 6 months during the hiatus, and the first 6 months after instituting the WE team (P=.85). However, 6 to 12 months after instituting the WE team, the number of incident forms per patient visits decreased (P=.028). After the WE team, employee satisfaction and commitment to quality increased as demonstrated by Gallup surveys, suggesting a correlation to the WE team. Conclusions: A team focused on addressing workflow and improving processes can reduce the number of errors reaching the patient. Time is necessary before a reduction in errors reaching patients will be seen.

  5. Defining a Leader Role curriculum for radiation oncology: A global Delphi consensus study.

    Science.gov (United States)

    Turner, Sandra; Seel, Matthew; Trotter, Theresa; Giuliani, Meredith; Benstead, Kim; Eriksen, Jesper G; Poortmans, Philip; Verfaillie, Christine; Westerveld, Henrike; Cross, Shamira; Chan, Ming-Ka; Shaw, Timothy

    2017-05-01

    The need for radiation oncologists and other radiation oncology (RO) professionals to lead quality improvement activities and contribute to shaping the future of our specialty is self-evident. Leadership knowledge, skills and behaviours, like other competencies, can be learned (Blumenthal et al., 2012). The objective of this study was to define a globally applicable competency set specific to radiation oncology for the CanMEDS Leader Role (Frank et al., 2015). A modified Delphi consensus process delivering two rounds of on-line surveys was used. Participants included trainees, radiation/clinical oncologists and other RO team members (radiation therapists, physicists, and nurses), professional educators and patients. 72 of 95 (76%) invitees from nine countries completed the Round 1 (R1) survey. Of the 72 respondents to RI, 70 completed Round 2 (R2) (97%). In R1, 35 items were deemed for 'inclusion' and 21 for 'exclusion', leaving 41 'undetermined'. After review of items, informed by participant comments, 14 competencies from the 'inclusion' group went into the final curriculum; 12 from the 'undetermined' group went to R2. In R2, 6 items reached consensus for inclusion. This process resulted in 20 RO Leader Role competencies with apparent global applicability. This is the first step towards developing learning, teaching and assessment tools for this important area of training. Copyright © 2017 Elsevier B.V. All rights reserved.

  6. Oncology Patient Perceptions of the Use of Ionizing Radiation in Diagnostic Imaging.

    Science.gov (United States)

    Steele, Joseph R; Jones, Aaron K; Clarke, Ryan K; Giordano, Sharon H; Shoemaker, Stowe

    2016-07-01

    To measure the knowledge of oncology patients regarding use and potential risks of ionizing radiation in diagnostic imaging. A 30-question survey was developed and e-mailed to 48,736 randomly selected patients who had undergone a diagnostic imaging study at a comprehensive cancer center between November 1, 2013 and January 31, 2014. The survey was designed to measure patients' knowledge about use of ionizing radiation in diagnostic imaging and attitudes about radiation. Nonresponse bias was quantified by sending an abbreviated survey to patients who did not respond to the original survey. Of the 48,736 individuals who were sent the initial survey, 9,098 (18.7%) opened it, and 5,462 (11.2%) completed it. A total of 21.7% of respondents reported knowing the definition of ionizing radiation; 35.1% stated correctly that CT used ionizing radiation; and 29.4% stated incorrectly that MRI used ionizing radiation. Many respondents did not understand risks from exposure to diagnostic doses of ionizing radiation: Of 3,139 respondents who believed that an abdominopelvic CT scan carried risk, 1,283 (40.9%) believed sterility was a risk; 669 (21.3%) believed heritable mutations were a risk; 657 (20.9%) believed acute radiation sickness was a risk; and 135 (4.3%) believed cataracts were a risk. Most patients and caregivers do not possess basic knowledge regarding the use of ionizing radiation in oncologic diagnostic imaging. To ensure health literacy and high-quality patient decision making, efforts to educate patients and caregivers should be increased. Such education might begin with information about effects that are not risks of diagnostic imaging. Copyright © 2016 American College of Radiology. Published by Elsevier Inc. All rights reserved.

  7. Nuclear data needed for applications in radiation oncology

    International Nuclear Information System (INIS)

    White, R.M.; Chadwick, M.B.; Siantar, C.L.H.; Chandler, W.P.

    1994-03-01

    Fast neutrons have been used to treat over 15,000 cancer patients in approximately twenty centers worldwide and proton therapy is emerging as a potential treatment of choice for tumors near critical anatomical structures. Neutron therapy requires reaction data to ∼70 MeV while proton therapy requires data to ∼250 MeV. The cross section databases require energy- and angle-dependent cross sections for secondary neutrons, charged-particles and recoil nuclei. We discuss expansion of our nuclear databases and development of a three-dimensional radiation transport package that uses CT images as the input mesh to an all-particle Monte Carlo code. Called PEREGRINE, this code calculates dose distributions in the human body and can be used as a tool to determine the dependence of dose on details of the evaluated nuclear data

  8. Processes for Quality Improvements in Radiation Oncology Clinical Trials

    International Nuclear Information System (INIS)

    FitzGerald, T.J.; Urie, Marcia; Ulin, Kenneth; Laurie, Fran; Yorty, Jeffrey C.; Hanusik, Richard; Kessel, Sandy; Jodoin, Maryann Bishop; Osagie, Gani; Cicchetti, M. Giulia; Pieters, Richard; McCarten, Kathleen; Rosen, Nancy

    2008-01-01

    Quality assurance in radiotherapy (RT) has been an integral aspect of cooperative group clinical trials since 1970. In early clinical trials, data acquisition was nonuniform and inconsistent and computational models for radiation dose calculation varied significantly. Process improvements developed for data acquisition, credentialing, and data management have provided the necessary infrastructure for uniform data. With continued improvement in the technology and delivery of RT, evaluation processes for target definition, RT planning, and execution undergo constant review. As we move to multimodality image-based definitions of target volumes for protocols, future clinical trials will require near real-time image analysis and feedback to field investigators. The ability of quality assurance centers to meet these real-time challenges with robust electronic interaction platforms for imaging acquisition, review, archiving, and quantitative review of volumetric RT plans will be the primary challenge for future successful clinical trials

  9. [Technological innovations in radiation oncology require specific quality controls].

    Science.gov (United States)

    Lenaerts, E; Mathot, M

    2014-01-01

    During the last decade, the field of radiotherapy has benefited from major technological innovations and continuously improving treatment efficacy, comfort and safety of patients. This mainly concerns the imaging techniques that allow 4D CT scan recording the respiratory phases, on-board imaging on linear accelerators that ensure perfect positioning of the patient for treatment and irradiation techniques that reduce very significantly the duration of treatment sessions without compromising quality of the treatment plan, including IMRT (Intensity Modulated Radiation Therapy) and VMAT (Volumetric Modulated Arc therapy). In this context of rapid technological change, it is the responsibility of medical physicists to regularly and precisely monitor the perfect functioning of new techniques to ensure patient safety. This requires the use of specific quality control equipment best suited to these new techniques. We will briefly describe the measurement system Delta4 used to control individualized treatment plan for each patient treated with VMAT technology.

  10. Using Big Data Analytics to Advance Precision Radiation Oncology.

    Science.gov (United States)

    McNutt, Todd R; Benedict, Stanley H; Low, Daniel A; Moore, Kevin; Shpitser, Ilya; Jiang, Wei; Lakshminarayanan, Pranav; Cheng, Zhi; Han, Peijin; Hui, Xuan; Nakatsugawa, Minoru; Lee, Junghoon; Moore, Joseph A; Robertson, Scott P; Shah, Veeraj; Taylor, Russ; Quon, Harry; Wong, John; DeWeese, Theodore

    2018-06-01

    Big clinical data analytics as a primary component of precision medicine is discussed, identifying where these emerging tools fit in the spectrum of genomics and radiomics research. A learning health system (LHS) is conceptualized that uses clinically acquired data with machine learning to advance the initiatives of precision medicine. The LHS is comprehensive and can be used for clinical decision support, discovery, and hypothesis derivation. These developing uses can positively impact the ultimate management and therapeutic course for patients. The conceptual model for each use of clinical data, however, is different, and an overview of the implications is discussed. With advancements in technologies and culture to improve the efficiency, accuracy, and breadth of measurements of the patient condition, the concept of an LHS may be realized in precision radiation therapy. Copyright © 2018 Elsevier Inc. All rights reserved.

  11. Iridium-Knife: Another knife in radiation oncology.

    Science.gov (United States)

    Milickovic, Natasa; Tselis, Nikolaos; Karagiannis, Efstratios; Ferentinos, Konstantinos; Zamboglou, Nikolaos

    Intratarget dose escalation with superior conformity is a defining feature of three-dimensional (3D) iridium-192 ( 192 Ir) high-dose-rate (HDR) brachytherapy (BRT). In this study, we analyzed the dosimetric characteristics of interstitial 192 Ir HDR BRT for intrathoracic and cerebral malignancies. We examined the dose gradient sharpness of HDR BRT compared with that of linear accelerator-based stereotactic radiosurgery and stereotactic body radiation therapy, usually called X-Knife, to demonstrate that it may as well be called a Knife. Treatment plans for 10 patients with recurrent glioblastoma multiforme or intrathoracic malignancies, five of each entity, treated with X-Knife (stereotactic radiosurgery for glioblastoma multiforme and stereotactic body radiation therapy for intrathoracic malignancies) were replanned for simulated HDR BRT. For 3D BRT planning, we used identical structure sets and dose prescription as for the X-Knife planning. The indices for qualitative treatment plan analysis encompassed planning target volume coverage, conformity, dose falloff gradient, and the maximum dose-volume limits to different organs at risk. Volume coverage in HDR plans was comparable to that calculated for X-Knife plans with no statistically significant difference in terms of conformity. The dose falloff gradient-sharpness-of the HDR plans was considerably steeper compared with the X-Knife plans. Both 3D 192 Ir HDR BRT and X-Knife are effective means for intratarget dose escalation with HDR BRT achieving at least equal conformity and a steeper dose falloff at the target volume margin. In this sense, it can reasonably be argued that 3D 192 Ir HDR BRT deserves also to be called a Knife, namely Iridium-Knife. Copyright © 2017 American Brachytherapy Society. Published by Elsevier Inc. All rights reserved.

  12. Clinical audit in radiation oncology: results from one centre

    International Nuclear Information System (INIS)

    Stevens, G.; Firth, I.

    1996-01-01

    Patient, tumour and treatment-related data were collected for courses of radiation treatment that were commenced within two 6-month periods in both 1988 and 1993. In both time periods, 45-49% of patients were treated with curative intent. Of these, one-third were irradiated definitively and two-thirds in an adjuvant setting. Most of the remainder were treated with palliative intent. In both time periods, breast and lung tumours represented approximately 20% each of the total treatment courses. Skin, head and neck, gynaecological, urological and haematological primary tumours accounted for 5-10% each. Treatment intents differed markedly for different primary sites, thus in 1993 65% of patients with breast primaries were treated curatively compared with 6% of patients with lung primaries. Treatment schedules for curative intent were similar in both time periods and for the majority of treatment sites. Median fraction numbers were 25 (excluding skin primaries), reflecting conventional daily fractionation. Treatment schedules for palliation showed greater variation and there was a trend towards shorter treatment courses in 1993. For palliative treatment of bone, brain and lung, from either primary or metastatic disease, treatment schedules with 10-15 fractions were used most frequently in 1988. In 1993, however, the majority of patients received 1-5 fractions. Patients living in areas with rural postcodes were more likely to receive palliative irradiation and had a higher incidence of melanoma than patients living in areas with Sydney metropolitan postcodes. As approximately 50% of patients were treated with palliative intent, changes in the fractionation patterns used can alter significantly the utilization and availability of megavoltage equipment. However, any reduction in attendances caused by hypofractionation for palliation may be offset by the trend to use hyperfractionation for curative treatments. The data support the hypothesis of reduced availability and use

  13. Ionizing radiation hazards and its protection in a radiodiagnostic department

    International Nuclear Information System (INIS)

    Sinha, R.P.; Rai, S.D.

    1977-01-01

    After mentioning the contribution to gonadal dose from natural background and man-made radiation sources including those used in medical radiology, methods for minimising the radiation dose to the patients and staff in x-ray diagnostic department are discussed in brief. (M.G.B.)

  14. Modern Radiation Therapy for Extranodal Lymphomas: Field and Dose Guidelines From the International Lymphoma Radiation Oncology Group

    Energy Technology Data Exchange (ETDEWEB)

    Yahalom, Joachim, E-mail: yahalomj@mskcc.org [Department of Radiation Oncology, Memorial Sloan-Kettering Cancer Center, New York, New York (United States); Illidge, Tim [Institute of Cancer Sciences, University of Manchester, Manchester Academic Health Sciences Centre, The Christie National Health Service Foundation Trust, Manchester (United Kingdom); Specht, Lena [Department of Oncology and Hematology, Rigshospitalet, University of Copenhagen, Copenhagen (Denmark); Hoppe, Richard T. [Department of Radiation Oncology, Stanford University, Palo Alto, California (United States); Li, Ye-Xiong [Department of Radiation Oncology, Cancer Hospital, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing (China); Tsang, Richard [Department of Radiation Oncology, Princess Margaret Hospital, University of Toronto, Toronto, Ontario (Canada); Wirth, Andrew [Division of Radiation Oncology, Peter MacCallum Cancer Institute, St. Andrews Place, East Melbourne (Australia)

    2015-05-01

    Extranodal lymphomas (ENLs) comprise about a third of all non-Hodgkin lymphomas (NHL). Radiation therapy (RT) is frequently used as either primary therapy (particularly for indolent ENL), consolidation after systemic therapy, salvage treatment, or palliation. The wide range of presentations of ENL, involving any organ in the body and the spectrum of histological sub-types, poses a challenge both for routine clinical care and for the conduct of prospective and retrospective studies. This has led to uncertainty and lack of consistency in RT approaches between centers and clinicians. Thus far there is a lack of guidelines for the use of RT in the management of ENL. This report presents an effort by the International Lymphoma Radiation Oncology Group (ILROG) to harmonize and standardize the principles of treatment of ENL, and to address the technical challenges of simulation, volume definition and treatment planning for the most frequently involved organs. Specifically, detailed recommendations for RT volumes are provided. We have applied the same modern principles of involved site radiation therapy as previously developed and published as guidelines for Hodgkin lymphoma and nodal NHL. We have adopted RT volume definitions based on the International Commission on Radiation Units and Measurements (ICRU), as has been widely adopted by the field of radiation oncology for solid tumors. Organ-specific recommendations take into account histological subtype, anatomy, the treatment intent, and other treatment modalities that may be have been used before RT.

  15. Modern Radiation Therapy for Extranodal Lymphomas: Field and Dose Guidelines From the International Lymphoma Radiation Oncology Group

    International Nuclear Information System (INIS)

    Yahalom, Joachim; Illidge, Tim; Specht, Lena; Hoppe, Richard T.; Li, Ye-Xiong; Tsang, Richard; Wirth, Andrew

    2015-01-01

    Extranodal lymphomas (ENLs) comprise about a third of all non-Hodgkin lymphomas (NHL). Radiation therapy (RT) is frequently used as either primary therapy (particularly for indolent ENL), consolidation after systemic therapy, salvage treatment, or palliation. The wide range of presentations of ENL, involving any organ in the body and the spectrum of histological sub-types, poses a challenge both for routine clinical care and for the conduct of prospective and retrospective studies. This has led to uncertainty and lack of consistency in RT approaches between centers and clinicians. Thus far there is a lack of guidelines for the use of RT in the management of ENL. This report presents an effort by the International Lymphoma Radiation Oncology Group (ILROG) to harmonize and standardize the principles of treatment of ENL, and to address the technical challenges of simulation, volume definition and treatment planning for the most frequently involved organs. Specifically, detailed recommendations for RT volumes are provided. We have applied the same modern principles of involved site radiation therapy as previously developed and published as guidelines for Hodgkin lymphoma and nodal NHL. We have adopted RT volume definitions based on the International Commission on Radiation Units and Measurements (ICRU), as has been widely adopted by the field of radiation oncology for solid tumors. Organ-specific recommendations take into account histological subtype, anatomy, the treatment intent, and other treatment modalities that may be have been used before RT

  16. [Advances in radiation oncology for metastatic bone disease].

    Science.gov (United States)

    Thariat, Juliette; Fric, Danièle; Kerr, Christine; Leysalle, Axel; Angellier, Gaelle; Dejean, Catherine; Tuillier, Titien; Bensadoun, René-Jean; Lagrange, Jean-Léon

    2013-11-01

    Irradiation of bone metastases primarily aims at alleviating pain, preventing fracture in the short term. The higher doses and more conformal dose distribution achievable while saving healthy tissue with new irradiation techniques have induced a paradigm shift in the management of bone metastases in a growing number of clinical situations. A search of the English and French literature was conducted using the keywords: bone metastases, radiotherapy, interventional radiology, vertebroplasty, radiofrequency, chemoembolization. RESULTS-DISCUSSION: Stereotactic irradiation yields pain relief rates greater than 90% in Phase I/II and retrospective studies. IMRT (static, rotational, helical) and stereotactic irradiation yield local control rates of 75-90% at 2 years. Some situations previously evaluated as palliative are currently treated more aggressively with optimized radiation sometimes combined modality interventional radiology. A recommendation can only be made for stereotactic irradiation in vertebral oligometastases or reirradiation. In the absence of a sufficient level of evidence, the increasing use of conformal irradiation techniques can only reflect the daily practice and the patient benefit while integrating economic logic care. The impact of these aggressive approaches on survival remains to be formally demonstrated by interventional prospective studies or observatories including quality of life items and minimal 2-year follow-up.

  17. Robotic motion compensation for applications in radiation oncology

    International Nuclear Information System (INIS)

    Herrmann, Christian

    2013-01-01

    Radiation therapy today, on account of improvements in treatment procedures over the last 60 years, allows precise treatment of static tumors inside the human body. However, irradiation of moving tumors is still a challenging task as moving tumors often leave the treatment beam and the radiation dose delivered to the tumor reduces simultaneously increasing that on healthy tissue. This research work aims to push the frontiers of radiation therapy in order to enable precise treatment of moving tumors with focus on research and development of a unique real-time system enabling active motion compensation through robotic means to compensate tumor motion. During treatment, patients lie on a treatment couch which is normally used for static position corrections of patient set-up errors prior to radiation treatment. The treatment couch used, called HexaPOD, is a parallel manipulator with six degrees of freedom which can precisely position heavy loads inside a small region. Despite the HexaPOD not initially built with dynamics in mind, it is used in this work for sustained motion compensation by moving patients such that tumors stay precisely located at the center of the treatment beam during the complete course of treatment. In order to realize real-time tumor motion compensation by means of the HexaPOD, several challenges need to be addressed. Real-time aspects are covered by the adoption of a hard real-time operation system in combination with measurement and estimation of latencies of all physical quantities in the compensation system such as tumor or breathing position measurements. Accurate timing information is respected consistently in the whole system and all software-induced latencies are adaptively compensated for. This requires knowledge of future tumor positions from predictors. Several predictors for breathing and tumor motion predictions are proposed and evaluated in terms of a variety of different performance metrics. Extensions to prediction algorithms are

  18. Robotic motion compensation for applications in radiation oncology

    Energy Technology Data Exchange (ETDEWEB)

    Herrmann, Christian

    2013-07-22

    Radiation therapy today, on account of improvements in treatment procedures over the last 60 years, allows precise treatment of static tumors inside the human body. However, irradiation of moving tumors is still a challenging task as moving tumors often leave the treatment beam and the radiation dose delivered to the tumor reduces simultaneously increasing that on healthy tissue. This research work aims to push the frontiers of radiation therapy in order to enable precise treatment of moving tumors with focus on research and development of a unique real-time system enabling active motion compensation through robotic means to compensate tumor motion. During treatment, patients lie on a treatment couch which is normally used for static position corrections of patient set-up errors prior to radiation treatment. The treatment couch used, called HexaPOD, is a parallel manipulator with six degrees of freedom which can precisely position heavy loads inside a small region. Despite the HexaPOD not initially built with dynamics in mind, it is used in this work for sustained motion compensation by moving patients such that tumors stay precisely located at the center of the treatment beam during the complete course of treatment. In order to realize real-time tumor motion compensation by means of the HexaPOD, several challenges need to be addressed. Real-time aspects are covered by the adoption of a hard real-time operation system in combination with measurement and estimation of latencies of all physical quantities in the compensation system such as tumor or breathing position measurements. Accurate timing information is respected consistently in the whole system and all software-induced latencies are adaptively compensated for. This requires knowledge of future tumor positions from predictors. Several predictors for breathing and tumor motion predictions are proposed and evaluated in terms of a variety of different performance metrics. Extensions to prediction algorithms are

  19. The implications of breast cancer molecular phenotype for radiation oncology

    Directory of Open Access Journals (Sweden)

    Shirin eSioshansi

    2011-06-01

    Full Text Available The identification of distinct molecular subtypes of breast cancer has advanced the understanding and treatment of breast cancer by providing insight into prognosis, patterns of recurrence and effectiveness of therapy. The prognostic significance of molecular phenotype with regard to distant recurrences and overall survival are well established in the literature and has been readily incorporated into systemic therapy management decisions. However, despite the accumulating data suggesting similar prognostic significance for locoregional recurrence, integration of molecular phenotype into local management decision making has lagged. Although there are some conflicting reports, collectively the literature supports a low risk of local recurrence in the hormone receptor positive luminal subtypes compared to hormone receptor negative subtypes (triple negative and HER2-enriched. The development of targeted therapies, such as trastuzumab for the treatment of HER2-enriched subtype, has been shown to mitigate the increased risk of local recurrence. Unfortunately, no such remedy exists to address the increased risk of local recurrence for patients with triple negative tumors, making it a clinical challenge for radiation oncologists. In this review we discuss the correlation between molecular subtype and local recurrence following either breast conservation therapy or mastectomy. We also explore the possible mechanisms for increased local recurrence in triple negative breast cancer and radiotherapeutic implications for this population, such as the safety of breast conservation, consideration of dose escalation and the appropriateness of accelerated partial breast irradiation.

  20. The Implications of Breast Cancer Molecular Phenotype for Radiation Oncology

    Energy Technology Data Exchange (ETDEWEB)

    Sioshansi, Shirin [Department of Radiation Oncology, Tufts Medical Center, Tufts University School of Medicine, Boston, MA (United States); Department of Radiation Oncology, Rhode Island Hospital, Warren Alpert School of Medicine at Brown University, Providence, RI (United States); Huber, Kathryn E. [Department of Radiation Oncology, Tufts Medical Center, Tufts University School of Medicine, Boston, MA (United States); Wazer, David E., E-mail: dwazer@tuftsmedicalcenter.org [Department of Radiation Oncology, Tufts Medical Center, Tufts University School of Medicine, Boston, MA (United States); Department of Radiation Oncology, Rhode Island Hospital, Warren Alpert School of Medicine at Brown University, Providence, RI (United States)

    2011-06-28

    The identification of distinct molecular subtypes of breast cancer has advanced the understanding and treatment of breast cancer by providing insight into prognosis, patterns of recurrence, and effectiveness of therapy. The prognostic significance of molecular phenotype with regard to distant recurrences and overall survival are well established in the literature and has been readily incorporated into systemic therapy management decisions. However, despite the accumulating data suggesting similar prognostic significance for locoregional recurrence, integration of molecular phenotype into local management decision making has lagged. Although there are some conflicting reports, collectively the literature supports a low risk of local recurrence (LR) in the hormone receptor (HR) positive luminal subtypes compared to HR negative subtypes [triple negative (TN) and HER2-enriched]. The development of targeted therapies, such as trastuzumab for the treatment of HER2-enriched subtype, has been shown to mitigate the increased risk of LR. Unfortunately, no such remedy exists to address the increased risk of LR for patients with TN tumors, making it a clinical challenge for radiation oncologists. In this review we discuss the correlation between molecular subtype and LR following either breast conservation therapy or mastectomy. We also explore the possible mechanisms for increased LR in TN breast cancer and radiotherapeutic implications for this population, such as the safety of breast conservation, consideration of dose escalation, and the appropriateness of accelerated partial breast irradiation.

  1. The Implications of Breast Cancer Molecular Phenotype for Radiation Oncology

    International Nuclear Information System (INIS)

    Sioshansi, Shirin; Huber, Kathryn E.; Wazer, David E.

    2011-01-01

    The identification of distinct molecular subtypes of breast cancer has advanced the understanding and treatment of breast cancer by providing insight into prognosis, patterns of recurrence, and effectiveness of therapy. The prognostic significance of molecular phenotype with regard to distant recurrences and overall survival are well established in the literature and has been readily incorporated into systemic therapy management decisions. However, despite the accumulating data suggesting similar prognostic significance for locoregional recurrence, integration of molecular phenotype into local management decision making has lagged. Although there are some conflicting reports, collectively the literature supports a low risk of local recurrence (LR) in the hormone receptor (HR) positive luminal subtypes compared to HR negative subtypes [triple negative (TN) and HER2-enriched]. The development of targeted therapies, such as trastuzumab for the treatment of HER2-enriched subtype, has been shown to mitigate the increased risk of LR. Unfortunately, no such remedy exists to address the increased risk of LR for patients with TN tumors, making it a clinical challenge for radiation oncologists. In this review we discuss the correlation between molecular subtype and LR following either breast conservation therapy or mastectomy. We also explore the possible mechanisms for increased LR in TN breast cancer and radiotherapeutic implications for this population, such as the safety of breast conservation, consideration of dose escalation, and the appropriateness of accelerated partial breast irradiation.

  2. Department of Radiation and Environmental Biology - Overview

    International Nuclear Information System (INIS)

    Cebulska-Wasilewska, A.

    2000-01-01

    Full text:The year 1999 we devoted mainly to the activities concerning our basic research, and requirements and expectations of three research projects. The environmental project from the European Community was supporting our research in the issues of human monitoring of occupational exposure to pesticides. The two other radiobiology projects from the State Committee of Research were supporting our search on the biological efficiency and its enhancement of radio-therapeutic sources of various LET radiation. We succeeded fruitful co-operation with colleagues from Academy of Mining and Metallurgy that let us go faster with modernization of our laboratory by automation of our methods for screening cytogenetic damages. A lot of efforts were paid to modify our work by automatic reports of the coordinates of aberrant metaphases, and to make a smooth work of our new and own metaphase finder. We are sure that our new and unique research tool will not only enhance the accuracy and speed of measurements, but will also be useful for the purpose of the retrospective biological dosimetry of absorbed doses. We have applied fluorescent in situ hybridization (FISH) for cytogenetic studies of biological effects induced by neutrons. Now, we are looking forward to apply this technique in a combination with the DNA damage measures done by SCGE assay, to our research on mechanisms of the induction and repair, or interaction of the lesions induced by genotoxic agents. Understanding of the regulation of these processes could be a good goal for the new century to come. (author)

  3. R-IDEAL: A Framework for Systematic Clinical Evaluation of Technical Innovations in Radiation Oncology.

    Science.gov (United States)

    Verkooijen, Helena M; Kerkmeijer, Linda G W; Fuller, Clifton D; Huddart, Robbert; Faivre-Finn, Corinne; Verheij, Marcel; Mook, Stella; Sahgal, Arjun; Hall, Emma; Schultz, Chris

    2017-01-01

    The pace of innovation in radiation oncology is high and the window of opportunity for evaluation narrow. Financial incentives, industry pressure, and patients' demand for high-tech treatments have led to widespread implementation of innovations before, or even without, robust evidence of improved outcomes has been generated. The standard phase I-IV framework for drug evaluation is not the most efficient and desirable framework for assessment of technological innovations. In order to provide a standard assessment methodology for clinical evaluation of innovations in radiotherapy, we adapted the surgical IDEAL framework to fit the radiation oncology setting. Like surgery, clinical evaluation of innovations in radiation oncology is complicated by continuous technical development, team and operator dependence, and differences in quality control. Contrary to surgery, radiotherapy innovations may be used in various ways, e.g., at different tumor sites and with different aims, such as radiation volume reduction and dose escalation. Also, the effect of radiation treatment can be modeled, allowing better prediction of potential benefits and improved patient selection. Key distinctive features of R-IDEAL include the important role of predicate and modeling studies (Stage 0), randomization at an early stage in the development of the technology, and long-term follow-up for late toxicity. We implemented R-IDEAL for clinical evaluation of a recent innovation in radiation oncology, the MRI-guided linear accelerator (MR-Linac). MR-Linac combines a radiotherapy linear accelerator with a 1.5-T MRI, aiming for improved targeting, dose escalation, and margin reduction, and is expected to increase the use of hypofractionation, improve tumor control, leading to higher cure rates and less toxicity. An international consortium, with participants from seven large cancer institutes from Europe and North America, has adopted the R-IDEAL framework to work toward coordinated, evidence

  4. Impact of Quality Assurance Rounds in a Canadian Radiation Therapy Department

    Energy Technology Data Exchange (ETDEWEB)

    Lefresne, Shilo; Olivotto, Ivo A.; Joe, Howard; Blood, Paul A. [Radiotherapy Department, BC Cancer Agency, Vancouver Island Centre, Vancouver, British Columbia (Canada); Radiotherapy Department, University of British Columbia, Vancouver, British Columbia (Canada); Olson, Robert A., E-mail: rolson2@bccancer.bc.ca [Radiotherapy Department, University of British Columbia, Vancouver, British Columbia (Canada); Radiotherapy Department, BC Cancer Agency, Centre for the North, Prince George, British Columbia (Canada)

    2013-03-01

    Purpose: Quality assurance (QA) programs aim to identify inconsistencies that may compromise patient care. Radiation treatment planning is a well-documented source of variation in radiation oncology, leading many organizations to recommend the implementation of QA rounds in which radiation therapy plans are peer reviewed. This study evaluates the outcome of QA rounds that have been conducted by a radiation therapy department since 2004. Methods and Materials: Prospectively documented records of QA rounds, from 2004 to 2010, were obtained. During rounds, randomly selected radiation therapy plans were peer reviewed and assigned a grade of A (adequate), B (minor suggestions of change to a plan for a future patient), or C (significant change required before the next fraction). The proportion of plans that received each recommendation was calculated, and the relationship between recommendations for each plan, tumor site, and mean years of experience of the radiation oncologist (RO) were explored. Chart reviews were performed for each plan that received a C. Results: During the study period, 1247 plans were evaluated; 6% received a B and 1% received a C. The mean RO years of experience were lower for plans graded C versus those graded A (P=.02). The tumor sites with the highest proportion of plans graded B or C were gastrointestinal (14%), lung (13%), and lymphoma (8%). The most common reasons for plans to receive a grade of C were inadequate target volume coverage (36%), suboptimal dose or fractionation (27%), errors in patient setup (27%), and overtreatment of normal tissue (9%). Conclusions: This study demonstrated that QA rounds are feasible and an important element of a radiation therapy department's QA program. Through peer review, plans that deviate from a department's expected standard can be identified and corrected. Additional benefits include identifying patterns of practice that may contribute to inconsistencies in treatment planning and the

  5. Impact of Quality Assurance Rounds in a Canadian Radiation Therapy Department

    International Nuclear Information System (INIS)

    Lefresne, Shilo; Olivotto, Ivo A.; Joe, Howard; Blood, Paul A.; Olson, Robert A.

    2013-01-01

    Purpose: Quality assurance (QA) programs aim to identify inconsistencies that may compromise patient care. Radiation treatment planning is a well-documented source of variation in radiation oncology, leading many organizations to recommend the implementation of QA rounds in which radiation therapy plans are peer reviewed. This study evaluates the outcome of QA rounds that have been conducted by a radiation therapy department since 2004. Methods and Materials: Prospectively documented records of QA rounds, from 2004 to 2010, were obtained. During rounds, randomly selected radiation therapy plans were peer reviewed and assigned a grade of A (adequate), B (minor suggestions of change to a plan for a future patient), or C (significant change required before the next fraction). The proportion of plans that received each recommendation was calculated, and the relationship between recommendations for each plan, tumor site, and mean years of experience of the radiation oncologist (RO) were explored. Chart reviews were performed for each plan that received a C. Results: During the study period, 1247 plans were evaluated; 6% received a B and 1% received a C. The mean RO years of experience were lower for plans graded C versus those graded A (P=.02). The tumor sites with the highest proportion of plans graded B or C were gastrointestinal (14%), lung (13%), and lymphoma (8%). The most common reasons for plans to receive a grade of C were inadequate target volume coverage (36%), suboptimal dose or fractionation (27%), errors in patient setup (27%), and overtreatment of normal tissue (9%). Conclusions: This study demonstrated that QA rounds are feasible and an important element of a radiation therapy department's QA program. Through peer review, plans that deviate from a department's expected standard can be identified and corrected. Additional benefits include identifying patterns of practice that may contribute to inconsistencies in treatment planning and the continuing

  6. Department of Cosmic Radiation Physics: Overview

    International Nuclear Information System (INIS)

    Gawin, J.

    1999-01-01

    Full text: The Department of Cosmic Ray Physics in Lodz is involved in basic research in the area of high energy physics and cosmic ray physics related to: - Studies of asymptotic properties of hadronic interactions based on the analysis of cosmic ray propagation in the atmosphere. - Experimental and phenomenological studies of Extensive Air Showers induced by cosmic ray particles. - Search for point sources of high energy cosmic rays. - Studies of cosmic ray propagation in the Galaxy and mechanisms of particle acceleration. - Studies of mass composition of cosmic rays in the energy range 10 15 - 10 17 eV. Theoretical and experimental studies of Extensive Air Shower properties are performed mostly based on the results obtained by the