Medical and administrative management of a nuclear medicine department with a microcomputer

International Nuclear Information System (INIS)

Legras, B.; Kohler, F.

1984-01-01

The use of a microcomputer for data management in a department of Nuclear Medicine has allowed to reduce considerably office work, and supplies the physicians with very useful statistics on the investigations carried out [fr

Reduction of doses to staff in a nuclear medicine department

International Nuclear Information System (INIS)

Van Every, B.

1982-01-01

Data relating to the radiation protection of staff working in the Department of Nuclear Medicine, Alfred Hospital, Victoria during the period 1977 to 1981 are examined. No member of staff received more than one tenth of the annual whole body dose limit of 5x10 4 μSv. The reduction in the total whole body dose of staff and in the technologist's individual dose is due to relocating the department, using appropriate radiation monitoring equipment, using a staff roster and making staff aware of previous doses

A quality assurance in a Nuclear Medicine Department: Implementation, results and implications

International Nuclear Information System (INIS)

Komninos, C.; Roach, P.J.

1998-01-01

Full text: An increasing emphasis is being placed on quality assurance programs in all areas of health care delivery. We describe our experience with such a program in the Nuclear Medicine Department of a large teaching hospital. We obtained completed patient questionnaires from 92 outpatients referred to the Nuclear Medicine Department. Questions related to areas such as provision of information about the test; patient''s impressions of staff involved with the procedure (doctors, technologists, nurses, secretaries); waiting times and delays; the appearance of the department; and the patients'' general level of satisfaction with their attendance in our department. Suggestions for improvement were specifically encouraged. The results indicated that while there was a high level of satisfaction with the people performing the studies, comments and criticisms were made by a significant number of people in some areas. These included provision of more information about the study prior to and during the test; all staff introducing themselves by name during the procedure; better communication about any delays; and an upgrading in the appearance of the department. Based on the results of this questionnaire, we have been able to implement various changes within the department. Although the results of our survey will apply specifically to this department, we encourage other departments and practices to implement similar patient surveys, thereby potentially improving the quality of service and patient satisfaction

A quality assurance in a Nuclear Medicine Department: Implementation, results and implications

Energy Technology Data Exchange (ETDEWEB)

Komninos, C.; Roach, P.J. [Royal North Shore Hospital, St Leonards, NSW (Australia)

1998-03-01

Full text: An increasing emphasis is being placed on quality assurance programs in all areas of health care delivery. We describe our experience with such a program in the Nuclear Medicine Department of a large teaching hospital. We obtained completed patient questionnaires from 92 outpatients referred to the Nuclear Medicine Department. Questions related to areas such as provision of information about the test; patient``s impressions of staff involved with the procedure (doctors, technologists, nurses, secretaries); waiting times and delays; the appearance of the department; and the patients`` general level of satisfaction with their attendance in our department. Suggestions for improvement were specifically encouraged. The results indicated that while there was a high level of satisfaction with the people performing the studies, comments and criticisms were made by a significant number of people in some areas. These included provision of more information about the study prior to and during the test; all staff introducing themselves by name during the procedure; better communication about any delays; and an upgrading in the appearance of the department. Based on the results of this questionnaire, we have been able to implement various changes within the department. Although the results of our survey will apply specifically to this department, we encourage other departments and practices to implement similar patient surveys, thereby potentially improving the quality of service and patient satisfaction.

Technetium99m shortage: Practical solutions to manage lack of the radio-isotope in nuclear medicine departments

International Nuclear Information System (INIS)

Biechlin-Chassel, M.L.; Francois-Joubert, A.; Bolot, C.; Desruet, M.D.; Bourrel, F.; Pelegrin, M.; Couret, I.; Lao, S.; Quelven, I.

2010-01-01

Technetium 99m ( 99m Tc) shortage crisis regularly affect nuclear medicine activity and oblige the community to find solutions in order to perform most of the prescribed exams and avoid systematic substitutions by other non-nuclear medicine techniques. Firstly, some practical solutions can be set up in radiopharmacy departments such as using more than two generators together, realizing fractionated elutions, preparing radiopharmaceuticals with elutions providing from different generators.. Then, it could be interesting to have a reflexion in nuclear medicine departments to convene patients the days when 99m Tc supply is sufficient, to pool some exams or to make substitutions with more available isotopes. (authors)

Links between nuclear medicine and radiopharmacy

International Nuclear Information System (INIS)

Pelegrin, M.; Francois-Joubert, A.; Chassel, M.L.; Desruet, M.D.; Bolot, C.; Lao, S.

2010-01-01

Radiopharmaceuticals are nowadays under the responsibility of the radio-pharmacist because of their medicinal product status. Radiopharmacy belongs to the hospital pharmacy department, nevertheless, interactions with nuclear medicine department are important: rooms are included or located near nuclear medicine departments in order to respect radiation protection rules, more over staff, a part of the material and some activities are shared between the two departments. Consequently, it seems essential to formalize links between the radiopharmacy and the nuclear medicine department, setting the goals to avoid conflicts and to ensure patients' security. Modalities chosen for this formalization will depend on the establishment's organization. (authors)

Quality control in Department of Nuclear Medicine, Clinical Center Banja Luka, RS, Bosnia and Herzegovina

International Nuclear Information System (INIS)

Goran Vuleta

2007-01-01

Complete test of publication follows. The aim of this work is to give a review of situations in the Department of Nuclear Medicine in Banja Luka related to quality control. We must perform daily, weekly and monthly control of equipment in the Department of Nuclear Medicine, and we must keep records. In our Department we have equipment from different producers and different year of production: 3 gamma cameras (1973, 1989, 2000); 2 auto gamma counters (2000, 2006); 2 dose calibrators (1973, 2000); 1 thyroid uptake system (2000). Normally procedures for quality control are also different. The situation, according to results of quality control is good. All equipment is working normally and with good performance (except one gamma camera - a problem with hard drive), but we don't have a routine daily control and periodical control for others tests. Keeping a records is another problem. Why? 1. In Bosnia and Herzegovina we don't have Regulatory authority. That means that we don't have legislation, rules, inspection or any other regulatory instruments. 2. There is only school for nurses, we have no special school for medical technician. So, we need an education in that field. 3. Very small number of physicist in hospital, no education for medical and nuclear medicine physicist. Conclusion. Situation in Department of Nuclear Medicine in Banja Luka related to quality control is on the medium level. We are trying to put that on the higher level, but to accomplish that we need additional education for nurses (technicians) and physicist.

Radiopharmaceutical prescription in nuclear medicine departments; La prescription medicale des radiopharmaceutiques au sein d'un service de medecine nucleaire

Energy Technology Data Exchange (ETDEWEB)

Biechlin-Chassel, M.L. [Radiopharmacie, service de pharmacie, Centre hospitalier de Chambery, 73 - Chambery (France); Lao, S. [Service de medecine nucleaire, CHU-Hopital de l' Archet, 06 - Nice (France); Bolot, C. [Service de pharmacie, hospices civiles de Lyon, groupement hospitalier Est, 69 - Bron (France); Francois-Joubert, A. [Service de medecine nucleaire, centre hospitalier de Chambery, 73 - Chambery (France)

2010-11-15

In France, radiopharmaceutical prescription is often discussed depending to which juridical structure the nuclear medicine department is belonging. According to current regulation, this prescription is an obligation in a department linked to hospital with a pharmacy department inside. But situation remains unclear for independent nuclear medicine departments where physicians are not constrained to prescribe radiopharmaceuticals. However, as radiographers and nurses are only authorized to realize theirs acts in front of a medical prescription, one prescription must be realized. Nowadays, computerized prescription tools have been developed but only for radiopharmaceutical drugs and not for medical acts. In the aim to achieve a safer patient care, the prescription regulation may be applied whatever differences between nuclear medicines departments. (authors)

Integration of PACS and HIS info the workflow of a nuclear medicine department. Experience in Regensburg

International Nuclear Information System (INIS)

Maenner, P.; Fuchs, E.; Marienhagen, J.; Schoenberger, J.; Eilles, C.; Tege, B.; Reicherzer, H.G.; Kurz, M.; Boerner, W.

2006-01-01

Aim: the development of new diagnostic techniques and the implementation of a modern quality control management system requires the continuous adaptation of existing data processing tools to the nuclear medicine diagnostic workflow. Furthermore, PACS connected to HIS facilitates and enhances the transfer of data and pictures, and satisfies the legal requirements for data retention as regulated by law. Therefore, the aim of this work is to present the architecture, structure and results of such a system newly installed in a department of nuclear medicine. Methods: initially, the nuclear medicine workflow was carefully analyzed and each step was correlated to the corresponding module. The standard SAP R/3 and IS-H / IS-H*med based software used for patient administration at the University of Regensburg Hospital was adapted to the needs of the Nuclear Medicine Department. The networking of the imaging systems was done by integration of a PACS. Finally, the PACS was connected to the HIS to allow the attachment of images to the medical report. Results, conclusion: by connecting the HIS to the nuclear medicine PACS, the workflow was significantly improved. The data management sequence starting at the reception desk, continuing through the nuclear medical examination, to the physician's final written and image report is clearly structured. Although high demands exist on technical support and administration the integration of PACS and HIS into the nuclear medicine workflow leads to enhanced efficiency and reduction in hospital costs. Patient and data management are considerably improved in this way. (orig.)

Nuclear medicine

International Nuclear Information System (INIS)

Chamberlain, M.J.

1986-01-01

Despite an aggressive, competitive diagnostic radiology department, the University Hospital, London, Ontario has seen a decline of 11% total (in vivo and in the laboratory) in the nuclear medicine workload between 1982 and 1985. The decline of in vivo work alone was 24%. This trend has already been noted in the U.S.. Nuclear medicine is no longer 'a large volume prosperous specialty of wide diagnostic application'

The nuclear medicine department in the emergency management plan: a referent structure for the nuclear and radiological risks

International Nuclear Information System (INIS)

Barat, J.L.; Ducassou, D.; Lesgourgues, P.; Zamaron, S.; Boulard, G.

2006-01-01

Each french public or private hospital has to establish guidelines for an immediate response to mass casualties (Emergency Management Plan or 'White' Plan). For a nuclear accident or terrorist attack, the staff of the Nuclear Medicine Department may be adequately prepared and equipped. This paper presents the nuclear and radiological risks section of the final draft of the White Plan developed at Bordeaux University Hospital. (author)

Radiation doses of employees of a nuclear medicine department after implementation of more rigorous radiation protection methods

International Nuclear Information System (INIS)

Piwowarska-Bilska, H.; Supinska, A.; Listewnik, M. H.; Zorga, P.; Birkenfeld, B.

2013-01-01

The appropriate radiation protection measures applied in departments of nuclear medicine should lead to a reduction in doses received by the employees. During 1991-2007, at the Department of Nuclear Medicine of Pomeranian Medical University (Szczecin, Poland), nurses received on average two-times higher (4.6 mSv) annual doses to the whole body than those received by radiopharmacy technicians. The purpose of this work was to examine whether implementation of changes in the radiation protection protocol will considerably influence the reduction in whole-body doses received by the staff that are the most exposed. A reduction in nurses' exposure by ∼63% took place in 2008-11, whereas the exposure of radiopharmacy technicians grew by no more than 22% in comparison with that in the period 1991-2007. Proper reorganisation of the work in departments of nuclear medicine can considerably affect dose reduction and bring about equal distribution of the exposure. (authors)

Fundamentals of nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Alazraki, N.P.; Mishkin, F.S.

1984-01-01

This guidebook for clinical nuclear medicine is written as a description of how nuclear medicine procedures should be used by clinicians in evaluating their patients. It is designed to assist medical students and physicians in becoming acquainted with nuclear medicine techniques for detecting and evaluating most common disorders. The material provides an introduction to, not a textbook of, nuclear medicine. Each chapter is devoted to a particular organ system or topic relevant to the risks and benefits involved in nuclear medicine studies. The emphasis is on presenting the rationales for ordering the various clinical imaging procedures performed in most nuclear medicine departments. Where appropriate, alternative imaging modalities including ultrasound, computed tomography imaging, and radiographic special procedures are discussed. Comparative data between nuclear medicine imaging and other modalities are presented to help guide the practicing clinician in the selection of the most appropriate procedure for a given problem.

Nuclear Medicine in Turkey

International Nuclear Information System (INIS)

Durak, H.

2001-01-01

Nuclear Medicine is a medical specialty that uses radionuclides for the diagnosis and treatment of diseases and it is one of the most important peaceful applications of nuclear sciences. Nuclear Medicine has a short history both in Turkey and in the world. The first use of I-131 for the treatment of thyrotoxicosis in Turkey was in 1958 at the Istanbul University Cerrahpasa Medical School. In 1962, Radiobiological Institute in Ankara University Medical School was established equipped with well-type counters, radiometers, scalers, external counters and a rectilinear scanner. In 1965, multi-probe external detection systems, color dot scanners and in 1967, anger scintillation camera had arrived. In 1962, wet lab procedures and organ scanning, in 1965 color dot scanning, dynamic studies (blood flow - renograms) and in 1967 analogue scintillation camera and dynamic camera studies have started. In 1974, nuclear medicine was established as independent medical specialty. Nuclear medicine departments have started to get established in 1978. In 1974, The Turkish Society of Nuclear Medicine (TSNM) was established with 10 members. The first president of TSNM was Prof. Dr. Yavuz Renda. Now, in the year 2000, TSNM has 349 members. Turkish Society of Nuclear Medicine is a member of European Association of Nuclear Medicine (EANM), World Federation of Nuclear Medicine and Biology (WFNMB) and WFNMB Asia-Oceania. Since 1974, TSNM has organized 13 national Nuclear Medicine congresses, 4 international Nuclear Oncology congresses and 13 nuclear medicine symposiums. In 1-5 October 2000, 'The VII th Asia and Oceania Congress of Nuclear Medicine and Biology' was held in Istanbul, Turkey. Since 1992, Turkish Journal of Nuclear Medicine is published quarterly and it is the official publication of TSNM. There are a total of 112 Nuclear Medicine centers in Turkey. There are 146 gamma cameras. (52 Siemens, 35 GE, 16 Elscint, 14 Toshiba, 10 Sopha, 12 MIE, 8 Philips, 9 Others) Two cyclotrons are

The main rules regarding the management of solid waste and liquid effluent contaminated during use at nuclear medicine departments

International Nuclear Information System (INIS)

Boudouin, E.

2011-01-01

This article describes the key requirements applicable to the management of contaminated medical waste and effluent from hospitals and health care centres, and more especially from nuclear medicine departments that use radionuclides for the purposes of diagnosis (in vivo or in vitro) or in patient treatment. It also presents the key management regulations, making a distinction between contaminated solid waste and contaminated liquid waste from such nuclear medicine departments. (author)

Java-based remote viewing and processing of nuclear medicine images: toward "the imaging department without walls".

Science.gov (United States)

Slomka, P J; Elliott, E; Driedger, A A

2000-01-01

In nuclear medicine practice, images often need to be reviewed and reports prepared from locations outside the department, usually in the form of hard copy. Although hard-copy images are simple and portable, they do not offer electronic data search and image manipulation capabilities. On the other hand, picture archiving and communication systems or dedicated workstations cannot be easily deployed at numerous locations. To solve this problem, we propose a Java-based remote viewing station (JaRViS) for the reading and reporting of nuclear medicine images using Internet browser technology. JaRViS interfaces to the clinical patient database of a nuclear medicine workstation. All JaRViS software resides on a nuclear medicine department server. The contents of the clinical database can be searched by a browser interface after providing a password. Compressed images with the Java applet and color lookup tables are downloaded on the client side. This paradigm does not require nuclear medicine software to reside on remote computers, which simplifies support and deployment of such a system. To enable versatile reporting of the images, color tables and thresholds can be interactively manipulated and images can be displayed in a variety of layouts. Image filtering, frame grouping (adding frames), and movie display are available. Tomographic mode displays are supported, including gated SPECT. The time to display 14 lung perfusion images in 128 x 128 matrix together with the Java applet and color lookup tables over a V.90 modem is remote nuclear medicine viewing station using Java and an Internet or intranet browser. Images can be made easily and cost-effectively available to referring physicians and ambulatory clinics within and outside of the hospital, providing a convenient alternative to film media. We also find this system useful in home reporting of emergency procedures such as lung ventilation-perfusion scans or dynamic studies.

Effect of usual lead apron in decreasing dose rate in nuclear medicine department

Energy Technology Data Exchange (ETDEWEB)

Momennezhad, M.; Ghazikhanloo, K.; Zakavi, S.R. [Mashhad Univ. of Medical Sciences (Iran, Islamic Republic of)

2006-07-01

Full text of publication follows: Introduction: In a busy nuclear medicine department personnel exposure to radiation is inevitable during patient positioning and radiotracer preparation. There is controversy regarding usage of usual lead aprons with respect to penetrating gamma rays used in nuclear medicine departments as well as production of characteristic lead x-ray from aprons.This study tries to evaluate the effect of 0.5 mm lead apron on dose reduction. Methods and materials: We used three point sources usual radioisotopes used in nuclear medicine departments (99 mTc, 201 Tl and 131 I) and a single head L.F.O.V. gamma camera (S.M.V., D.S.X.) was used for counting purposes. The count rate for each source was about 20 K count/sec in air and in a brain water phantom. All point sources were placed at a distance of 3 meters, parallel to the center of the detector. The collimator was removed and imaging was performed for 1 min with and without lead apron on the detector. Lead apron covered all field of view of the detector. Each imaging was repeated 3 times and mean count was obtained for each radioisotope. The measurements were accomplished from full spectrum and specific region of spectrum such as characteristic lead x rays region (88 keV 20%) with and without apron. Result and Discussion: The measurement and comparison of count rates (count/min) for each source in different conditions (with and without apron source in air and in water phantom) showed that count rates were reduced in air about 77.3%, 84.2% and 40.8% for 99 mTc, 201 Tl and 131 I respectively. The reduction in count rates when sources placed in brain water phantom were 83.5%, 87% and 53.7% for the same isotope respectively. As the main source of radiation for personnel is from scattered photon and with respect to about 83% of count rate reduction using lead aprons for 99 mTc, it is expected that wearing lead apron significantly decrease dose rate. Conclusion: Our study showed that lead aprons

Effect of usual lead apron in decreasing dose rate in nuclear medicine department

International Nuclear Information System (INIS)

Momennezhad, M.; Ghazikhanloo, K.; Zakavi, S.R.

2006-01-01

Full text of publication follows: Introduction: In a busy nuclear medicine department personnel exposure to radiation is inevitable during patient positioning and radiotracer preparation. There is controversy regarding usage of usual lead aprons with respect to penetrating gamma rays used in nuclear medicine departments as well as production of characteristic lead x-ray from aprons.This study tries to evaluate the effect of 0.5 mm lead apron on dose reduction. Methods and materials: We used three point sources usual radioisotopes used in nuclear medicine departments (99 mTc, 201 Tl and 131 I) and a single head L.F.O.V. gamma camera (S.M.V., D.S.X.) was used for counting purposes. The count rate for each source was about 20 K count/sec in air and in a brain water phantom. All point sources were placed at a distance of 3 meters, parallel to the center of the detector. The collimator was removed and imaging was performed for 1 min with and without lead apron on the detector. Lead apron covered all field of view of the detector. Each imaging was repeated 3 times and mean count was obtained for each radioisotope. The measurements were accomplished from full spectrum and specific region of spectrum such as characteristic lead x rays region (88 keV 20%) with and without apron. Result and Discussion: The measurement and comparison of count rates (count/min) for each source in different conditions (with and without apron source in air and in water phantom) showed that count rates were reduced in air about 77.3%, 84.2% and 40.8% for 99 mTc, 201 Tl and 131 I respectively. The reduction in count rates when sources placed in brain water phantom were 83.5%, 87% and 53.7% for the same isotope respectively. As the main source of radiation for personnel is from scattered photon and with respect to about 83% of count rate reduction using lead aprons for 99 mTc, it is expected that wearing lead apron significantly decrease dose rate. Conclusion: Our study showed that lead aprons

Extracts from IAEA's Resources Manual in Nuclear Medicine. Part-3: Establishing Nuclear Medicine Services

International Nuclear Information System (INIS)

2003-01-01

In the past, consideration was given to the categories of nuclear medicine ranging from simple imaging or in-vitro laboratories, to more complex departments performing a full range of in-vitro and in-vivo procedures that are also involved in advanced clinical services, training programmes, research and development. In developing countries, nuclear medicine historically has often been an offshoot of pathology, radiology or radiotherapy services. These origins are currently changing as less radioimmunoassay is performed and fully-fledged, independent departments of nuclear medicine are being set up. The trend appears to be that all assays (radioassay or ELISA) are done in a biochemistry laboratory whereas nuclear medicine departments are involved largely in diagnostic procedures, radionuclide therapy and non-imaging in-vitro tests. The level of nuclear medicine services is categorized according to three levels of need: Level 1: Only one gamma camera is needed for imaging purposes. The radiopharmaceutical supply, physics and radiation protection services are contracted outside the centre. Other requirements include a receptionist and general secretarial assistance. A single imaging room connected to a shared reporting room should be sufficient, with a staff of one nuclear medicine physician and one technologist, with back-up. This level is appropriate for a small private practice. Level 2: This is suitable for a general hospital where there are multiple imaging rooms where in-vitro and other non-imaging studies would generally be performed as well as radionuclide therapy. Level 3: his is appropriate for an academic institution where there is a need for a comprehensive clinical nuclear medicine service, human resource development and research programmes. Radionuclide therapy for in-patients and outpatients is provided

Air contamination measurements for the evaluation of internal dose to workers in nuclear medicine departments

Science.gov (United States)

De Massimi, B.; Bianchini, D.; Sarnelli, A.; D'Errico, V.; Marcocci, F.; Mezzenga, E.; Mostacci, D.

2017-11-01

Radionuclides handled in nuclear medicine departments are often characterized by high volatility and short half-life. It is generally difficult to monitor directly the intake of these short-lived radionuclides in hospital staff: this makes measuring air contamination of utmost interest. The aim of the present work is to provide a method for the evaluation of internal doses to workers in nuclear medicine, by means of an air activity sampling detector, to ensure that the limits prescribed by the relevant legislation are respected. A continuous air sampling system measures isotope concentration with a Nal(TI) detector. Energy efficiency of the system was assessed with GEANT4 and with known activities of 18F. Air is sampled in a number of areas of the nuclear medicine department of the IRST-IRCCS hospital (Meldola- Italy). To evaluate committed doses to hospital staff involved (doctors, technicians, nurses) different exposure situations (rooms, times, radionuclides etc) were considered. After estimating the intake, the committed effective dose has been evaluated, for the different radionuclides, using the dose coefficients mandated by the Italian legislation. Error propagation for the estimated intake and personal dose has been evaluated, starting from measurement statistics.

Data processing equipment of a Nuclear Medicine Department in 1980 - Introductory Report

International Nuclear Information System (INIS)

Itti, R.; Liehn, J.C.; Valeyre, J.

1979-01-01

A brief history enables the place taken by computers in nuclear medicine to be situated. Three stages are involved: at first, the quantitative functional studies developed (radioisotopic uptake curves) then the morphological studies with the research into increasingly efficient pictures systems and the introduction of data processing to improve the quality of the pictures and, finally, the digital analysis of the pictures leading to the build-up of regional physiological studies. The part played by computer systems in a Nuclear Medicine Department is summarized. The main advantages are emphasized and present possibilities are indicated. The components which make it possible to design a future acquisition and data processing system that may be used not only for routine practice examinations but also for axial scanning studies by emission are presented. The application of hyper-specialized systems using microprocessors is also under consideration [fr

Analysis of radiation doses to patients from diagnostic department of nuclear medicine

International Nuclear Information System (INIS)

Lepej, L.; Messingerova, M.

1995-01-01

In this paper the values of mean effective dose equivalents per unit activity (H E/1Bq ) were used for the calculation of mean effective dose equivalents for one examination (H E ). The collective effective dose equivalents for each radiopharmaceutical and type of examination (S ER ) and global collective effective dose equivalent for department for all radiopharmaceuticals (S E ) during evaluated period were defined. The data for years from 1992 to 1994 were evaluated and compared with results in literature. The evaluation of radiation doses in nuclear medicine department is useful parameter for internal quality control. Using this method, the radiation dose in this laboratory was changed to minimum (under mean value of Slovak Republic). Unfortunately, the real data of patients radiation doses are different from the calculated one. Due to different kinetic of radiopharmaceuticals in individual patients (influenced by pathology, age, etc.) the evaluation of radiation burden to nuclear medicine patients is problematic. But this approach enable the relative comparison of the changes in values of H E and S E during the observed period. The evaluation of individual (minimal) effective dose equivalent - (H min ) which represents dose calculated under physiologic conditions can be useful for indication of diagnostic examination by physicians. Therefore the systematic registration of H min from all examinations - patient's radiation history. This is specially important in the case of children and young people. The importance of the proposed method, is in regulation of radiation dose from nuclear medicine diagnostic examinations, not only be the control of number and type of examinations, but also by selection of used radiopharmaceuticals and by the way how to use them. (J.K.) 1 fig., 2 refs

Nuclear Medicine in a developing country

International Nuclear Information System (INIS)

Wenzel, K.S. von; Rubow, S.M.; Ellmann, A.; Ghoorun, S.

2002-01-01

Namibia is a country with 1,8 million inhabitants, of whom the majority has limited access to first world facilities. Nevertheless, medical services of high standard are offered. A Nuclear Medicine Department was established at Windhoek Central Hospital in 1982. A nuclear physician, two nuclear medicine radiographers and a nursing sister staff the department. Equipment includes a Siemens Orbiter and an Elscint Apex SPX Helix gamma camera. Radiopharmaceuticals are obtained from suppliers in South Africa. Investigations performed include musculoskeletal, liver, hepatobiliary, thyroid, renal studies, ventilation perfusion lung scans as well as the following Nuclear Cardiology studies: Gated blood pool scans, Tc-99m pyrophosphate hot spot scans, Tl-201 myocardial perfusion studies, Tc-99m MIBI myocardial perfusion studies and Tl-201 rest-redistribution studies. Problems experienced at the Windhoek Nuclear Medicine department include: Lack of funding and high cost of equipment and radiopharmaceuticals, lack of understanding of Nuclear Medicine by the hospital management and health administrators, and difficulties in procuring short-lived radiopharmaceuticals. Furthermore, the absence of company representatives and spare parts in Namibia leads to loss of time whenever equipment needs to be repaired. Working as the only nuclear medicine physician in a country also poses major problems. Careful management of resources and information drives have helped to sustain the Nuclear Medicine service despite economic problems in the country. Installation of a tele-link between the department in Windhoek Hospital and Tygerberg Hospital in South Africa has greatly assisted to overcome the problem of isolation and lack of back up from fellow specialists. The IAEA has equipped both departments with Hermes workstations (Nuclear Diagnostics) and a tele-link is maintained via modem. The current software provided with the Hermes system is ideally suited to processing of data such as gated

Beijing nuclear medicine survey 2005: general information

International Nuclear Information System (INIS)

Geng Jianhua; Si Hongwei; Chen Shengzu

2008-01-01

Objective: To evaluate the status of nuclear medicine department in Beijing area. Methods: Staff, equipment and clinical applications of nuclear medicine departments in Beijing area during 2005 were evaluated by postal questionnaires. Results: Thirty nuclear medicine departments responded to our survey. In these departments, 321 staff, 141 doctors, 122 technicians, 7 physicists, 22 nurses and 29 other staff were employed; and 41 large imaging equipments, 37 SPECT, 3 PET, 1 PET-CT were equipped. During 2005, 88135 radionuclide imaging (84734 for SPECT, 3401 for PET), 462246 radioimmunoassay and 2228 radionuclide therapies (the most for Graves' disease, the second for thyroid cancer, the third for bone metastasis) were performed. For only 41.5% and 22.0% equipments the daily quality control (QC) and weekly QC were conducted. Conclusions Staff, equipments and activities of nuclear medicine department in Beijing were in a considerable scale, but did not balance among hospitals. Most departments should increase the number of physicists and the equipment QC procedures to improve the image quality. (authors)

Radiation hazards in the nuclear medicine

International Nuclear Information System (INIS)

Roo, M.J.K. de

1981-01-01

After a survey of the actual situation of nuclear medicine in Belgium, the evolution of nuclear medicine is studied with regard to quantitative aspects (tracerquantities, number of radioisotopic explorations, number of certified doctors) and qualitative aspects (use of short living isotopes emitting low energy radiation, introduction of in vitro tests). Taking these data into consideration, the exposure of nuclear medicine staff by external or internal radiation is evaluated. From this study it appears that the radiation exposure of the personnel of nuclear medicine departments remains low if proper manipulation methods and simple protective devices are used and if there is an efficient collaboration with an active health physics department or radiation control organism. (author)

Evaluation of radiation protection in nuclear medicine diagnostic procedures

International Nuclear Information System (INIS)

Mohammed, Ezzeldien Mohammed Nour

2013-05-01

This study conducted to evaluate the radiation protection in nuclear medicine diagnostic procedures in four nuclear medicine departments in Sudan. The evaluated procedures followed in these departments were in accordance with the standards, International Recommendations and code of practice for radiation protection in nuclear medicine. The evolution included the optimum design for diagnostic nuclear medicine departments, dealing with radioactive sources, quality assurance and quality control, training and responsibilities for radiation worker taking into account economic factors in Sudan. Evaluation of radiation protection procedures in diagnostic investigations was carried out by taken direct measurements of dose rate and the contamination level in some areas where radiation sources, radiation workers and public are involved. Designated questionnaires covered thirteen areas of radiation protection based on inspection check list for nuclear medicine prepared by the International Atomic Energy Agency (IAEA) and American Association of Physicist in Medicine (AAPM) were used in the evaluation. This questionnaire has been Filled by Radiation Protection Officer (RPO), nuclear medicine technologist, nuclear medicine specialist in the nuclear medicine departments. Four hospitals, two governmental hospital and two private hospitals, have been assisted, the assessment shows that although the diagnostic nuclear medicine department in Sudan are not applying a fully safety and radiation protection procedures, but the level of radiation dose and the contamination level were found within acceptable limits. The private hospital D scored the higher level of protection (85.25%) while the governmental hospital C scored the lower level of protection (59.02%). Finally, this study stated some recommendations that if implemented could improve the level of radiation protection in nuclear medicine department. One of the most important recommendations is that a proper radiation protection

The medical physicist in a nuclear medicine department; El fisico medico en un departamento de medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Trujillo Z, F.E.; Gomez A, E. [Instituto nacional de Cancerologia, 14000 Mexico D.F. (Mexico)

2007-07-01

The diagnostic studies and therapeutic treatments carried out in a Nuclear Medicine department make use of radioactive material. For such a reason it becomes necessary to take a strict control in the reception, use and waste that are generated of the typical works inside the department. Also, work related with the quality control of the equipment dedicated to produce images and of those not image formers, need to carry out to guarantee its maximum performance; as well as quality of the diagnostic and of the therapy imparted in patients. Additionally its are needed to make originated works of the individual procedures to patient and of the acquisition of radioactive materials and removal of the waste or radioactive contaminations. Presently work the recommendations of the American College of Radiology (ACR), the European Federation of Organizations for Medical Physics (EFOMP) and of the Mexican Official Standards relating to the functions that should be observed in a Nuclear Medicine Department are exposed. The ACR and the EFOMP, conclude in their recommendations that the medical physicist fulfills with the suitable profile and likewise they describe in detail the actions and functions that he should supervise, to carry out, to document and to inform. (Author)

Analysis of radiation doses to patients from diagnostic department of nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Lepej, L; Messingerova, M [F.D. Rosvelt Hospital, Banska Bystrica (Slovakia). Dept. of Nuclear Medicine; Ftacnikova, S [Inst. of Preventive and Clinical Medicine, Bratislava (Slovakia)

1996-12-31

In this paper the values of mean effective dose equivalents per unit activity (H{sub E/1Bq}) were used for the calculation of mean effective dose equivalents for one examination (H{sub E}). The collective effective dose equivalents for each radiopharmaceutical and type of examination (S{sub ER}) and global collective effective dose equivalent for department for all radiopharmaceuticals (S{sub E}) during evaluated period were defined. The data for years from 1992 to 1994 were evaluated and compared with results in literature. The evaluation of radiation doses in nuclear medicine department is useful parameter for internal quality control. Using this method, the radiation dose in this laboratory was changed to minimum (under mean value of Slovak Republic). Unfortunately, the real data of patients radiation doses are different from the calculated one. Due to different kinetic of radiopharmaceuticals in individual patients (influenced by pathology, age, etc.) the evaluation of radiation burden to nuclear medicine patients is problematic. But this approach enable the relative comparison of the changes in values of H{sub E} and S{sub E} during the observed period. The evaluation of individual (minimal) effective dose equivalent - (H{sub min}) which represents dose calculated under physiologic conditions can be useful for indication of diagnostic examination by physicians. Therefore the systematic registration of H{sub min} from all examinations - patient`s radiation history. This is specially important in the case of children and young people. The importance of the proposed method, is in regulation of radiation dose from nuclear medicine diagnostic examinations, not only be the control of number and type of examinations, but also by selection of used radiopharmaceuticals and by the way how to use them. (J.K.) 1 fig., 2 refs.

Coordination compounds in nuclear medicine

International Nuclear Information System (INIS)

Jurisson, S.; Berning, D.; Wei Jia; Dangshe Ma

1993-01-01

Radiopharmaceuticals, drugs containing a radionuclide, are used routinely in nuclear medicine departments for the diagnosis of disease and are under investigation for use in the treatment of disease. Nuclear medicine takes advantage of both the nuclear properties of the radionuclide and the pharmacological properties of the radiopharmaceutical. Herein lies the real strength of nuclear medicine, the ability to monitor biochemical and physiological functions in vivo. This review discusses the coordination chemistry that forms the basis for nuclear medicine applications of the FDA-approved radiopharmaceuticals that are in clinical use, and of the most promising diagnostic and therapeutic radiopharmaceuticals that are in various stages of development. 232 refs

A DICOM based PACS for nuclear medicine

International Nuclear Information System (INIS)

Lassmann, M.; Reiners, C.

2002-01-01

The installation of a radiology information system (RIS) connected to a hospital information system (HIS) and a picture archiving and communications system (PACS) seems mandatory for a nuclear medicine department in order to guarantee a high patient throughput. With these systems a fast transmission of reports, images to the in- and out-patients' wards and private practitioners is realized. Therefore, since April 2000, at the department of nuclear medicine of the university of Wuerzburg a completely DICOM based PACS has been implemented in addition to the RIS. With this system a DICOM based workflow is realized throughout the department of nuclear medicine for reporting and archiving. The PACS is connected to six gamma-cameras, a PET scanner, a bone densitometry system and an ultrasound device. The volume of image data archived per month is 4 GByte. Patient demographics are provided to the modalities via DICOM-Worklist. With these PACS components a department specific archive purely based on DICOM can be realized. During the installation process problems occurred mainly because of the complex DICOM standard for nuclear medicine. Related to that is the problem that most of the software implementations still contain bugs or are not adapted to the needs of a nuclear medicine department (particularly for PET). A communication software for the distribution of nuclear medicine reports and images based on techniques used for the worldwide web is currently tested. (orig.) [de

Study of dose levels absorbed by members of the public in the nuclear medicine departments; Estudo dos niveis de dose em individuos do publico nos servicos de medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Cabral, Geovanna Oliveira de Mello

2001-03-01

In nuclear Medicine, radioisotopes are bound to various compounds (called radiopharmaceuticals) for use in various diagnostic and therapeutic applications. These unsealed sources are administered in various forms to patients, who remain radioactive for hours or days, and represent a source of potential radiation exposure for others. Thus, in nuclear medicine departments, radiation protection of workers and members of the public, especially persons accompanying patients, must consider, this exposure. In Brazil, the Comissao Nacional de Energia Nuclear (CNEN) establishes that, in nuclear medicine departments, the patients and persons accompanying should be separated each other. However, this rule is not always followed due to many factors such as physical and emotional conditions of patients. In this context, the aim of this study was the investigation of dose levels, which the persons accompanying patients are exposed to. For monitoring, thermoluminescent dosimeters were employed. The dosimeters were given to 380 persons who were accompanying patients in nuclear medicine departments. Exposure results were lower than 1 mSv. On the basis of CNEN rules, issues regarding stay conditions for members of the public in these departments are discussed. (author)

Radiation safety in the nuclear medicine department: impact of the UK Ionising Radiations Regulations

International Nuclear Information System (INIS)

Harding, L.K.

1987-01-01

The new 1985 regulations and guidance on radiation protection in the U.K. are discussed in relation to the needs for controlled areas in the nuclear medicine department and patient wards, admittance to hospital to comply with legislation, classification of workers, patient waiting rooms, handling flood sources, pregnancy and breast feeding. (U.K.)

222Radon concentration and irradiation dose inside the department of nuclear medicine in Wuhan

International Nuclear Information System (INIS)

Cheng Xiaoli; Wang Changyin; Gao Jianhua; Zou Xiaofeng

2002-01-01

Objective: Inspecting the high radioactivity area in department of nuclear medicine in Wuhan region and estimating the irradiation dose on relevant doctors. Methods: Select six 'three A' hospitals' high radioactivity area in department of nuclear medicine and common residential houses as examples. A half-year surveillance using 222 Rn detector (type LIH-2) was performed. Results: In high radioactivity rooms, imaging rooms residential houses, the average 222 Rn concentration are 27.8, 48.2, 27.1 (Bq·m -3 ) respectively. Effective dose equivalent absorbed by doctors in high radioactivity room and imaging room are 0.16 and 0.28 mSv. The authors estimated that the effective dose equivalent of doctors in these two room and common residents per year are 0.84, 0.70 and 0.64 mSv respectively. Conclusions: Doctors in imaging room and high radioactivity room are exposed to a relatively higher annual effective dose than common residents. But they are still within the normal range. Only two imaging rooms have high 222 Rn concentrations, which will cause potential harm

Checklists for quality assurance and audit in nuclear medicine

International Nuclear Information System (INIS)

Williams, E.D.; Harding, L.K.; McKillop, J.H.

1989-01-01

A series of checklists are given which aim to provide some guidance to staff in determining whether their working procedures in nuclear medicine are likely to produce a good service and avoid mistakes. The checklists relate to the special equipment used in nuclear medicine departments, radiopharmaceuticals, nuclear medicine staff, services to medical and other hospital staff and finally the service to patients. The checklists are relevant to an average nuclear medicine department performing less than 2000 imaging studies per year. (U.K.)

Evaluation of radiation doses received by the staff in nuclear medicine department of Rick

International Nuclear Information System (INIS)

Ali, Naemat Abdalla Mohamed

2001-01-01

Environmental monitoring in nuclear medicine rooms at Radiation and Isotopes Center Khartoum RICK were carried out using survey meter and thermoluminescent dosimetry. Staff bodies and hands doses measurements are being conducted using thermoluminescent dosimetry. The purpose of the study is to evaluate the radiation received by the staff work in the nuclear medicine department at RICK. Survey meter (RDS-120) and TLD clips of LiF. (Mg.Ti) were used to measure the environment leading of the staff. The associated annual doses have been determined to the staff bodies and hands. It was found that the dose-equivalent rates from bodies and hands of the staff obtained through this work using TLD clips are: nuclear medicine technologist body reading 6.75 mSv per year, physicist body reading 7.89 mSv per year, chemist body reading 6.1 mSv per year, and nurse body reading 8.1 mSv per year. On the other hand the nuclear medicine technologist hands reading 24.19 mSv per year, physicist hands reading 19.15 mSv per year, chemist hands reading 14.616 mSv per year, and nurse hands reading 277.96 mSv per year. All the staff reading in this study agree with the national regulations and international recommendations. It is clear that the dose of nurse hands is the highest one, this is because when they inject the patient with the Tc-99 m they use to spend relatively long time. (Author)

The development of nuclear medicine in Slovenia and Ljubljana; half a century of nuclear medicine in Slovenia

International Nuclear Information System (INIS)

Slavec, Zvonka Zupanic; Gaberscek, Simona; Slavec, Ksenija

2012-01-01

Nuclear medicine began to be developed in the USA after 1938 when radionuclides were introduced into medicine and in Europe after radionuclides began to be produced at the Harwell reactor (England, 1947). Slovenia began its first investigations in the 1950s. This article describes the development of nuclear medicine in Slovenia and Ljubljana. The first nuclear medicine interventions were performed in Slovenia at the Internal Clinic in Ljubljana in the period 1954–1959. In 1954, Dr Jože Satler started using radioactive iodine for thyroid investigations. In the same year, Dr Bojan Varl, who is considered the pioneer of nuclear medicine in Slovenia, began systematically introducing nuclear medicine. The first radioisotope laboratories were established in January 1960 at the Institute of Oncology and at the Internal Clinic. Under the direction of Dr. Varl, the laboratory at the Internal Clinic developed gradually and in 1973 became the Clinic for Nuclear Medicine with departments for in vivo and in vitro diagnostics and for the treatment of inpatients and outpatients at the thyroid department. The Clinic for Nuclear Medicine became a teaching unit of the Medical Faculty and developed its own post-graduate programme – the first student enrolled in 1972. In the 1960s, radioisotope laboratories opened in the general hospitals of Slovenj Gradec and Celje, and in the 1970s also in Maribor, Izola and Šempeter pri Novi Gorici. Nowadays, nuclear medicine units are modernly equipped and the staff is trained in morphological, functional and laboratory diagnostics in clinical medicine. They also work on the treatment of cancer, increased thyroid function and other diseases

Radiation protection on nuclear medicine services

International Nuclear Information System (INIS)

Anon

2000-01-01

Nuclear medicine is a sector of the medicine that studies and applies radionuclide in diagnosis and therapy. Nuclear medicine is a very specific area of the medicine, making use of non-sealed radioactive sources which are prescribed to the patient orally or are injected. Special procedures in radiation protection are required in nuclear medicine to manipulate these kind of sources and to produce technetium-99m through molybdenum generator. The present paper addresses the them radiation protection in a Nuclear Medicine Department (NMD), showing the main requirements of the CNEN- National Commission of Nuclear Energy and the Public Health. Radiation protection procedures adopted in assembling a NMD, as well the daily techniques for monitoring and for individual dosimetry are discussed. Past and present analyses in a level of radiation protection are presented. (author)

Key formal and legal aspects of acquiring radiopharmaceuticals used in nuclear medicine departments

International Nuclear Information System (INIS)

Kapuscinski, J.

2007-01-01

The article presents the key both Polish and EU legal regulation concerning terms and conditions of acquiring radiopharmaceuticals, i.e. isotope labelled compounds used for diagnostic and/ therapeutic purposes in nuclear medicine departments. The emphasis was put on the requirements regarding provision of the medicaments' safety in broad meaning of the term, which are important factors in providing patients' safety. Legal acts discussed in the article remain valid as of May 2007. (author)

Experience with Nuclear Medicine Information System

Directory of Open Access Journals (Sweden)

Bilge Volkan-Salanci

2012-12-01

Full Text Available Objective: Radiology information system (RIS is basically evolved for the need of radiologists and ignores the vital steps needed for a proper work flow of Nuclear Medicine Department. Moreover, CT/MRI oriented classical PACS systems are far from satisfying Nuclear Physicians like storing dynamic data for reprocessing and quantitative analysis of colored images. Our purpose was to develop a workflow based Nuclear Medicine Information System (NMIS that fulfills the needs of Nuclear Medicine Department and its integration to hospital PACS system. Material and Methods: Workflow in NMIS uses HL7 (health level seven and steps include, patient scheduling and retrieving information from HIS (hospital information system, radiopharmacy, acquisition, digital reporting and approval of the reports using Nuclear Medicine specific diagnostic codes. Images and dynamic data from cameras of are sent to and retrieved from PACS system (Corttex© for reprocessing and quantitative analysis. Results: NMIS has additional functions to the RIS such as radiopharmaceutical management program which includes stock recording of both radioactive and non-radioactive substances, calculation of the radiopharmaceutical dose for individual patient according to body weight and maximum permissible activity, and calculation of radioactivity left per unit volume for each radionuclide according their half lives. Patient scheduling and gamma camera patient work list settings were arranged according to specific Nuclear Medicine procedures. Nuclear Medicine images and reports can be retrieved and viewed from HIS. Conclusion: NMIS provides functionality to standard RIS and PACS system according to the needs of Nuclear Medicine. (MIRT 2012;21:97-102

Radiation exposure of workers in nuclear medicine

International Nuclear Information System (INIS)

Bujnova, A.

2008-01-01

Nuclear medicine is an interdisciplinary department that deals with diagnosis and therapy using open sources. Therefore workers in nuclear medicine are in daily contact with ionizing radiation and thus it is essential to monitor a radiation load. Each work must therefore carry out monitoring of workers. It monitors compliance with the radiation limits set by law, allows an early detection of deviations from normal operation and to demonstrate whether the radiation protection at the workplace is optimized. This work describes the principles of monitoring of workers in nuclear medicine and monitoring methods for personal dosimetry. In the next section the author specifically deals with personal dosimetry at the Department of Nuclear Medicine St. Elizabeth Cancer Institute, Bratislava (KNM-Ba-OUSA). The main part of the work is to evaluate the results of a one-year monitoring of radiation workers KNM-Ba-OUSA. (author)

Environmental dose in the Nuclear Medicine Department of the National Institute of Cancer

International Nuclear Information System (INIS)

Torres U, C. L.; Avila A, O. L.; Medina V, L. A.; Buenfil B, A. E.; Brandan S, M. E.; Trujillo Z, F. E.; Gamboa de Buen, I.

2009-01-01

The dosimeters TLD-100 and TLD-900 were used to know the levels of environmental dose in areas of the Nuclear Medicine Department of the National Institute of Cancer. The dosimeters calibration was carried out in the Metrology Department of the National Institute of Nuclear Research. The radioisotopes used in the studied areas are 131 I, 18 F, 67 Ga, 99m Tc, 111 In, 201 Tl and 137 Cs with gamma energies between 93 and 662 KeV. Dosimeters were placed during five months in the diagnostic, injection, waiting and PET rooms as well as hot room, waste room, enclosed corridors to patient rooms treated with 131 I and 137 Cs and witness dosimeters to know the bottom. The values found vary between 0.3 and 70 major times that those of bottom. The maximum doses were measured in the waste room and in the enclosed corridor to the patient rooms with cervical uterine cancer treated with 137 Cs. (Author)

Nuclear Medicine

Science.gov (United States)

... Parents/Teachers Resource Links for Students Glossary Nuclear Medicine What is nuclear medicine? What are radioactive tracers? ... funded researchers advancing nuclear medicine? What is nuclear medicine? Nuclear medicine is a medical specialty that uses ...

Occupational exposure at the Department of Nuclear Medicine as a work environment: A 19-year follow-up

International Nuclear Information System (INIS)

Piwowarska-Bilska, H.; Birkenfeld, B.; Gwardys, A.; Listewnik, M. H.; Elbl, B.; Cichon-Bankowska, K.; Supinska, A.

2011-01-01

Background: This study assessed the radiation safety at Nuclear Medicine Department being a work environment. Ionizing radiation exposure of the employees in the last 19 years and the effects of legislative changes in radiological protection were analyzed. Material/Methods: All employees of the investigated department were regularly and individually monitored using chest badges equipped with Kodak film type 2. Overall, 629 annual doses of the employees of nuclear medicine department, registered in the period 1991 - 2009, were analyzed statistically. Results: Technicians were found to be the largest exposed professional group, whereas nurses received the highest annual doses. Physicians received an average annual dose at the border detection methods. Ancillary and administration staff occasionally received doses above the method detection limit (MDL). The average annual dose for all dosimetry records was 0.7 mSv, and that for dosimetry records equal and higher than MDL was 2.2 mSv. Conclusions: There was no case of an exceeded dose limit for a worker. Furthermore, improvement of radiological protection had a significant impact on the reduction of doses for the most exposed employees. (authors)

Evaluation of the radiological protection in several departments of nuclear medicine

International Nuclear Information System (INIS)

Lopez Bejerano, G.; Jova Sed, L.

2001-01-01

For the evaluation of radiation protection, in several departments of nuclear medicine a survey was elaborated and applied that includes mainly: aspects of the licence and compliance with the requirements settled down in this, the program of individual radiological surveillance and their evaluation, functions that it completes the service of radiation protection, training program and the personnel's training, equipment and means of radiation protection, radiological surveillance program of the work areas, characteristics of the installation, radioactive waste management, quality assurance program, relative aspects to radiation protection in the procedures of diagnoses, as well as to pregnant patients and those related with the investigation of accidental medical exposures. The work makes a systematization and discussion of the state of compliance of the radiation protection requirements reflected in the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS) and the main recommendations are exposed to achieve in these departments the optimization of the radiation protection. (author)

[Costing nuclear medicine diagnostic procedures].

Science.gov (United States)

Markou, Pavlos

2005-01-01

To the Editor: Referring to a recent special report about the cost analysis of twenty-nine nuclear medicine procedures, I would like to clarify some basic aspects for determining costs of nuclear medicine procedure with various costing methodologies. Activity Based Costing (ABC) method, is a new approach in imaging services costing that can provide the most accurate cost data, but is difficult to perform in nuclear medicine diagnostic procedures. That is because ABC requires determining and analyzing all direct and indirect costs of each procedure, according all its activities. Traditional costing methods, like those for estimating incomes and expenses per procedure or fixed and variable costs per procedure, which are widely used in break-even point analysis and the method of ratio-of-costs-to-charges per procedure may be easily performed in nuclear medicine departments, to evaluate the variability and differences between costs and reimbursement - charges.

Equivalent doses of ionizing radiation received by medical staff at a nuclear medicine department

International Nuclear Information System (INIS)

Dziuk, E.; Kowalczyk, A.; Siekierzynski, M.; Jazwinski, J.; Chas, J.; Janiak, M.K.; Palijczuk, D.

2002-01-01

Aim: Total annual activity of I-131 used for the treatment of thyroid disorders at the Dept.of Nuclear Medicine, Central Clinical Hospital, Military University School of Medicine, in Warsaw, Poland, equal to 190 GBq; at the same time, total activity of Tc-99m utilized at the same Department for diagnostic purposes reached 1 TBq. As estimated from the radiometer readings, in extreme cases the equivalent at a couple of measurement points at this Department may exceed 200 mSv per year. Thus, in the present study we aimed to assess the potential risk of the exposure of medical personnel of the Department to ionizing radiation. Material and Methods: Polymethacrylate cases each housing four thermoluminescent dosimeters were continuously worn for one year by the nurses and doctors with the dosimeters being replaced by the new ones every three months. In addition, cases containing thermoluminescent dosimeters (three dosimeters per case) were placed in 20 different measurement points across the Department and the monitoring of the doses was carried out continuously for more than six years (from May 1995 to March 2002). Based on the quarterly readings of the dosimeters, equivalent doses were calculated for both the members of the personnel and the measurement space points. Results: The doses registered in the patient rooms ranged 5 to 90 mSv x y -1 , in the application room 10 to 15 mSv x y -1 , in the laboratory rooms 1.5 to 30 mSv x y -1 , and in the waiting room 2 to 6 mSv x y -1 ; no increment above the background level was detected in the nurses' station. Accordingly, the annual doses calculated from the dosimeters worn by the staff ranged 0.2 to 1.1 mSv x y -1 ; these latter findings were confirmed by direct readings from individual film dosimeters additionally worn by the staff members. Conclusion: The obtained results indicate that it is unlikely for the personnel of the monitored Nuclear Medicine Department to receive doses of radiation exceeding 40% of the annual

Nuclear medicine: the Philippine Heart Center experience

International Nuclear Information System (INIS)

Cancino, E.L.

1994-01-01

The following is a report of a three (3) months on-the-job training in Nuclear Medicine at the Nuclear Medicine Department of the Philippine Heart Center. The hospital has current generation nuclear medicine instruments with data processor and is capable of a full range of in vivo and in vitro procedures. Gamma camera is the principal instrument for imaging in nuclear medicine used in the Philippine Heart Center. Thyroid scanning procedure is being performed with these instruments. Also the cardiovascular procedures, the pulmonary, skeletal, renal and hepatobiliary procedures were being performed with the use of gamma camera. Special emphasis is on nuclear cardiology since the PHC attends primarily to cardiovascular patients. (auth.)

Czechoslovak nuclear medicine, development and present state

Energy Technology Data Exchange (ETDEWEB)

Hupka, S [Ustav Klinickej Onkologie, Bratislava (Czechoslovakia)

1981-01-01

The growth is described of nuclear medicine departments and units in Czechoslovakia in the past 25 years of the existence of the Czechoslovak Society for Nuclear Medicine and Radiation Hygiene, the numbers of personnel and their qualifications. While only three nuclear medicine units were involved in the use of radioisotopes for diagnostic and therapeutic purposes in the 1950's, 29 specialized departments and 15 laboratories are now in existence with a staff of 299 medical doctors and other university graduates and 365 technicians and nurses. They operate all possible instruments, from simple detector devices via gamma cameras to computer tomographs. Briefly, the involvement of the Society is described in coordinated research programs, both with institutions in the country and with the other CMEA countries and IAEA.

Code of practice for radiation protection in nuclear medicine

International Nuclear Information System (INIS)

Hamed, M. I.

2010-05-01

In aim of this study was to develop a draft for a new code practice for radiation protection in nuclear medicine that meets the current relevant international recommendation. The draft includes the following main fields: methods of radiation protection for workers, patients and public. Also, the principles of safe design of nuclear medicine departments, quality assurance program, proper manipulation of radiation sources including radioactive waste and emergency preparedness and response. The practical part of this study includes inspections of three nuclear medicine departments available in Sudan so as to assess the degree of compliance of those departments with what is stated in this code. The inspection missions have been conducted using a checklist that addresses all items that may affect radiation raincoat issues in addition to per formin area radiation monitoring around the installation of the radioactive sources. The results of this revealed that most of the departments do not have effective radiation protection program which in turn could lead to unnecessary exposure to patients, public and workers. Finally, some recommendations are given that - if implemented - could improve the status of radiation protection in nuclear medicine department. (Author)

Establishment of national diagnostic reference level for renal doses in nuclear medicine departments at Khartoum-Sudan

International Nuclear Information System (INIS)

Alameen, Suhaib; Hamid, Alhadi; Rushdi, M. A. H.

2016-01-01

In this work we established a diagnostic reference level (DRL) for patient dose focusing on the investigation of activity to the kidneys during(99mTc-DTPA) kidney scan, selected two department nuclear medicine in main hospitals in Khartoum state. The DRLs is an investigational level used to identify unusually high radiation doses for common diagnostic medical in Nuclear Medicine procedures and suggested action levels above which a facility should review its methods and determine if acceptable image quality can be achieved at lower doses. The high specific activity of 99mTc makes it suitable as a first pass agent, for multiple or sequential studies, 99mTc diethylenetriaminepentaacetic acid (DTPA) is preferred to 99mTc-pertechnetate. Patients who had been prepared for the kidney scan 99mTc- DTPA were divided to three groups. The first group received dose less than 5 mCi, are represent (27.03%) from all patients, second group received dose 5 to 5.5 mCi are represent(66.67%) and the third group received dose from 5.6 to 6.2 mCi are represent (6.31%) from all patients 99mTc-DTPA. And according to the IAEA recommendation for adult doses(5-10mCi) this study show that about 93.1% of the sample examines by dose less than 5.5 mCi. The results presented will serve as a baseline data needed for deriving reference doses for renal examinations for nuclear medicine departments in Sudan.(Author)

Occupational exposure of nuclear medicine personnel

International Nuclear Information System (INIS)

Roessler, M.

1982-01-01

The results are given of measurements of the radiation burden of personnel in departments of nuclear medicine in the years 1979 to 1981 using film dosemeters and ring thermoluminescence dosemeters evaluated by the national personnel dosemeter service. The relations are examined of the exposure of hands and the preparation of radiopharmaceuticals and especially their use for examinations. Certain organizational measures are indicated for reducina radiation burden in a laboratory for the preparation of radiopharmaceuticals. The results of measurements and evaluations of radiation burden of personnel of nuclear medicine departments are confronted with conclusions published in the literature. (author)

Radiation doses to patients from nuclear medicine examinations

International Nuclear Information System (INIS)

Boehm, K.; Boehmova, I.

2014-01-01

Public Health Authority of the Slovak Republic, Bratislava The exposure of the population to ionizing radiation is rising rapidly, nearly exclusively due to increasing medical use of radiation, including diagnostic methods of nuclear medicine. In 2012 Public health authority of the Slovak republic (PHA SR) performed a survey about the population exposure from nuclear medicine procedures. The primary objectives of this survey were to assess the frequency of different nuclear medicine procedures, determine the average activities administered by nuclear medicine procedures and compare them with the national diagnostic reference levels and determine the annual collective effective dose to the Slovak population from nuclear medicine. The effective dose calculation was based on the methodology of the ICRP32, ICRP80 and ICRP106. In Slovak republic are 11 nuclear medicine departments. The collected data of activities administered by different procedures correspond to 100 % of nuclear medicine departments. The total number of procedures included in the study was 36 250. The most commonly performed procedure was bone scintigraphy (35.9%), followed by lung perfusion and ventilation scintigraphy (17.0%), static and dynamic renal scintigraphy (13.0%), whole-body positron emission tomography of tumors with PET radiopharmaceuticals (11.6%), myocardial perfusion (8.8%), thyroid scintigraphy (6.2%), parathyroid scintigraphy (2.1%), scintigraphy of tumors (2.1%), scintigraphy of the liver and spleen (0.8%), brain perfusion (0.7%) and examination of the gastrointestinal system (0.3%). (authors)

General Nuclear Medicine

Science.gov (United States)

... Resources Professions Site Index A-Z General Nuclear Medicine Nuclear medicine imaging uses small amounts of radioactive ... of General Nuclear Medicine? What is General Nuclear Medicine? Nuclear medicine is a branch of medical imaging ...

Nuclear Medicine National Headquarter System

Data.gov (United States)

Department of Veterans Affairs — The Nuclear Medicine National HQ System database is a series of MS Excel spreadsheets and Access Database Tables by fiscal year. They consist of information from all...

OrdoCMN: a communication tool for nuclear medicine

International Nuclear Information System (INIS)

Lamy, P.; Bizollon, C.; Damien, J.; Itti, R.

1997-01-01

OrdoCMN is a computer software which offers an easy solution for the management of a nuclear medicine department. It has been developed using a data management tool: 4. Dimension. This network based software acts mainly as a communication tool between the various parts of the nuclear medicine department. It provides time saving and optimisation for the interdependent operations which are necessary when performing a scintigraphy study. In addition, it has all the functionalities which are needed to manage the data concerning a scintigraphy examination: study planing, patient files, radiopharmaceuticals prescription edition, labels and report printing, and radiopharmaceuticals management. Centered around the patient's file, it guaranties the confidentiality and security of the informations through several levels of security: passwords, data coding, etc. Since further evolution is specially easy, thanks to its modular structure, it may be adapted to the specific needs of any nuclear medicine department. (authors)

Present situation and proposal for nuclear medicine development

International Nuclear Information System (INIS)

Oliva Gonzalez, Juan P.

2003-01-01

In the present paper, the current situation of the Cuban nuclear medicine, after its introduction in the country in the 40s of the 20 th century and its expansion since 1962 and, particularly, from the installation of the first gamma camera in 1980, is analyzed. Nowadays, there is a total 14 Nuclear Medicine Departments or Services in our country within the National Oncology Networks and national Health System (SNS), which provide medical attention to the population depending on the nuclear equipment available A Program for the medical and technical personnel's training is proposed, as well as for gradual development of nuclear medicine department's (including the installation of gamma cameras, divided into two stages: 2003-2004 and 2005-2006). The prospective results of the proposed program are analyzed, as well as the impact on the populations health

Nuclear medicine

International Nuclear Information System (INIS)

Lentle, B.C.

1986-01-01

Several growth areas for nuclear medicine were defined. Among them were: cardiac nuclear medicine, neuro-psychiatric nuclear medicine, and cancer diagnosis through direct tumor imaging. A powerful new tool, Positron Emission Tomography (PET) was lauded as the impetus for new developments in nuclear medicine. The political environment (funding, degree of autonomy) was discussed, as were the economic and scientific environments

Magistral preparation in nuclear medicine departments: Requirements for their realization

International Nuclear Information System (INIS)

Desruet, M.D.; Bolot, C.; Bourrel, F.; Francois-Joubert, A.; Biechlin-Chassel, M.L.; Couret, I.; Pelegrin, M.; Lao, S.; Ouhayon, E.; Sauvan, R.

2010-01-01

Use of radiopharmaceuticals in French nuclear medicine departments depends on marketing authorization and their development may be compromised by a limited return on investment. As an alternative, radiopharmaceuticals may also be prepared in the form of a magistral preparation, like in some European countries. In this case, these preparations are subjected to restrictions and requirements for radio-pharmacies relating to quality assurance, facilities and equipment, quality of starting materials and final radiopharmaceutical products defined in French good preparation practice. Labelled tracers used as magistral preparations have to be prepared under the full responsibility of a radio-pharmacist and used under the responsibility of the prescribing physician. Conditions of sufficient guarantees for the safety of the patient and adherence to pharmaceutical rules must be evaluated individually. However, this form of preparation intends to supply specific medical needs for an individual patient and is not an answer in the framework of development of radiopharmaceuticals. (authors)

The design of a purpose-built nuclear medicine department

International Nuclear Information System (INIS)

Dixon, J.; Walker, B.

1999-01-01

Full text: In December 1997, the Department of Nuclear Medicine relocated to new purpose-built premises. Two years of detailed planning preceded this move. Several innovative features were incorporated in the design. The 6 gamma camera rooms are arranged in pairs with shared shielded console areas, around a central 'staff-only' corridor with the radiopharmacy dispensing room (RP) at one end. This allows for direct staff access between these rooms while preserving the privacy of the patients. Hatches from the RP to the stress lab and procedures rooms allow for minimal carrying of doses. A separate hotlab adjoining the RP with a dedicated dose calibrator is used for preparations of all therapy doses and 18 F. A 'no return' policy was adopted for the RP. A separate isolated radioactive waste storage room (WSR) has an easily accessible anteroom used only for 99 Tc m , which allows efficient management of this short-lived waste. The nurses' station visualizes all waiting facilities, which include separate areas for trolley and ambulant patients as well as a playroom for the paediatric patients. An area for resting 18 F patients is located away from the general waiting areas and close to the coincidence detection camera room. After 1 year of operation, these specific design features have proved successful. They have led to improvement in the efficiency of operation of the department for the staff and increased comfort for the patients

Dose received by occupationally exposed workers at a nuclear medicine department

Science.gov (United States)

Ávila, O.; Sánchez-Uribe, N. A.; Rodríguez-Laguna, A.; Medina, L. A.; Estrada, E.; Buenfil, A. E.; Brandan, M. E.

2012-10-01

Personal Dose Equivalent (PDE) values were determined for occupational exposed workers (OEW) at the Nuclear Medicine Department (NMD) of "Instituto Nacional de Cancerología" (INCan), Mexico, using TLD-100 thermoluminescent dosemeters. OEW at NMD, INCan make use of radiopharmaceuticals for diagnosis and treatment of diseases. Radionuclides associated to a pharmaceutical compound used at this Department are 131I, 18F, 68Ga, 99mTc, 111In and 11C with main gamma emission energies between 140 and 511 keV. Dosemeter calibration was performed at the metrology department of "Instituto Nacional de Investigaciones Nucleares" (ININ), Mexico. Every occupational worker used dark containers with three dosimeters which were replaced monthly for a total of 5 periods. Additionally, control dosemeters were also placed at a site free of radioactive sources in order to determine the background radiation. Results were adjusted to find PDE/day and estimating annual PDE values in the range between 2 mSv (background) and 9 mSv. The mean annual value is 3.51 mSv and the standard deviation SD is 0.78 mSv. Four of the 16 OEW received annual doses higher than the average +1 SD (4.29 mSv). Results depend on OEW daily activities and were consistent for each OEW for the 5 studied periods as well as with PDE values reported by the firm that performs the monthly service. All obtained values are well within the established annual OEW dose limit stated in the "Reglamento General de Seguridad Radiológica", México (50 mSv), as well as within the lower limit recommended by the "International Commission on Radiation Protection" (ICRP), report no.60 (20 mSv). These results verify the adequate compliance of the NMD at INCan, Mexico with the norms given by the national regulatory commission.

More about ... Nuclear medicine

African Journals Online (AJOL)

Thyroid scintigraphy. In neonates with hypothyroidism detected on neonatal screening and confirmed by subsequent testing, a radionuclide thyroid scan should be performed as soon as possible. It must be undertaken in all nuclear medicine departments as a matter of urgency. Any delay in treatment should be avoided.

Quality management audits in nuclear medicine practices

International Nuclear Information System (INIS)

2008-12-01

An effective management system that integrates quality management (QM) is essential in modern nuclear medicine departments in Member States. The IAEA, in its Safety Standards Series, has published a Safety Requirement (GS-R-3) and a Safety Guide (GS-G-3.1) on management systems for all facilities. These publications address the application of an integrated management system approach that is applicable to nuclear medicine organizations as well. Quality management systems are maintained with the intent to continuously improve effectiveness and efficiency, enabling nuclear medicine to achieve the expectations of its quality policy, and to satisfy its customers. The IAEA has a long history of providing assistance in the field of nuclear medicine to its Member States. Regular quality audits and assessments are essential for modern nuclear medicine departments. More importantly, the entire QM and audit process has to be systematic, patient oriented and outcome based. The management of services should also take into account the diversity of nuclear medicine services around the world and multidisciplinary contributions. The latter include clinical, technical, radiopharmaceutical and medical physics procedures. Aspects of radiation safety and patient protection should also be integral to the process. Such an approach ensures consistency in providing safe, quality and superior services to patients. Increasingly standardized clinical protocol and evidence based medicine is used in nuclear medicine services, and some of these are recommended in numerous IAEA publications, for example, the Nuclear Medicine Resources Manual. Reference should also be made to other IAEA publications such as the IAEA Safety Standards Series, which include the regulations for the safe transport of nuclear material and on waste management as all of these have an impact on the provision of nuclear medicine services. The main objective of this publication is to introduce a routine of conducting an

Measurement of beta emitting radionuclides in dose calibrators routinely used in nuclear medicine departments

International Nuclear Information System (INIS)

Tastan, S.; Soylu, A.; Kucuk, O.; Ibis, E.

2004-01-01

Full text: Radionuclides for diagnostics purposes like Tc-99m, Tl-201, Ga-67 and In-111 are measured by using ionization type of dose calibrators. Therapeutic radionuclides, which emit both beta and gamma rays are detected by the same type of dose calibrators. Other therapeutic products like Y-90, P-32 and Sr-89 are pure beta emitters and they are gaining wider utility because various new therapy radiopharmaceuticals are being developed. The type of container material, like glass or plastic, may seriously affect radioactivity measurement due to attenuation, Since it is crucial to give the exact amount of radioactivity to the patient for therapy purposes, dedicated dose calibrators are specially manufactured for the measurement of these radionuclides. But these measuring systems are not widely available in nuclear medicine centers where therapy is applied to the patient. It is a known fact that dose calibrators routinely used in nuclear medicine departments can be calibrated for vials and syringes using standard sources of the same radioisotope. The method of calibration of Y-90 measurement for two ionization chamber dose calibrators available in the institute will be summarized in this presentation

Measurement of beta emitting radionuclides in dose calibrators routinely used in nuclear medicine departments

International Nuclear Information System (INIS)

Tastan, S.; Soylu, A.; Kucuk, O.; Ibis, E.

2004-01-01

Radionuclides for diagnostics purposes like Tc-99m, Tl-201, Ga-67 and In-111 are measured by using ionization type of dose calibrators. Therapeutic radionuclides, which emit both beta and gamma rays are detected by the same type of dose calibrators. Other therapeutic products like Y-90, P-32 and Sr-89 are pure beta emitters and they are gaining wider utility because various new therapy radiopharmaceuticals are being developed. The type of container material, like glass or plastic, may seriously affect radioactivity measurement due to attenuation, Since it is crucial to give the exact amount of radioactivity to the patient for therapy purposes, dedicated dose calibrators are specially manufactured for the measurement of these radionuclides. But these measuring systems are not widely available in nuclear medicine centers where therapy is applied to the patient. It is a known fact that dose calibrators routinely used in nuclear medicine departments can be calibrated for vials and syringes using standard sources of the same radioisotope. The method of calibration of Y-90 measurement for two ionization chamber dose calibrators available in the institute will be summarized in this presentation. (author)

Links between nuclear medicine and radiopharmacy; Structuration des liens entre medecine nucleaire et radiopharmacie

Energy Technology Data Exchange (ETDEWEB)

Pelegrin, M. [Inserm, U896, CRLC Val-d' Aurelle-Paul-Lamarque, institut de recherche en cancerologie de Montpellier (IRCM), universite Montpellier 1, 34 - Montpellier (France); Francois-Joubert, A. [Service de medecine nucleaire, centre hospitalier de Chambery, 73 - Chambery (France); Chassel, M.L. [Radiopharmacie, service de pharmacie, centre hospitalier de Chambery, 73 - Chambrry (France); Desruet, M.D. [Service de radiopharmacie et service pharmaceutique, clinique universitaire de medecine nucleaire, CHU de Grenoble, 38 - Grenoble (France); Bolot, C. [Service de radiopharmacie, service pharmaceutique, centre de medecine nucleaire, groupement hospitalier Est, 69 - Bron (France); Lao, S. [Service de radiopharmacie, medecine nucleaire, hopital de l' Archet, 06 - Nice (France)

2010-11-15

Radiopharmaceuticals are nowadays under the responsibility of the radio-pharmacist because of their medicinal product status. Radiopharmacy belongs to the hospital pharmacy department, nevertheless, interactions with nuclear medicine department are important: rooms are included or located near nuclear medicine departments in order to respect radiation protection rules, more over staff, a part of the material and some activities are shared between the two departments. Consequently, it seems essential to formalize links between the radiopharmacy and the nuclear medicine department, setting the goals to avoid conflicts and to ensure patients' security. Modalities chosen for this formalization will depend on the establishment's organization. (authors)

Occupational exposure in nuclear medicine in Portugal in the 1999-2003 period

International Nuclear Information System (INIS)

Martins, M. B.; Alves, J. G.; Abrantes, J. N.; Roda, A. R.

2007-01-01

The annual doses received by the staff of nuclear medicine departments from public hospitals and private clinics and evaluated by the Individual Monitoring Service of the Radiological Protection and Nuclear Safety Dept. (DPRSN) of the Nuclear and Technological Inst. (ITN) in Portugal, in the 5 y period from 1999 to 2003, are analysed and presented in this paper. In the 1999-2003 period, ITN-DPRSN monitored on an average 462 workers from nuclear medicine departments, which represents 6% of the 8000 workers of the medical field (approximately). The medical sector represents 80-85% of all the monitored population in Portugal. The professions of the monitored workers at nuclear medicine departments were identified by the respective departments as administrative, auxiliary, medical doctor, nuclear medicine technician, nurse, pharmacist and physicist. This information was collected at the onset of the monitoring and was updated over the last 3 y. The annual whole-body doses evaluated in the period 1999-2003 were used to derive the distribution of workers by dose intervals for every profession. The respective annual average doses and annual collective doses, as well as, the total average and total collective doses for the nuclear medicine sector were also determined and are presented. Internal radiation hasn't been monitored. (authors)

Nuclear Medicine and Application of Nuclear Techniques in Medicine

International Nuclear Information System (INIS)

Wiharto, Kunto

1996-01-01

The use of nuclear techniques medicine covers not only nuclear medicine and radiology in strict sense but also determination of body mineral content by neutron activation analysis and x-ray fluorescence technique either in vitro or in vivo, application of radioisotopes as tracers in pharmacology and biochemistry, etc. This paper describes the ideal tracer in nuclear medicine, functional and morphological imaging, clinical aspect and radiation protection in nuclear medicine. Nuclear technique offers facilities and chances related to research activities and services in medicine. The development of diagnostic as well as therapeutic methods using monoclonal antibodies labeled with radioisotope will undoubtedly play an important role in the disease control

The radiation dose to accompanying nurses, relatives and other patients in a nuclear medicine department waiting room

Energy Technology Data Exchange (ETDEWEB)

Harding, L K; Harding, N J; Warren, H; Mills, A; Thomson, W H [Dudley Road Hospital, Birmingham (UK)

1990-01-01

The radiation dose to accompanying nurses, relatives and other patients in a nuclear medicine department waiting room was assessed at 5 min intervals by observing the seating arrangement. The total radiation dose to each person was calculated, using fixed values of dose rate per 100 MBq activity for radionuclides, and applying the inverse square law. Radioactive decay and attenuation effects due to intervening persons were also taken into account. The median radiation doses to accompanying nurses, relatives and other patients were 2.3, 2.0 and 0.2 {mu}Sv with maximum values of 17, 33 and 5 {mu}Sv respectively. In all cases, the radiation dose received by patients was less than 0.2% of the radiation dose resulting from their own investigation. Also, the maximum radiation dose received by an accompanying norse or friend was less than 1% of their appropriate annual dose limit. Similar values were obtained with calculations based on a 15 min time interval. The radiation doses received by those in a nuclear medicine department waiting room are small, and separate waiting room facilities for radioactive patients are unnecessary. (author).

Workplace monitoring at the nuclear medicine department of IPO-CROL

International Nuclear Information System (INIS)

Rezio, M.T.; Vieira, M.R.; Alves, J.G.

2005-01-01

Full text: The Nuclear Medicine Department of the Portuguese Institute of Oncology in Lisboa (IPO-CROL, SA) has recently acquired a new type of equipment for workplace monitoring: TAM radiation meter system (Tema Sinergy, Italy). It consists of a Geiger-Mueller detector with a dose rate range between 0.1 μSv.h -1 to 0.02 Sv.h -1 and sensitive to energies between 50 keV to 1 MeV. Eight detectors were installed in the most important areas of our department, namely, radiopharmacy, waiting room for accompanying persons, waiting room of injected patients (at two points), room of injected patients, PET radiopharmacy, PET commands room, and waiting room of PET injected patients. The dose rate measured by the equipment is collected on a computer on a 24-hour basis. The system allows an online visualization of the measurements as well as the storage on a database for evaluation. In this work the data collected with this equipment is analyzed. The system gives us the dose rate average, for example, in the PET commands room (0,186 μSv.h -1 ) and in the PET radiopharmacy (0,240 μSv.h -1 ). The results show that the dose rate limits established by law for this type of installations (0.4 mSv.week -1 for professionally exposed workers and 0.02 mSv.week -1 for the general public) are not exceeded. The aim of this work is to demonstrate there are presently good radiation protection conditions at our department. (author)

Availability of oncological nuclear medicine in the regions of Slovakia

International Nuclear Information System (INIS)

Lepej, J.; Kaliska, L.

2004-01-01

Full text: Nuclear medicine (NM) imaging technology, alone and in combination with other imaging modalities, provides clinically significant and useful information in the staging and treatment of the oncological diseases. The main objective of our study was to find out and present the situation vis-a-vis nuclear medicine facilities in the Central European country that soon becomes the new member of EU. For the purposes statistical data of WHO, Slovak Republic (SR) and nuclear medicine department (NMD) were evaluated for the period 1995-2001. Comparison with Czech Republic (CR) was done because of almost similar occurrence of the malignant diseases in these two republics that were a one country till separation in 1993. First nuclear medicine department in Czechoslovakia was established about 55 years ago. Comparing to CR the expenditures on health care per capita in SR is only 67% of CR. The number of gamma cameras, physicians and number of investigations are far from good standard of CR. The number NM departments are significantly low and growth of only 29% compared to CR is alarming. The one main reason is inadequate financial support to the health care and high debts of hospitals running nuclear medicine facilities. Providing radiology departments with new CT and MRI scanners is another reason of less nuclear medicine facilities. During the last five years, though the number of gamma cameras increased by 10%, but the number of investigations did not rise accordingly. Because of bad management of health care services in Slovakia, the latest facilities availability is greatly delayed. However, the exception is the installation of a new PET scanner in 2001. Of late, sentinel lymph node detection was started only with the help of IAEA. Data shows that most of the nuclear medicine centers are around the state capital. It is imperative to have sufficient diagnostic and therapeutic facilities in each region so as to make these available to patients living away from the

Nuclear medicine in Tunisia : current status and prospects

International Nuclear Information System (INIS)

Hammami, Hatem

2013-01-01

Nuclear medicine is concerned with the utilisation of radioactivity in vivo or in vitro for diagnostic or therapeutic purposes. In Tunisia, there are four public departments of nuclear medicine and seven private clinics. 50% of the population is localized in the north, which justifies the existence of 7 public and private departments of nuclear medicine with nine gamma cameras in this region. In the south, there are 30 pour cent of the population that goes to Sfax and 20 pour cent to Sousse where we count two departments with gamma cameras in public services and one in the private sector. The nuclear medicine services in the public sector have 4 SPECT / CT. Siemens is the leading provider of gamma cameras and occupies 73 pour cent of market share, subsequently ranks SMV (13 pour cent) and (GE and GAEDE) have the same proportion of the market share (7 pour cent). For radio-protected rooms, there is a single center with a single chamber from four public services. On the other hand, there are 2/7 private centers that are equipped with five radio-protected electrically rooms. Concerning the human resources, there are 26 doctors and 24 technicians in the public sector. The private sector has 6 doctors and 12 technicians. In 2012, there has been 22000 examinations (diagnostic and therapeutic procedures) in which 14,600 in nuclear medicine departments of public hospitals. Bone scintigraphy ranks first, with a relative frequency of 40-80 pour cent thereafter ranks renal scintigraphy (10-15 pour cent) and then the thyroid scintigraphy (8-12 pour cent). The waiting period is a major problem, especially in the public sector. Taking as an example, for the therapy of thyroid, injection of 100 mCi of I-131 requires a period of waiting more than six months and waiting more than three months for the bone scan. The second problem for patient with cancer is the distance, there are 11 centers concentrated in 3 coastal cities and none in the inner areas of the country, no regional

Operational measurements during medical examinations: nuclear medicine department

International Nuclear Information System (INIS)

Gardin, I.

2009-01-01

After having briefly recalled the nuclear medicine principles and objectives, and the main radiations used for different purposes (positrons for diagnosis, photons for diagnosis, electrons for therapy or diagnosis), the author presents the principle of determination of the absorbed dose: how this dose is expressed, how it is calculated per cumulative activity unit, how cumulative activity is determined. Then, she discusses some practical aspects of dosimetric assessments during diagnosis or therapeutic examinations

Evaluation of management of radioactive waste in nuclear medicine department of radiation and isotopes center, Khartoum

International Nuclear Information System (INIS)

Ahmed, Amel Bushra Abaker

2001-01-01

Evaluation of management of radioactive waste in nuclear medicine department of radiation and isotopes center in Khartoum, Sudan, was conducted using radiation survey meter. The purpose of this study is to provide protection of workers, patients, co patients, an the environment by introducing good practice in management of radioactive waste generated in this lab. In this work measurement of radiation effective dose at different locations in the department were carried out. These locations were selected around the radioactive liquid and solid waste disposal position. It was found that the effective doses per year from radioactive wastes obtained through this work using the survey meter RDS-120 at these locations, are 1.47 mSv/y at the neighbouring patients room, 5.47 mSv/y at the hot lab., 0.09 mSv/y at the neighbouring toilet, 0.321 mSv/y at the water closet, and 1.4 mSv/y at the place down water closet. The results obtained shows that the dose levels waste at the location not exceed the recommended dose limits for workers 20 mSv/y, that set by basic safety standards (Bss 115) which published by the international atomic energy agency. Also it s comply with the national regulation, regulation on basic radiation protection requirement and dose limits 1996, issued by sudan atomic energy commission act 1996. The annual dose calculated for the patients and co-patients at rooms around the nuclear medicine department, the results shows that dose are fairly high. Measure should taken to improve the waste management in the department for better protection of workers, patients and co patients. (Author)

Nuclear medicine

International Nuclear Information System (INIS)

Kand, Purushottam

2012-01-01

Nuclear medicine is a specialized area of radiology that uses very small amounts of radioactive materials to examine organ function and structure. Nuclear medicine is older than CT, ultrasound and MRI. It was first used in patients over 60-70 years ago. Today it is an established medical specialty and offers procedures that are essential in many medical specialities like nephrology, pediatrics, cardiology, psychiatry, endocrinology and oncology. Nuclear medicine refers to medicine (a pharmaceutical) that is attached to a small quantity of radioactive material (a radioisotope). This combination is called a radiopharmaceutical. There are many radiopharmaceuticals like DTPA, DMSA, HIDA, MIBI and MDP available to study different parts of the body like kidneys, heart and bones etc. Nuclear medicine uses radiation coming from inside a patient's body where as conventional radiology exposes patients to radiation from outside the body. Thus nuclear imaging study is a physiological imaging, whereas diagnostic radiology is anatomical imaging. It combines many different disciplines like chemistry, physics mathematics, computer technology, and medicine. It helps in diagnosis and to treat abnormalities very early in the progression of a disease. The information provides a quick and accurate diagnosis of wide range of conditions and diseases in a person of any age. These tests are painless and most scans expose patients to only minimal and safe amounts of radiation. The amount of radiation received from a nuclear medicine procedure is comparable to, or often many times less than, that of a diagnostic X-ray. Nuclear medicine provides an effective means of examining whether some tissues/organs are functioning properly. Therapy using nuclear medicine in an effective, safe and relatively inexpensive way of controlling and in some cases eliminating, conditions such as overactive thyroid, thyroid cancer and arthritis. Nuclear medicine imaging is unique because it provides doctors with

Nuclear medicine

International Nuclear Information System (INIS)

Anon.

1993-01-01

The area of nuclear medicine, the development of artificially produced radioactive isotopes for medical applications, is relatively recent. Among the subjects covered in a lengthy discussion are the following: history of development; impact of nuclear medicine; understanding the most effective use of radioisotopes; most significant uses of nuclear medicine radioimmunoassays; description of equipment designed for use in the field of nuclear medicine (counters, scanning system, display systems, gamma camera); description of radioisotopes used and their purposes; quality control. Numerous historical photographs are included. 52 refs

Nuclear medicine training and practice in the Czech Republic

International Nuclear Information System (INIS)

Kaminek, Milan; Koranda, Pavel

2014-01-01

Nuclear medicine in the Czech Republic is a full specialty with an exclusive practice. Since the training program was organized and structured in recent years, residents have had access to the specialty of nuclear medicine, starting with a two-year general internship (in internal medicine or radiology). At present, nuclear medicine services are provided in 45 departments. In total, 119 nuclear medicine specialists are currently registered. In order to obtain the title of Nuclear Medicine Specialist, five years of training are necessary; the first two years consist of a general internship in internal medicine or radiology. The remaining three years consist of training in the nuclear medicine specialty itself, but includes three months of practice in radiology. Twenty-one physicians are currently in nuclear medicine training and a mean of three specialists pass the final exam per year. The syllabus is very similar to that of the European Union of Medical Specialists (UEMS), namely concerning the minimum recommended numbers for diagnostic and therapeutic procedures. In principle, the Czech law requires continuous medical education for all practicing doctors. The Czech Medical Chamber has provided a continuing medical education (CME) system. Other national CMEs are not accepted in Czech Republic. (orig.)

Nuclear medicine training and practice in the Czech Republic

Energy Technology Data Exchange (ETDEWEB)

Kaminek, Milan; Koranda, Pavel [University Hospital Olomouc, Department of Nuclear Medicine, Olomouc (Czech Republic)

2014-08-15

Nuclear medicine in the Czech Republic is a full specialty with an exclusive practice. Since the training program was organized and structured in recent years, residents have had access to the specialty of nuclear medicine, starting with a two-year general internship (in internal medicine or radiology). At present, nuclear medicine services are provided in 45 departments. In total, 119 nuclear medicine specialists are currently registered. In order to obtain the title of Nuclear Medicine Specialist, five years of training are necessary; the first two years consist of a general internship in internal medicine or radiology. The remaining three years consist of training in the nuclear medicine specialty itself, but includes three months of practice in radiology. Twenty-one physicians are currently in nuclear medicine training and a mean of three specialists pass the final exam per year. The syllabus is very similar to that of the European Union of Medical Specialists (UEMS), namely concerning the minimum recommended numbers for diagnostic and therapeutic procedures. In principle, the Czech law requires continuous medical education for all practicing doctors. The Czech Medical Chamber has provided a continuing medical education (CME) system. Other national CMEs are not accepted in Czech Republic. (orig.)

Nuclear Medicine on the net

International Nuclear Information System (INIS)

Graney, K.; Lin, P.C.; Chu, J.; Sathiakumur, C.

2003-01-01

Full text: To gain insight into Internet usage as a potential means of communicating with clinicians. Method: 200 clinicians within the South Western Sydney Health Area were surveyed by mail. Questionnaire details included Internet access, frequency of access, interest in department web site, suitability of content and interest in electronic bookings. The total response rate was 37% (74/200). General Practitioners comprised 46% of the respondents, and specialists 54%. All respondents had access to the Internet (44% from home only, 8% from work, 48% from both locations), with 57% accessing the Web daily. There was a high overall interest by respondents in accessing a Nuclear medicine web site, particularly for information and results, but a relative reluctance to consider electronic bookings. The following table outlines the respondents in detail. Our results indicate that a Nuclear Medicine web site has the potential to be an effective means of communicating with clinicians. Copyright (2003) The Australian and New Zealand Society of Nuclear Medicine Inc

Radiation protection in nuclear medicine

International Nuclear Information System (INIS)

Seeburrun, V.

2013-04-01

Radiation protection in nuclear medicine in this project is concerned with the reduction of doses to workers, patients and members of the public. Protection of workers is achieved by adopting good personal habits, good housekeeping, proper use of personal protective devices and equipment, attend training and have continuous education. Exposure to radiation of workers and the members of the public are minimised by proper management of radioactive waste and safe transport of radioactive material. The design and shielding of a nuclear medicine department shall further provide for the protection of the worker, the patient and the general public. Protection of patient is achieved by justifying the procedure, delivering the minimum radiation dose possible to the patient while obtaining the best image quality and applying guidance levels. Special considerations shall be given to pregnant and breast-feeding patients. Quality assurance programme through image quality, radiopharmaceutical quality and patient records on nuclear medicine procedures shall provide assurance to the patient. (au)

Children's (Pediatric) Nuclear Medicine

Science.gov (United States)

... Professions Site Index A-Z Children's (Pediatric) Nuclear Medicine Children’s (pediatric) nuclear medicine imaging uses small amounts ... Children's Nuclear Medicine? What is Children's (Pediatric) Nuclear Medicine? Nuclear medicine is a branch of medical imaging ...

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Professions Site Index A-Z Children's (Pediatric) Nuclear Medicine Children’s (pediatric) nuclear medicine imaging uses small amounts ... Children's Nuclear Medicine? What is Children's (Pediatric) Nuclear Medicine? Nuclear medicine is a branch of medical imaging ...

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Physician Resources Professions Site Index A-Z Children's (Pediatric) Nuclear Medicine Children’s (pediatric) nuclear medicine imaging uses ... limitations of Children's Nuclear Medicine? What is Children's (Pediatric) Nuclear Medicine? Nuclear medicine is a branch of ...

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... News Physician Resources Professions Site Index A-Z Children's (Pediatric) Nuclear Medicine Children’s (pediatric) nuclear medicine imaging ... the limitations of Children's Nuclear Medicine? What is Children's (Pediatric) Nuclear Medicine? Nuclear medicine is a branch ...

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Resources Professions Site Index A-Z Children's (Pediatric) Nuclear Medicine Children’s (pediatric) nuclear medicine imaging uses small ... of Children's Nuclear Medicine? What is Children's (Pediatric) Nuclear Medicine? Nuclear medicine is a branch of medical ...

Internal dosimetry in nuclear medicine procedures

International Nuclear Information System (INIS)

Carrera Magarino, F.; Salgado Garcia, C.; Ruiz Manzano, P.; Rivas Ballarin, M. A.; Jimenez Hefernan, A.; Sanchez Segovia, J.

2011-01-01

The Department of Radio Physics and Radiation Protection, University Hospital Lozano Blesa Zaragoza presented a calculus textbook to estimate patient doses in diagnostic nuclear medicine. In this paper present an updated referred Book of calculation.

Occupational radiation exposure in nuclear medicine department in Kuwait

Science.gov (United States)

Alnaaimi, M.; Alkhorayef, M.; Omar, M.; Abughaith, N.; Alduaij, M.; Salahudin, T.; Alkandri, F.; Sulieman, A.; Bradley, D. A.

2017-11-01

Ionizing radiation exposure is associated with eye lens opacities and cataracts. Radiation workers with heavy workloads and poor protection measures are at risk for vision impairment or cataracts if suitable protection measures are not implemented. The aim of this study was to measure and evaluate the occupational radiation exposure in a nuclear medicine (NM) department. The annual average effective doses (Hp[10] and Hp[0.07]) were measured using calibrated thermos-luminescent dosimeters (TLDs; MCP-N [LiF:Mg,Cu,P]). Five categories of staff (hot lab staff, PET physicians, NM physicians, technologists, and nurses) were included. The average annual eye dose (Hp[3]) for NM staff, based on measurements for a typical yearly workload of >7000 patients, was 4.5 mSv. The annual whole body radiation (Hp[10]) and skin doses (Hp[0.07]) were 4.0 and 120 mSv, respectively. The measured Hp(3), Hp(10), and Hp(0.07) doses for all NM staff categories were below the dose limits described in ICRP 2014 in light of the current practice. The results provide baseline data for staff exposure in NM in Kuwait. Radiation dose optimization measures are recommended to reduce NM staff exposure to its minimal value.

Analysis of changed bio-signal to radiation exposure of nuclear medicine worker

International Nuclear Information System (INIS)

Lee, Hwun Jae; Lee, Sang Bock

2007-01-01

In this paper, we are evaluated about bio-signal between general workers and nuclear medicine workers which is more radiation exposure relatively. In order to reciprocal evaluated two group, we experimented nuclear medicine workers in Chung-Buk National University Hospital at department of nuclear medicine and worker in Chon-Nam National University Hospital at CT room, general radiographic room, medical recording room, receipt room, general office room. Used of experimental equipments as follows, for a level of radiation measurement by pocket dosimeter which made by Arrow-Tech company, for heart rate and blood pressure measurement by TONOPORT V which made by GE medical systems company, for heat flux and skin temperature and energy expenditure measurement by Armband senseware 2000 which made by Bodymedia company. Result of experiment obtains as follows : 1) Individual radiation exposure is recorded 3.05 uSv at department of nuclear medicine and order as follows CT room, general radiograpic room, medical recording room, receipt room, general office room. Department of nuclear medicine more 1.5 times than other places. 2) Radiation accumulated dose is not related to Heat flux, Skin temperature, Energy expenditure. 3) Blood pressure is recorded equal to nuclear medical workers, general officer, general people about systolic blood pressure and diastolic blood pressure. Compared to blood pressure between nuclear medical works which is more radiation exposure and other workers was not changed. Consequently, more radiation exposed workers at nuclear medicine field doesn't have hazard

Assessment of OEP health's risk in nuclear medicine

International Nuclear Information System (INIS)

Santacruz-Gomez, K.; Manzano, C.; Melendrez, R.; Castaneda, B.; Barboza-Flores, M.; Pedroza-Montero, M.

2012-01-01

The use of ionizing radiation has been increased in recent years within medical applications. Nuclear Medicine Department offers both treatment and diagnosis of diseases using radioisotopes to controlled doses. Despite the great benefits to the patient, there is an inherent risk to workers which remains in contact with radiation sources for long periods. These personnel must be monitored to avoid deterministic effects. In this work, we retrospectively evaluated occupationally exposed personnel (OEP) to ionizing radiation in nuclear medicine during the last five years. We assessed both area and personal dosimetry of this department in a known Clinic in Sonora. Our results show an annual equivalent dose average of 4.49 ± 0.70 mSv in OEP without showing alarming changes in clinical parameters analyzed. These results allow us to conclude that health of OEP in nuclear medicine of this clinic has not been at risk during the evaluated period. However, we may suggest the use of individual profiles based on specific radiosensitivity markers.

Nuclear medicine physics

CERN Document Server

De Lima, Joao Jose

2011-01-01

Edited by a renowned international expert in the field, Nuclear Medicine Physics offers an up-to-date, state-of-the-art account of the physics behind the theoretical foundation and applications of nuclear medicine. It covers important physical aspects of the methods and instruments involved in modern nuclear medicine, along with related biological topics. The book first discusses the physics of and machines for producing radioisotopes suitable for use in conventional nuclear medicine and PET. After focusing on positron physics and the applications of positrons in medicine and biology, it descr

Computer applications in nuclear medicine

International Nuclear Information System (INIS)

Lancaster, J.L.; Lasher, J.C.; Blumhardt, R.

1987-01-01

Digital computers were introduced to nuclear medicine research as an imaging modality in the mid-1960s. Widespread use of imaging computers (scintigraphic computers) was not seen in nuclear medicine clinics until the mid-1970s. For the user, the ability to acquire scintigraphic images into the computer for quantitative purposes, with accurate selection of regions of interest (ROIs), promised almost endless computational capabilities. Investigators quickly developed many new methods for quantitating the distribution patterns of radiopharmaceuticals within the body both spatially and temporally. The computer was used to acquire data on practically every organ that could be imaged by means of gamma cameras or rectilinear scanners. Methods of image processing borrowed from other disciplines were applied to scintigraphic computer images in an attempt to improve image quality. Image processing in nuclear medicine has evolved into a relatively extensive set of tasks that can be called on by the user to provide additional clinical information rather than to improve image quality. Digital computers are utilized in nuclear medicine departments for nonimaging applications also, Patient scheduling, archiving, radiopharmaceutical inventory, radioimmunoassay (RIA), and health physics are just a few of the areas in which the digital computer has proven helpful. The computer is useful in any area in which a large quantity of data needs to be accurately managed, especially over a long period of time

Pulmonary explorations in nuclear medicine

International Nuclear Information System (INIS)

Beck, C.

1987-01-01

Ten years ago specialists in Nuclear Medicine from the South of France formed an Association called ACOMEN. The objectives were to create a permanent exchange of ideas between members and a close collaboration with physicians. The group objectives have led to a combination of efforts on the behalf of each one to clarify our techniques for physicians having recourse to this speciality as well as the various categories of students passing through the Nuclear Medicine Departments. Different groups within the ACOMEN were assigned to specific subjects. Each group was in charge of building the framework of a certain topic, which was then illustrated by selected documents contributed by all members. A slide collection, complete with an explanatory booklet is the final result of this collaboration. Thus anyone concerned in any way, with nuclear medicine, is able to quickly become familiar with the techniques of the speciality, to be aware of its possibilities and its limitations and to update his hnowledge. One realizes that the first theme selected was not the easiest; pulmonary radionuclide explorations are, as everyone knows, variable and even personalized. However, the choice was deliberate. The difficulty should stimulate those responsible for the other themes as well as the people working with them. There is already a slide collection available to anyone who wishes to learn about the use of nuclear medicine in the diagnosis of respiratory diseases [fr

Overview of radiation protection programme in nuclear medicine facility for diagnostic procedures

International Nuclear Information System (INIS)

Ahmed, Ezzeldein Mohammed Nour Mohammed

2015-02-01

This project was conducted to review Radiation Protection Program in Nuclear Medicine facility for diagnostic procedures which will provide guide for meeting the standard and regulatory requirements in diagnostic nuclear medicine. The main objective of this project is to keep dose to staff, patient and public as low as reasonably achievable (ALARA). The specific objectives were to review the Radiation Protection Program (RPP) in diagnostic nuclear medicine and to make some recommendation for improving the level of radiation protection in diagnostic nuclear medicine that will help to control normal exposure and prevent or mitigate potential exposure. The methodology used is review of various documents. The review showed that if the Radiation Protection Program is inadequate it leads to unjustified exposure to radiation. Finally, this study stated some recommendations that if implemented could improve the level of radiation protection in nuclear medicine department. One of the most important recommendations is that a qualified Radiation Protection Officer (RPO) should be appointed to lay down and oversee a radiation protection in the nuclear medicine department. The RPO must be given the full authority and the adequate time to enable him to perform his duties effectively. (au)

Radiation protection in nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Volodin, V; Hanson, G P

1993-12-31

The goal of this Chapter is to give a general outline of the essential principles and procedures for radiation protection in a nuclear medicine department where radionuclides are used for diagnosis and therapy. More detailed recommendations regarding radiation protection in nuclear medicine are given in the publications of the International Commission on Radiation Protection (ICRP, publications 25, 57, 60) and in ILO/IAEA/WHO Manual on Radiation Protection in Hospitals and General Practice (Volume 2: Unsealed Sources, WHO, Geneva, 1975), on which this Chapter is based. This chapter is not intended to replace the above-mentioned international recommendations on radiation protection, as well as existing national regulations on this subject, but intended only to provide guidance for implementing these recommendations in clinical practice

Radiation protection in nuclear medicine

International Nuclear Information System (INIS)

Volodin, V.; Hanson, G.P.

1992-01-01

The goal of this Chapter is to give a general outline of the essential principles and procedures for radiation protection in a nuclear medicine department where radionuclides are used for diagnosis and therapy. More detailed recommendations regarding radiation protection in nuclear medicine are given in the publications of the International Commission on Radiation Protection (ICRP, publications 25, 57, 60) and in ILO/IAEA/WHO Manual on Radiation Protection in Hospitals and General Practice (Volume 2: Unsealed Sources, WHO, Geneva, 1975), on which this Chapter is based. This chapter is not intended to replace the above-mentioned international recommendations on radiation protection, as well as existing national regulations on this subject, but intended only to provide guidance for implementing these recommendations in clinical practice

Exposure from diagnostic nuclear medicine procedures

International Nuclear Information System (INIS)

Iacob, O.; Diaconescu, C.; Isac, R.

2002-01-01

According to our last national study on population exposures from natural and artificial sources of ionizing radiation, 16% of overall annual collective effective dose represent the contribution of diagnostic medical exposures. Of this value, 92% is due to diagnostic X-ray examinations and only 8% arise from diagnostic nuclear medicine procedures. This small contribution to collective dose is mainly the result of their lower frequency compared to that of the X-ray examinations, doses delivered to patients being, on average, ten times higher. The purpose of this review was to reassess the population exposure from in vivo diagnostic nuclear medicine procedures and to evaluate the temporal trends of diagnostic usage of radiopharmaceuticals in Romania. The current survey is the third one conducted in the last decade. As in the previous ones (1990 and 1995), the contribution of the Radiation Hygiene Laboratories Network of the Ministry of Health and Family in collecting data from nuclear medicine departments in hospitals was very important

[In vivo mutagenicity and clastogenicity of ionizing radiation in nuclear medicine

International Nuclear Information System (INIS)

1989-01-01

The overall goals of our research remains to investigate the mutagenic and clastogenic effects of exposure to low levels of ionizing radiation in human lymphocytes. We are studying hospital patients referred to a nuclear medicine department for diagnostic cardiac imaging and nuclear medicine technologists who administer radionuclides

Nuclear medicine and the pregnant patient

International Nuclear Information System (INIS)

Collins, L.

1988-01-01

Estimates of the risks of exposing an embryo or fetus to radiation are discussed. Recommendations are made about the policies a nuclear medicine department should develop for handling cases of accidental irradiation of an embryo or fetus. The choices available where a known pregnancy is involved and diagnostic radiology is required are outlined. Only necessary examinations should be performed and care taken to avoid or minimise irradiation of the fetus. The nuclear medicine physician must be prepared to make (and defend if necessary) an informed decision on whether to proceed with an examination and must also be in a position to discuss the risks with anxious parents

Scientific publications from departments of clinical physiology and nuclear medicine in Denmark. A bibliometric analysis of "impact' in the years 1989-1994

DEFF Research Database (Denmark)

Hansen, HB; Brinch, K; Henriksen, Jens Henrik Sahl

1996-01-01

This study reports a bibliometric analysis of scientific publications emanating from departments of clinical physiology and nuclear medicine, Denmark, during the years 1989-1994. The total number of publications during this period was 860 (763 scientific journal papers, 71 book/book chapters and 26...... a collaboration between two or more departments of clinical physiology and nuclear medicine, but the collaboration with other medical specialities and institutions was much greater (85%). The 763 papers were published in 239 different scientific journals, 80% in journals with an official 'impact factor......', a bibliometric measure of quality (the average number of times a paper is cited in a journal in the publishing year and the subsequent year). Twenty per cent (20%) and 8.4% were printed in journals with an impact factor, respectively, of above 2.1 (the 500 journals most cited) and 3.7 (the 200 most cited), which...

Frontiers in nuclear medicine symposium: Nuclear medicine & molecular biology

Energy Technology Data Exchange (ETDEWEB)

NONE

1995-04-01

This document contains the abstracts from the American College of Nuclear Physicians 1993 Fall Meeting entitled, `Frontiers in Nuclear Medicine Symposium: Nuclear Medicine and Molecular Biology`. This meeting was sponsored by the US DOE, Office of Health and Environmental Research, Office of Energy Research. The program chairman was Richard C. Reba, M.D.

Impact of the prospective payment system on the delivery of nuclear medicine services

International Nuclear Information System (INIS)

Crucitti, T.W.; Pappas, V.M.

1986-07-01

The study evaluates the effect of the Medicare Prospective Payment System (PPS) on nuclear medicine technologists and services. Since 80% of nuclear medicine technologists work in hospitals, a large segment of the professionals would be affected by the new system. The survey was designed to assess the PPSs effect on nuclear medicine departments at the early implementation stage

Converting energy to medical progress [nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

NONE

2001-04-01

For over 50 years the Office of Biological and Environmental Research (BER) of the United States Department of Energy (DOE) has been investing to advance environmental and biomedical knowledge connected to energy. The BER Medical Sciences program fosters research to develop beneficial applications of nuclear technologies for medical diagnosis and treatment of many diseases. Today, nuclear medicine helps millions of patients annually in the United States. Nearly every nuclear medicine scan or test used today was made possible by past BER-funded research on radiotracers, radiation detection devices, gamma cameras, PET and SPECT scanners, and computer science. The heart of biological research within BER has always been the pursuit of improved human health. The nuclear medicine of tomorrow will depend greatly on today's BER-supported research, particularly in the discovery of radiopharmaceuticals that seek specific molecular and genetic targets, the design of advanced scanners needed to create meaningful images with these future radiotracers, and the promise of new radiopharmaceutical treatments for cancers and genetic diseases.

Converting energy to medical progress [nuclear medicine

International Nuclear Information System (INIS)

2001-01-01

For over 50 years the Office of Biological and Environmental Research (BER) of the United States Department of Energy (DOE) has been investing to advance environmental and biomedical knowledge connected to energy. The BER Medical Sciences program fosters research to develop beneficial applications of nuclear technologies for medical diagnosis and treatment of many diseases. Today, nuclear medicine helps millions of patients annually in the United States. Nearly every nuclear medicine scan or test used today was made possible by past BER-funded research on radiotracers, radiation detection devices, gamma cameras, PET and SPECT scanners, and computer science. The heart of biological research within BER has always been the pursuit of improved human health. The nuclear medicine of tomorrow will depend greatly on today's BER-supported research, particularly in the discovery of radiopharmaceuticals that seek specific molecular and genetic targets, the design of advanced scanners needed to create meaningful images with these future radiotracers, and the promise of new radiopharmaceutical treatments for cancers and genetic diseases

Nuclear medicine training and practice in Poland

International Nuclear Information System (INIS)

Teresinska, Anna; Birkenfeld, Bozena; Krolicki, Leszek; Dziuk, Miroslaw

2014-01-01

In Poland, nuclear medicine (NM) has been an independent specialty since 1988. At the end of 2013, the syllabus for postgraduate specialization in NM has been modified to be in close accordance with the syllabus approved by the European Union of Medical Specialists and is expected to be enforced before the end of 2014. The National Consultant in Nuclear Medicine is responsible for the specialization program in NM. The Medical Center of Postgraduate Training is the administrative body which accepts the specialization programs, supervises the training, organizes the examinations, and awards the specialist title. Specialization in NM for physicians lasts for five years. It consists of 36 months of training in a native nuclear medicine department, 12 months of internship in radiology, 3 months in cardiology, 3 months in endocrinology, 3 months in oncology, and 3 months in two other departments of NM. If a NM trainee is a specialist of a clinical discipline and/or is after a long residency in NM departments, the specialization in NM can be shortened to three years. During the training, there are obligatory courses to be attended which include the elements of anatomy imaging in USG, CT, and MR. Currently, there are about 170 active NM specialists working for 38.5 million inhabitants in Poland. For other professionals working in NM departments, it is possible to get the title of a medical physics specialist after completing 3.5 years of training (for those with a master's in physics, technical physics or biomedical engineering) or the title of a radiopharmacy specialist after completing 3 years of training (for those with a master's in chemistry or biology). At present, the specialization program in NM for nurses is being developed by the Medical Centre of Postgraduate Education. Continuing education and professional development are obligatory for all physicians and governed by the Polish Medical Chamber. The Polish Society of Nuclear Medicine (PTMN) organizes regular

Nuclear medicine training and practice in Poland

Energy Technology Data Exchange (ETDEWEB)

Teresinska, Anna [Institute of Cardiology, Department of Nuclear Medicine, Warsaw (Poland); Birkenfeld, Bozena [Pomeranian Medical University, Department of Nuclear Medicine, Szczecin (Poland); Krolicki, Leszek [Warsaw Medical University, Department of Nuclear Medicine, Warsaw (Poland); Dziuk, Miroslaw [Military Institute of Medicine, Department of Nuclear Medicine, Warsaw (Poland)

2014-10-15

In Poland, nuclear medicine (NM) has been an independent specialty since 1988. At the end of 2013, the syllabus for postgraduate specialization in NM has been modified to be in close accordance with the syllabus approved by the European Union of Medical Specialists and is expected to be enforced before the end of 2014. The National Consultant in Nuclear Medicine is responsible for the specialization program in NM. The Medical Center of Postgraduate Training is the administrative body which accepts the specialization programs, supervises the training, organizes the examinations, and awards the specialist title. Specialization in NM for physicians lasts for five years. It consists of 36 months of training in a native nuclear medicine department, 12 months of internship in radiology, 3 months in cardiology, 3 months in endocrinology, 3 months in oncology, and 3 months in two other departments of NM. If a NM trainee is a specialist of a clinical discipline and/or is after a long residency in NM departments, the specialization in NM can be shortened to three years. During the training, there are obligatory courses to be attended which include the elements of anatomy imaging in USG, CT, and MR. Currently, there are about 170 active NM specialists working for 38.5 million inhabitants in Poland. For other professionals working in NM departments, it is possible to get the title of a medical physics specialist after completing 3.5 years of training (for those with a master's in physics, technical physics or biomedical engineering) or the title of a radiopharmacy specialist after completing 3 years of training (for those with a master's in chemistry or biology). At present, the specialization program in NM for nurses is being developed by the Medical Centre of Postgraduate Education. Continuing education and professional development are obligatory for all physicians and governed by the Polish Medical Chamber. The Polish Society of Nuclear Medicine (PTMN) organizes

Control of the individual exposure in the practice of a nuclear medicine department

International Nuclear Information System (INIS)

Hernandez, J.M.; Castro Crespo, D.; Naranjo Cardentey, O.

1996-01-01

In Cuba, since the beginning of the 50 s radioisotopes and radiopharmaceutical have been used for medical purposes to diagnose different diseases. At present about 21 modules of Nuclear Medicine are available for this type of medical assistance service. Use of these substances has increased notably as years passed by, being it an important source of exposure to ionizing radiation. Therefore we were interested in knowing the behaviour of the distribution of equivalent doses during the procedures that are performed in one of such typical modules of nuclear medicine

Staff radiation doses associated with nuclear medicine procedures - a review of some recent measurements

International Nuclear Information System (INIS)

Harding, L.K.; Mostafa, A.B.; Thomson, W.H.

1990-01-01

Despite publication of the Approved Code of Practice and the Notes for Guidance, implementation of the UK Ionising Radiation Regulations has required local interpretation by nuclear medicine departments. One problem has been the lack of data upon which decisions can be based. In the last five years we and others have made a number of measurements of radiation doses to staff relating to nuclear medicine practice. This paper collates, summarizes and comments on this information. Where possible, results have been expressed in relation to the workload of an average nuclear medicine department. (author)

Role of nuclear medicine in imaging companion animals

International Nuclear Information System (INIS)

Currie, Geoffrey M.; Wheat, Janelle M.

2005-01-01

The role of equine nuclear medicine in Australia has been previously described in this journal and more recently, Lyall et al. provided a general overview of demographics of veterinary nuclear medicine departments in Australia. Lyall et al. discuss the main clinical applications of nuclear medicine scintigraphy in companion animals; dogs and cats. The aim of this article is to discuss in brief the applications of commonly performed nuclear medicine procedures in humans with respect to veterinary applications. More detailed discussion will also be offered for investigation of pathologies unique to veterinary nuclear medicine or which are more common in animals than humans. Companion animals are living longer today due to advances in both veterinary and human medicine. The problem is, like humans, longevity brings higher incidence of old age morbidity. As a pet owner, one might be initially motivated to extend life expectancy which is followed by the realisation that one also demands quality of life for pets. Early detection through advanced diagnostic tools, like nuclear medicine scintigraphy, allows greater efficacy in veterinary disease. There are limited veterinary nuclear medicine facilities in Australia due to cost and demand. Not surprisingly then, the growth of veterinary nuclear medicine in Australia, and overseas, has been integrally coupled to evaluation of race horses. While these facilities are generally specifically designed for race horses, racing greyhounds, lame family horses and companion animals are being investigated more frequently. In the USA, the American College of Veterinary Radiology (ACVC) is very active clinically and in research. The ACVC journal, Journal of Veterinary Radiology and Ultrasound, is published quarterly and includes a Nuclear Medicine section. Within the ACVR is the Society of Veterinary Nuclear Medicine. Proliferation of veterinary nuclear medicine centres in the USA has been associated with insurance and lifestyle changes

Quality assessment according to DIN EN ISO 9001:2000. An experience and development report of a nuclear medicine department

International Nuclear Information System (INIS)

Glawe, M.

2005-01-01

In 2001 the Department of Nuclear Medicine of the University Hospital Hamburg-Eppendorf was the first department in Germany certified by DIN EN ISO 9001:2000. Since then the quality management system (QM-system) was adapted to the needs and demands of our nuclear medicine department and of our team members. For easy access to all documents the whole system was put on a digital basis. Considering the meeting structure of our clinic the guidance of documents and the history of documents was integrated in a digital system. Revisions were made step-by-step with the objective to remove and avoid redundancies. To realise this requirement the investigation documentation (paragraph 85-sheet) was integrated in the QM-system in form and content complementing the guidelines of the corresponding Standard Operating Procedures (SOPs). The configuration of the SOPs has modified in the course of time and was tightened. A text module system was developed to assure a standardized quality of discharge letters and diagnostic findings. At regular intervals internal und external audits were performed. The exposure to so called ''undesired incidences'' has taken an important focus in our established QM-system. For a professional handling with mistakes we introduced a new system that also provides potential legal coverage. The critical examination of the own achievement and the professional handling of weak points is the major obstacle of a QM-system based on long-term considerations. (orig.)

Training and education in nuclear medicine at the Medical Faculty of the University of Zagreb

International Nuclear Information System (INIS)

Ivancevic, D.; Popovic, S.; Simonovic, I.; Vlatkovic, M.

1986-01-01

Training for specialization in nuclear medicine in Yugoslavia includes 12 months of training in departments of clinical medicine and 24 months of training in departments of nuclear medicine. Since 1974 many physicians have passed the specialist examination in Zagreb. A postgraduate study in nuclear medicine began at the Medical Faculty of the University of Zagreb in 1979. It includes four semesters of courses and research on a selected subject leading to the degree of Magister (Master of Science). Most of the training is conducted by the Institute of Nuclear Medicine at the University Hospital, Rebro, in Zagreb, which has the necessary teaching staff, equipment and space. Forty-four students have completed this postgraduate study. Nuclear medicine in a developing country faces several problems. Scarcity of expensive equipment and radiopharmaceuticals calls for modifications of methods, home made products and instrument maintenance. These, mostly economic, factors are given special emphasis during training. Nuclear power generation may solve some of the country's energy problems; therefore, specialists in nuclear medicine must obtain additional knowledge about the medical care and treatment of persons who might be subject to irradiation and contamination in nuclear power plants. Lower economic resources in developing countries require better trained personnel, stressing the need for organized training and education in nuclear medicine. With some support the Institute of Nuclear Medicine will be able to offer various forms of training and education in nuclear medicine for physicians, chemists, physicists, technologists and other personnel from developing countries. (author)

Nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Sharma, S M [Bhabha Atomic Research Centre, Bombay (India). Radiation Medicine Centre

1967-01-01

The article deals with the growth of nuclear medicine in India. Radiopharmaceuticals both in elemental form and radiolabelled compounds became commercially available in India in 1961. Objectives and educational efforts of the Radiation Medicine Centre setup in Bombay are mentioned. In vivo tests of nuclear medicine such as imaging procedures, dynamic studies, dilution studies, thyroid function studies, renal function studies, linear function studies, blood flow, and absorption studies are reported. Techniques of radioimmunoassay are also mentioned.

The applications of nuclear techniques in nuclear medicine

International Nuclear Information System (INIS)

Zhao Huiyang

1986-01-01

There are a great deal of advanced techniques in nuclear medicine imaging, because many recent achivements of nuclear techniques have been applied to medicine in recent years. This paper presents the effects of nuclear techniques in development of nuclear medicine imaging. The first part describes radiopharmaceuticals and nuclear medicine imaging including commonly used 99m Tc labeled agents and cyclotron produced radionuclides for organ imaging. The second part describes nuclear medicine instrucments, including PECT, SPECT, MRI ect.; and discussions on the advantages, disadvantages and present status

PACS in nuclear medicine

International Nuclear Information System (INIS)

Kang, Keon Wook

2000-01-01

PACS (Picture Archiving and Communication System) is being rapidly spread and installed in many hospitals, but most of the system do not include nuclear medicine field. Although additional costs of hardware for nuclear medicine PACS is low, the complexity in developing viewing software and little market have made the nuclear medicine PACS not popular. Most PACS utilize DICOM 3.0 as standard format, but standard format in nuclear medicine has been Interfile. Interfile should be converted into DICOM format if nuclear images are to be stored and visualized in most PACS. Nowadays, many vendors supply the DICOM option in gamma camera and PET. Several hospitals in Korea have already installed nucler PACS with DICOM, but only the screen captured images are supplied. Software for visualizing pseudo-color with color lookup tables and expressing with volume view should be developed to fulfill the demand of referring physicians and nuclear medicine physicians. PACS is going to integrate not only radiologic images but also endoscopic and pathologic images. Web and PC based PACS is now a trend and is much compatible with nuclear medicine PACS. Most important barrier for nuclear medicine PACS that we encounter is not a technical problem, but indifference of investor such as administrator of hospital or PACS. Now it is time to support and invest for the development of nuclear medicine PACS

Evaluation of radiation shielding rate of lead aprons in nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Han, Sang Hyun; Han, Beom Heui; Lee, Sang Ho [Dept. of Radiological Science, Seonam University, Asan (Korea, Republic of); Hong, Dong Heui [Dept. of Radiological Science, Far East University, Eumseong (Korea, Republic of); Kim, Gi Jin [Dept. of Nuclear Medicine, Konyang University Hospital, Daejeon (Korea, Republic of)

2017-03-15

Considering that the X-ray apron used in the department of radiology is also used in the department of nuclear medicine, the study aimed to analyze the shielding rate of the apron according to types of radioisotopes, thus γ ray energy, to investigate the protective effects. The radioisotopes used in the experiment were the top 5 nuclides in usage statistics {sup 99m}Tc, {sup 18}F, {sup 131}I, {sup 123}I, and {sup 201}Tl, and the aprons were lead equivalent 0.35 mmPb aprons currently under use in the department of nuclear medicine. As a result of experiments, average shielding rates of aprons were {sup 99m}Tc 31.59%, {sup 201}Tl 68.42%, and {sup 123}I 76.63%. When using an apron, the shielding rate of {sup 13}'1I actually resulted in average dose rate increase of 33.72%, and {sup 18}F showed an average shielding rate of –0.315%, showing there was almost no shielding effect. As a result, the radioisotopes with higher shielding rate of apron was in the descending order of {sup 123}I, {sup 201}Tl, {sup 99m}Tc, {sup 18}F, {sup 131}I. Currently, aprons used in the nuclear medicine laboratory are general X-ray aprons, and it is thought that it is not appropriate for nuclear medicine environment that utilizes γ rays. Therefore, development of nuclear medicine exclusive aprons suitable for the characteristics of radioisotopes is required in consideration of effective radiation protection and work efficiency of radiation workers.

Use of dual-head gamma camera in radionuclide internal contamination monitoring on radiation workers from a nuclear medicine department

International Nuclear Information System (INIS)

Rodriguez-Laguna, A.; Brandan, M.E.

2008-01-01

As a part of an internal dosimetry program that is performed at the Mexican National Institute of Cancerology - Nuclear Medicine Department, in the present work we suggest a procedure for the routinely monitoring of internal contamination on radiation workers and nuclear medicine staff. The procedure is based on the identification and quantification of contaminating radionuclides in human body by using a dual-head whole-body gamma camera. The results have shown that the procedures described in this study can be used to implement a method to quantify minimal accumulated activity in the main human organs to evaluate internal contamination with radionuclides. The high sensitivity of the uncollimated gamma camera is advantageous for the routinely detection and identification of small activities of internal contamination. But, the null spatial resolution makes impossible the definition of contaminated region of interest. Then, the use of collimators is necessary to the quantification of incorporated radionuclides activities in the main human organs and for the internal doses assessment. (author)

Radiation Monitoring in a Newly Established Nuclear Medicine Facility

International Nuclear Information System (INIS)

Afroj, Kamila; Anwar-Ul-Azim, Md.; Nath, Khokon Kumar; Khan, Md. Rezaul Karim

2010-05-01

A study of area monitoring in a nuclear medicine department's new physical facility was performed for 3 months to ascertain the level of radiation protection of the staff working in nuclear medicine and that of the patients and patient's attendants. Exposure to nuclear medicine personnel is considered as occupational exposure, while exposure to patients is considered medical exposure and exposure to patients' attendants is considered public exposure. The areas for the sources of radiation considered were the hot laboratory, where unsealed isotopes, radionuclides, generators are stored and dosages are prepared, the patients' waiting room, where the radioactive nuclides are administered orally and intravenously for diagnosis and treatment and the SPECT rooms, where the patients' acquisition are taken. The monitoring process was performed using the TLD supplied and measured by the Health Physics Division of Bangladesh Atomic Energy Commission. The result shows no over-exposure of radiation from any of the working areas. The environment of the department is safe for work and free from unnecessary radiation exposure risk. (author)

Assessment of OEP health's risk in nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Santacruz-Gomez, K.; Manzano, C.; Melendrez, R.; Castaneda, B.; Barboza-Flores, M.; Pedroza-Montero, M. [Departamento de Fisica, Universidad de Sonora. A.P. 1626 Hermosillo, Sonora, Mexico and Centro de Investigacion en Materiales Avanzados CIMAV, A.C. Chihuahua, Chihuahua (Mexico); Centro de Diagnostico Integral del Noroeste, Luis Donaldo Colosio 23 83000 Centro Hermosillo, Sonora (Mexico); Departamento de Investigacion en Fisica, Universidad de Sonora. A. P. 5-088 Hermosillo, Sonora (Mexico); Departamento de Fisica, Universidad de Sonora. A.P. 1626 Hermosillo, Sonora (Mexico); Departamento de Investigacion en Fisica, Universidad de Sonora. A. P. 5-088 Hermosillo, Sonora (Mexico)

2012-10-23

The use of ionizing radiation has been increased in recent years within medical applications. Nuclear Medicine Department offers both treatment and diagnosis of diseases using radioisotopes to controlled doses. Despite the great benefits to the patient, there is an inherent risk to workers which remains in contact with radiation sources for long periods. These personnel must be monitored to avoid deterministic effects. In this work, we retrospectively evaluated occupationally exposed personnel (OEP) to ionizing radiation in nuclear medicine during the last five years. We assessed both area and personal dosimetry of this department in a known Clinic in Sonora. Our results show an annual equivalent dose average of 4.49 {+-} 0.70 mSv in OEP without showing alarming changes in clinical parameters analyzed. These results allow us to conclude that health of OEP in nuclear medicine of this clinic has not been at risk during the evaluated period. However, we may suggest the use of individual profiles based on specific radiosensitivity markers.

Measurements Of Fingers Doses Of Staff Members In Nuclear Medicine Department

International Nuclear Information System (INIS)

AL LEHYANI, S.H.; SHOUSHA, H.A.; HASSAN, R.A.

2009-01-01

For some occupationally radiation exposed groups, the hands are more heavily exposed to ionizing radiation than the rest of the body. The Egyptian Atomic Energy Authority runs an extensive personal dosimetry service in Egypt, but finger doses have not been measured to a wide extent. In this study, the finger doses were measured for five different nuclear medicine staff occupational groups for which heavy irradiation of the hands was suspected. Finger doses were measured for nuclear medicine physicians, technologists, nurses and physicists. The nuclear medicine staff working with the radioactive materials wears two TLD dosimeters during the whole period, which lasted from 1 to 4 weeks. The staff performs their work on a regular basis throughout the month, and means annual doses were calculated for these groups. The doses to the fingers for the 99m Tc technologists and nurses of groups (2) and (3) were observed to be 30.24 ± 14.5 μSv/GBq (mean ± SD) and 30.37 ± 17.5 μSv/GBq, respectively. Similarly, the dose to the fingers for the 131 I technologists in group (5) was estimated to be 126.13 ± 38.2μSv/GBq. Finger doses for the physicians could not be calculated per unit of activity because they did not handle the radiopharmaceuticals directly but their doses were reported in millisieverts that accumulated in 1 week. The doses to the fingers of the physicist were 16.3±7.7 μSv/GBq. The maximum average finger dose in this study was found to be 2.8 mSv for the technologists handled therapeutic 131 I (group 5). It could be concluded that the maximum expected annual dose to the extremities appeared to be less than the annual limit (500 mSv/y).

Evaluation of radiation shielding rate of lead aprons in nuclear medicine

International Nuclear Information System (INIS)

Han, Sang Hyun; Han, Beom Heui; Lee, Sang Ho; Hong, Dong Heui; Kim, Gi Jin

2017-01-01

Considering that the X-ray apron used in the department of radiology is also used in the department of nuclear medicine, the study aimed to analyze the shielding rate of the apron according to types of radioisotopes, thus γ ray energy, to investigate the protective effects. The radioisotopes used in the experiment were the top 5 nuclides in usage statistics "9"9"mTc, "1"8F, "1"3"1I, "1"2"3I, and "2"0"1Tl, and the aprons were lead equivalent 0.35 mmPb aprons currently under use in the department of nuclear medicine. As a result of experiments, average shielding rates of aprons were "9"9"mTc 31.59%, "2"0"1Tl 68.42%, and "1"2"3I 76.63%. When using an apron, the shielding rate of "1"3'1I actually resulted in average dose rate increase of 33.72%, and "1"8F showed an average shielding rate of –0.315%, showing there was almost no shielding effect. As a result, the radioisotopes with higher shielding rate of apron was in the descending order of "1"2"3I, "2"0"1Tl, "9"9"mTc, "1"8F, "1"3"1I. Currently, aprons used in the nuclear medicine laboratory are general X-ray aprons, and it is thought that it is not appropriate for nuclear medicine environment that utilizes γ rays. Therefore, development of nuclear medicine exclusive aprons suitable for the characteristics of radioisotopes is required in consideration of effective radiation protection and work efficiency of radiation workers

Directory of computer users in nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Erickson, J.J.; Gurney, J.; McClain, W.J. (eds.)

1979-09-01

The Directory of Computer Users in Nuclear Medicine consists primarily of detailed descriptions and indexes to these descriptions. A typical Installation Description contains the name, address, type, and size of the institution and the names of persons within the institution who can be contacted for further information. If the department has access to a central computer facility for data analysis or timesharing, the type of equipment available and the method of access to that central computer is included. The dedicated data processing equipment used by the department in its nuclear medicine studies is described, including the peripherals, languages used, modes of data collection, and other pertinent information. Following the hardware descriptions are listed the types of studies for which the data processing equipment is used, including the language(s) used, the method of output, and an estimate of the frequency of the particular study. An Installation Index and an Organ Studies Index are also included. (PCS)

Directory of computer users in nuclear medicine

International Nuclear Information System (INIS)

Erickson, J.J.; Gurney, J.; McClain, W.J.

1979-09-01

The Directory of Computer Users in Nuclear Medicine consists primarily of detailed descriptions and indexes to these descriptions. A typical Installation Description contains the name, address, type, and size of the institution and the names of persons within the institution who can be contacted for further information. If the department has access to a central computer facility for data analysis or timesharing, the type of equipment available and the method of access to that central computer is included. The dedicated data processing equipment used by the department in its nuclear medicine studies is described, including the peripherals, languages used, modes of data collection, and other pertinent information. Following the hardware descriptions are listed the types of studies for which the data processing equipment is used, including the language(s) used, the method of output, and an estimate of the frequency of the particular study. An Installation Index and an Organ Studies Index are also included

Nuclear medicine and mathematics

Energy Technology Data Exchange (ETDEWEB)

Pedroso de Lima, J.J. [Dept. de Biofisica e Proc. de Imagem, IBILI - Faculdade de Medicina, Coimbra (Portugal)

1996-06-01

The purpose of this review is not to present a comprehensive description of all the mathematical tools used in nuclear medicine, but to emphasize the importance of the mathematical method in nuclear medicine and to elucidate some of the mathematical concepts currently used. We can distinguish three different areas in which mathematical support has been offered to nuclear medicine: Physiology, methodology and data processing. Nevertheless, the boundaries between these areas can be indistinct. It is impossible in a single article to give even an idea of the extent and complexity of the procedures currently usede in nuclear medicine, such as image processing, reconstruction from projections and artificial intelligence. These disciplines do not belong to nuclear medicine: They are already branches of engineering, and my interest will reside simply in revealing a little of the elegance and the fantastic potential of these new `allies` of nuclear medicine. In this review the mathematics of physiological interpretation and methodology are considered together in the same section. General aspects of data-processing methods, including image processing and artificial intelligence, are briefly analysed. The mathematical tools that are most often used to assist the interpretation of biological phenomena in nuclear medicine are considered; these include convolution and deconvolution methods, Fourier analysis, factorial analysis and neural networking. (orig.)

Nuclear medicine and mathematics

International Nuclear Information System (INIS)

Pedroso de Lima, J.J.

1996-01-01

The purpose of this review is not to present a comprehensive description of all the mathematical tools used in nuclear medicine, but to emphasize the importance of the mathematical method in nuclear medicine and to elucidate some of the mathematical concepts currently used. We can distinguish three different areas in which mathematical support has been offered to nuclear medicine: Physiology, methodology and data processing. Nevertheless, the boundaries between these areas can be indistinct. It is impossible in a single article to give even an idea of the extent and complexity of the procedures currently usede in nuclear medicine, such as image processing, reconstruction from projections and artificial intelligence. These disciplines do not belong to nuclear medicine: They are already branches of engineering, and my interest will reside simply in revealing a little of the elegance and the fantastic potential of these new 'allies' of nuclear medicine. In this review the mathematics of physiological interpretation and methodology are considered together in the same section. General aspects of data-processing methods, including image processing and artificial intelligence, are briefly analysed. The mathematical tools that are most often used to assist the interpretation of biological phenomena in nuclear medicine are considered; these include convolution and deconvolution methods, Fourier analysis, factorial analysis and neural networking. (orig.)

Integrating cardiology for nuclear medicine physicians. A guide to nuclear medicine physicians

International Nuclear Information System (INIS)

Movahed, Assad; Gnanasegaran, Gopinath; Buscombe, John R.; Hall, Margaret

2009-01-01

Nuclear cardiology is no longer a medical discipline residing solely in nuclear medicine. This is the first book to recognize this fact by integrating in-depth information from both the clinical cardiology and nuclear cardiology literature, and acknowledging cardiovascular medicine as the fundamental knowledge base needed for the practice of nuclear cardiology. The book is designed to increase the practitioner's knowledge of cardiovascular medicine, thereby enhancing the quality of interpretations through improved accuracy and clinical relevance.The text is divided into four sections covering all major topics in cardiology and nuclear cardiology: -Basic Sciences and Cardiovascular Diseases; -Conventional Diagnostic Modalities; -Nuclear Cardiology; -Management of Cardiovascular Diseases. (orig.)

Advanced Bayesian processing of clinical data in nuclear medicine

International Nuclear Information System (INIS)

Jirsa, L.

1999-11-01

The Bayesian methodology was applied with a view to improving the quality of thyroid gland disease treatment at a nuclear medicine department. The specific tasks included: formulation of the estimation tasks from the theoretical point of view; elaborating algorithms to estimate various physical, medical and dosimetric quantities used in radiodiagnosis and radiotherapy of thyroid gland diseases; testing their numerical precision; testing their numerical stability on a large set of clinical data; implementation of the algorithms at a level applicable in routine conditions of the nuclear medicine department and replace by them the data processing methods used there so far; exploring and testing the quality improvement of the estimates; and in dependence on the results, proposing hints where improvement of the data measurement methodology is necessary

Internal dosimetry in nuclear medicine procedures; Dosimetria interna por procedimientos en medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Carrera Magarino, F.; Salgado Garcia, C.; Ruiz Manzano, P.; Rivas Ballarin, M. A.; Jimenez Hefernan, A.; Sanchez Segovia, J.

2011-07-01

The Department of Radio Physics and Radiation Protection, University Hospital Lozano Blesa Zaragoza presented a calculus textbook to estimate patient doses in diagnostic nuclear medicine. In this paper present an updated version referred Book of calculation.

Overview. Department of Nuclear Physical Chemistry. Section 9

Energy Technology Data Exchange (ETDEWEB)

Szeglowski, Z. [Institute of Nuclear Physics, Cracow (Poland)

1995-12-31

In the papers presented bellow the activities of the Department of Nuclear Physical Chemistry in 1994 are presented. A further effort was made towards routine production of neutron-deficient isotopes for nuclear medicine - and namely {sup 67} Ga and {sup 139} Ce. Small activities of {sup 111} In were produced by the {alpha} bombardment of Ag target. In order to improve the {sup 111} In production the deuterons reaction with cadmium target was studied. The other field of the Department research is studying of the physicochemical properties of transactinoid elements (104,105, 106). The Department is also engaged in works of the National Network of Early Detection of Radioactive Contamination in Air. In this section, apart of the detail descriptions of mentioned activities, the information about personnel employed in the Department, papers and reports published in 1994, contribution to conferences and grants are also given.

Overview. Department of Nuclear Physical Chemistry. Section 9

Energy Technology Data Exchange (ETDEWEB)

Szeglowski, Z [Institute of Nuclear Physics, Cracow (Poland)

1996-12-31

In the papers presented bellow the activities of the Department of Nuclear Physical Chemistry in 1994 are presented. A further effort was made towards routine production of neutron-deficient isotopes for nuclear medicine - and namely {sup 67} Ga and {sup 139} Ce. Small activities of {sup 111} In were produced by the {alpha} bombardment of Ag target. In order to improve the {sup 111} In production the deuterons reaction with cadmium target was studied. The other field of the Department research is studying of the physicochemical properties of transactinoid elements (104,105, 106). The Department is also engaged in works of the National Network of Early Detection of Radioactive Contamination in Air. In this section, apart of the detail descriptions of mentioned activities, the information about personnel employed in the Department, papers and reports published in 1994, contribution to conferences and grants are also given.

Nuclear medicine and AIDS

International Nuclear Information System (INIS)

O'Doherty, M.J.; Kent and Canterbury Hospital, Canterbury; Nunan, T.O.

1993-01-01

The human immunodeficiency virus (HIV) infection and its associated illnesses in a relatively young population of patients provides an expanding role for nuclear medicine. The disease enforces a review of each department's infection control procedures. It has also resulted in an increase in the number of patients presenting with diseases such as Pneumocystis carinii pneumonia, Kaposi's sarcoma etc. which prior to the HIV epidemic were extremely rare. Thus in high risk patients the interpretation of abnormalities in nuclear medicine scans needs to include the spectrum of opportunistic infections and unusual tumours. The presence of opportunistic infections in the severely immunocompromised patient has led to the development of techniques not normally used, i.e. lung 99 Tc m -diethylenetriamine pentaacetate (DTPA) transfer/clearance, donor leukocyte scanning to allow rapid diagnosis of an abnormality. Radionuclide techniques are also used to monitor the effect of therapy directed at the HIV itself or against opportunistic infections. This review covers aspects of infection control as well as the use of radionuclides to investigate specific problems related to HIV infection and therapy of the associated disease processes. (author)

Practical nuclear medicine

CERN Document Server

Gemmell, Howard G; Sharp, Peter F

2006-01-01

Nuclear medicine plays a crucial role in patient care, and this book is an essential guide for all practitioners to the many techniques that inform clinical management. The first part covers the scientific basis of nuclear medicine, the rest of the book deals with clinical applications. Diagnostic imaging has an increasingly important role in patient management and, despite advances in other modalities (functional MRI and spiral CT), nuclear medicine continues to make its unique contribution by its ability to demonstrate physiological function. This book is also expanded by covering areas of d

Nuclear Medicine week in Colombia

International Nuclear Information System (INIS)

Padhy, A.K.

2003-01-01

During the week of 6-12 October 2003 the IAEA organized a Research Coordination Meeting on 'Relationship between lower Respiratory Tract Infection, Gastroesophageal reflux and bronchial Asthma in children' at Hospital San Ignacio in Bogota. Besides there were four workshops in Bogota; workshops on Bone infection and Bone scan in Pediatric ortopaedics at Hospital Militar and Fundacion CardioInfantil, a workshop for Nuclear Medicine Technologists and a workshop on Sentinel Lymph Node mapping and Surgical Gamma Probe Application at Institute of Oncology. A nuclear cardiology workshop was organized in Medellin, and finally crowning them all was the 9th Congress of the Colombian Association of Nuclear Medicine at Cali from 10-12 October, 2003; probably the largest and best Colombian nuclear medicine congress every held in the country. A workshop was also organized in Cali for nuclear medicine technologists in conjunction with the Annual Convention. It was a mix of IAEA's Technical Cooperation and Regular Budget activities along with the activities of Colombian Association of Nuclear Medicine, bringing in absolute synergy to galvanize the entire nuclear medicine community of the country. The week saw nuclear medicine scientists from more than 20 IAEA Member States converging on Colombia to spread the message of nuclear medicine, share knowledge and to foster International understanding and friendship among the nuclear medicine people of the world

Physics and radiobiology of nuclear medicine

CERN Document Server

Saha, Gopal B

2013-01-01

The Fourth Edition of Dr. Gopal B. Saha’s Physics and Radiobiology of Nuclear Medicine was prompted by the need to provide up-to-date information to keep pace with the perpetual growth and improvement in the instrumentation and techniques employed in nuclear medicine since the last edition published in 2006. Like previous editions, the book is intended for radiology and nuclear medicine residents to prepare for the American Board of Nuclear Medicine, American Board of Radiology, and American Board of Science in Nuclear Medicine examinations, all of which require a strong physics background. Additionally, the book will serve as a textbook on nuclear medicine physics for nuclear medicine technologists taking the Nuclear Medicine Technology Certification Board examination.

Radiopharmacy contamination in nuclear medicine - a survey report

International Nuclear Information System (INIS)

Ghai, Anchal; Mardi, Somnath; Kumar, Pradeep; Sarika; Mittal, B.R.; Singh, B.

2011-01-01

To conduct the radiation survey of the category IV Nuclear Medicine department and to further measure and compare the level of loose contamination in areas with high levels of exposure at two different time points (morning and evening) using wipe test

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... interventions. Children's (pediatric) nuclear medicine refers to imaging examinations done in babies, young children and teenagers. Nuclear ... nuclear medicine procedure work? With ordinary x-ray examinations, an image is made by passing x-rays ...

Nuclear Medicine Engineering

International Nuclear Information System (INIS)

Mateescu, Gheorghe; Craciunescu, Teddy

2000-01-01

'An image is more valuable than a thousand words' - this is the thought that underlies the authors' vision about the field of nuclear medicine. The monograph starts with a review of some theoretical and engineering notions that grounds the field of nuclear medicine: nuclear radiation, interaction of radiation with matter, radiation detection and measurement, numerical analysis. Products and methods needed for the implementation of diagnostic and research procedures in nuclear medicine are presented: radioisotopes and radiopharmaceuticals, equipment for in-vitro (radioimmunoassay, liquid scintillation counting) and in-vivo investigations (thyroid uptake, renography, dynamic studies, imaging). A special attention is focused on medical imaging theory and practice as a source of clinical information (morphological and functional). The large variety of parameters, components, biological structures and specific properties of live matter determines the practical use of three-dimensional tomographic techniques based on diverse physical principles: single-photon emission, positron emission, X-rays transmission, nuclear magnetic resonance, ultrasounds transmission and reflection, electrical impedance measurement. The fundamental reconstruction algorithms i.e., algorithms based on the projection theorem and Fourier filtering, algebraic reconstruction techniques and the algorithms based on statistical principles: maximum entropy, maximum likelihood, Monte Carlo algorithms, are depicted in details. A method based on the use of the measured point spread function is suggested. Some classical but often used techniques like linear scintigraphy and Anger gamma camera imaging are also presented together with some image enhancement techniques like Wiener filtering and blind deconvolution. The topic of the book is illustrated with some clinical samples obtained with nuclear medicine devices developed in the Nuclear Medicine Laboratory of the National Institute of Nuclear Physics and

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... by Image/Video Gallery Your Radiologist Explains Nuclear Medicine Transcript Welcome to Radiology Info dot org Hello! ... d like to talk to you about nuclear medicine. Nuclear medicine offers the potential to identify disease ...

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... Sponsored by Image/Video Gallery Your Radiologist Explains Nuclear Medicine Transcript Welcome to Radiology Info dot org ... I’d like to talk to you about nuclear medicine. Nuclear medicine offers the potential to identify ...

Nuclear power in human medicine

International Nuclear Information System (INIS)

Kuczera, Bernhard

2012-01-01

The public widely associate nuclear power with the megawatt dimensions of nuclear power plants in which nuclear power is released and used for electricity production. While this use of nuclear power for electricity generation is rejected by part of the population adopting the polemic attitude of ''opting out of nuclear,'' the application of nuclear power in medicine is generally accepted. The appreciative, positive term used in this case is nuclear medicine. Both areas, nuclear medicine and environmentally friendly nuclear electricity production, can be traced back to one common origin, i.e. the ''Atoms for Peace'' speech by U.S. President Eisenhower to the U.N. Plenary Assembly on December 8, 1953. The methods of examination and treatment in nuclear medicine are illustrated in a few examples from the perspective of a nuclear engineer. Nuclear medicine is a medical discipline dealing with the use of radionuclides in humans for medical purposes. This is based on 2 principles, namely that the human organism is unable to distinguish among different isotopes in metabolic processes, and the radioactive substances are employed in amounts so small that metabolic processes will not be influenced. As in classical medicine, the application of these principles serves two complementary purposes: diagnosis and therapy. (orig.)

Preliminary results of the analysis of the administered activities in diagnostic studies of nuclear medicine

International Nuclear Information System (INIS)

Lopez Bejerano, G.; Sed, L.J.

2001-01-01

The worldwide use of Nuclear Medicine diagnostic procedures and the tendency to its increment, infers an important exposure of the population to ionising radiation; it has motivated that the IAEA in the International Basic Safety Standards (BSS), emits recommendations for the establishment of guidance levels of activities administered to the patients in diagnostic procedures. Taking into account the above-mentioned and that in Cuba there exist 20 departments of Nuclear Medicine that in the majority possess equipment with more than 20 years of operation, which influences directly the medical exposure. A survey was designed and applied in 10 of these departments. The survey evaluates the compliance with the BSS requirements, and specifically, the activities administered to the patients in Nuclear Medicine diagnostic procedures are analysed. In the present work the obtained preliminary results of the statistical analysis carried out on the activity values used in Nuclear Medicine departments are presented, and comparisons made for a proposal of guidance levels for the national practice, which is compared with those recommended internationally. (author)

Nuclear medicine

International Nuclear Information System (INIS)

Blanquet, Paul; Blanc, Daniel.

1976-01-01

The applications of radioisotopes in medical diagnostics are briefly reviewed. Each organ system is considered and the Nuclear medicine procedures pertinent to that system are discussed. This includes, the principle of the test, the detector and the radiopharmaceutical used, the procedure followed and the clinical results obtained. The various types of radiation detectors presently employed in Nuclear Medicine are surveyed, including scanners, gamma cameras, positron cameras and procedures for obtaining tomographic presentation of radionuclide distributions [fr

Radiation safety in nuclear medicine procedures

International Nuclear Information System (INIS)

Cho, Sang Geon; Kim, Ja Hae; Song, Ho Chun

2017-01-01

Since the nuclear disaster at the Fukushima Daiichi Nuclear Power Plant in 2011, radiation safety has become an important issue in nuclear medicine. Many structured guidelines or recommendations of various academic societies or international campaigns demonstrate important issues of radiation safety in nuclear medicine procedures. There are ongoing efforts to fulfill the basic principles of radiation protection in daily nuclear medicine practice. This article reviews important principles of radiation protection in nuclear medicine procedures. Useful references, important issues, future perspectives of the optimization of nuclear medicine procedures, and diagnostic reference level are also discussed

Radiation safety in nuclear medicine procedures

Energy Technology Data Exchange (ETDEWEB)

Cho, Sang Geon; Kim, Ja Hae; Song, Ho Chun [Dept. of Nuclear Medicine, Medical Radiation Safety Research Center, Chonnam National University Hospital, Gwangju (Korea, Republic of)

2017-03-15

Since the nuclear disaster at the Fukushima Daiichi Nuclear Power Plant in 2011, radiation safety has become an important issue in nuclear medicine. Many structured guidelines or recommendations of various academic societies or international campaigns demonstrate important issues of radiation safety in nuclear medicine procedures. There are ongoing efforts to fulfill the basic principles of radiation protection in daily nuclear medicine practice. This article reviews important principles of radiation protection in nuclear medicine procedures. Useful references, important issues, future perspectives of the optimization of nuclear medicine procedures, and diagnostic reference level are also discussed.

Evaluation of maximum absorbed dose for accompanying patients in nuclear medicine establishments; Avaliacao da dose maxima absorvida por acompanhantes de pacientes em servicos de medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Cabral, Geovanna; Amaral, Ademir; Hazin, Clivis A. [Pernambuco Univ., Recife, PE (Brazil). Dept. de Energia Nuclear; Lima, Ricardo A.; Nogueira, Maria S. [Centro Regional de Ciencias Nucleares (CRCN), Recife, PE (Brazil); Lopes, Ferdinand [Centro de Medicina Nuclear de Pernambuco (CEMUPE), Recife, PE (Brazil); Guimaraes, Maria Ines C.C. [Sao Paulo Univ., SP (Brazil). Centro de Medicina Nuclear

2001-07-01

In nuclear medicine, radioisotopes are bound to various pharmaceuticals for use in diagnostic and therapeutic applications. These unsealed sources are administered in various forms to patients, who remain radioactive for hours or days, and represent a source of potential radiation exposure for others. Thus, in nuclear medicine departments, radiation protection of workers and members of the public (especially persons accompanying patients) must consider this exposure. In this study, thermoluminescent dosimeters were given to various persons who were accompanying patients in two nuclear medicine departments in Recife, Pernambuco State, Brazil. Exposure results are given, and issues regarding exposure conditions and times for members of the public in these departments are discussed. (author)

Quality control in nuclear medicine

International Nuclear Information System (INIS)

Leme, P.R.

1983-01-01

The following topics are discussed: objectives of the quality control in nuclear medicine; the necessity of the quality control in nuclear medicine; guidelines and recommendations. An appendix is given concerning the guidelines for the quality control and instrumentation in nuclear medicine. (M.A.) [pt

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... that are congenital (present at birth) or that develop during childhood. Physicians use nuclear medicine imaging to evaluate organ ... Nuclear medicine scans are typically used to ...

A postal survey of quality assurance in nuclear medicine imaging in the UK during 1988

International Nuclear Information System (INIS)

Williams, E.D.; Harding, L.K.; McKillop, J.H.

1989-01-01

A questionnaire was sent to all the estimated 200 hospital departments providing nuclear medicine imaging services in the UK. Replies were received from 162 (81%). The questionnaire was brief, but covered a wide range of aspects of a nuclear medicine service. While all responses showed departments to have some quality control procedures in operation, they were often not used correctly. In most departments there appears to be scope for improvement so that departmental managers can monitor more closely the quality of service provided. (author)

Nuclear Medicine Practice in Kenya

International Nuclear Information System (INIS)

Ndirangu, T.D.

2017-01-01

Nuclear medicine is a medical specialty that relies on the use of nuclear technology in the diagnosis and treatment (therapy) of diseases. Nuclear medicine uses the principle that a certain radiopharmaceutical (tracer) will at a certain point in time have a preferential uptake by a particular body, tissue or cell. This uptake is then imaged by the use of detectors mounted in gamma cameras or PET (positron emission tomography) devices.. Unlike other radiation applications for medical use, nuclear medicine uses open (unsealed) sources of radiation. In a country with an estimated population of 48 million in 2017, Kenya has only two (2) nuclear medicine facilities (units). Being a relatively new medical discipline in Kenya, several measures have been taken by the clinical nuclear medicine team to create awareness at various levels

Proceedings of the forty third annual conference of Society of Nuclear Medicine India: empowering modern medicine with molecular nuclear medicine

International Nuclear Information System (INIS)

2011-01-01

Theme of the 43rd Annual Conference of the Society of Nuclear Medicine India is 'empowering modem medicine with molecular nuclear medicine'. Keeping the theme in mind, the scientific committee has arranged an attractive and comprehensive program for both physicians and scientists reflecting the multimodality background of Nuclear Medicine and Metabolic Imaging. During this meeting the present status and future prospects of Nuclear medicine are discussed at length by esteemed faculty in dedicated symposia and interesting featured sessions which are immensely facilitate in educating the participants. Nuclear Medicine has come a long way since the first applications of radioiodine in the diagnosis of thyroid disease. The specialty of nuclear medicine in India is growing very rapidly. Technology continues to push the field in new directions and open new pathways for providing optimal care to patients. It is indeed an exciting time in the world of imaging and in the field of nuclear medicine. Innovative techniques in hardware and software offer advantages for enhanced accuracy. New imaging agents, equipment, and software will provide us with new opportunities to improve current practices and to introduce new technology into the clinical protocols. Papers relevant to INIS are indexed separately

THE STRUCTURE AND FUNCTION OF DEPARTMENTS OF MEDICINE.

Science.gov (United States)

Landefeld, C Seth

2016-01-01

The structure and function of departments of medicine are important for several reasons. First, departments of medicine are the biggest departments in virtually every medical school and in most universities with a medical school, and they are the largest professional units in most academic medical centers. In fact, Petersdorf described them as "the linchpins of medical schools" (1). Departments of medicine account for one-fourth or more of the academic medical enterprise: they include about one-fourth of the faculty of medical school, account for roughly one-fourth of the patient care and clinical revenue of academic medical centers, and their faculty perform a disproportionate share of teaching and research, accounting for up to 45% of National Institutes of Health (NIH) - funded research in some medical schools. Second, the department's ability to fulfill its role and advance its mission depends on its structure and function. Finally, lessons learned from examining the structure and function of departments of medicine may guide other departments and schools of medicine themselves in improving their structure and function. This paper describes the issues that face departments of medicine in 2016. I begin by providing the context for these issues with a definition of a department of medicine, describing briefly the history of departments, and stating their mission.

Nuclear medicine technology study guide

CERN Document Server

Patel, Dee

2011-01-01

Nuclear Medicine Technology Study Guide presents a comprehensive review of nuclear medicine principles and concepts necessary for technologists to pass board examinations. The practice questions and content follow the guidelines of the Nuclear Medicine Technology Certification Board (NMTCB) and American Registry of Radiological Technologists (ARRT), allowing test takers to maximize their success in passing the examinations. The book is organized by sections of increasing difficulty, with over 600 multiple-choice questions covering all areas of nuclear medicine, including radiation safety; radi

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Children's (Pediatric) Nuclear Medicine? What are some common uses of the procedure? How does the nuclear medicine procedure work? What does the equipment look like? How is ...

Quality assessment according to DIN EN ISO 9001:2000. Certification in a nuclear medicine department

International Nuclear Information System (INIS)

Doebert, N.; Osterloh, M.; Menzel, C.; Gruenwald, F.; Kahla-Witzsch, H.A.

2005-01-01

In the year 2002 our department started to inaugurate a quality management system. The certification according to DIN EN ISO 9001:2000 as required by the hospital management was achieved in August 2004. The aim was the optimisation of internal operating schedules and the standardisation of procedures according to logistic interfaces with external structures. Since 2000 the implementation of an internal quality management system is required by German law (SGB V paragraph 135) and threatened by penalty in case of non-implementation (SGB V paragraph 137). Beside a basic audit and optimisation of all organisational procedures all core processes of our department were determined and the approvals were checked. These aims concern i.e. both the quality of our diagnostics of nuclear medicine and of the in vitro laboratory and the aspects of service such as quickness of scheduling and forwarding of reports and economic and efficient aspects of our work. An important role plays the department of ''quality management'', whose main tasks are the professional guidance and the training of the quality management representatives. The realisation of the new regulations and the restructuring resulted in an increase of effectiveness and in an improvement of operational procedures in our department. Especially the patients and the staff granted from the reorganised and modified sequence of operations. Implementation of a quality management system takes some efforts but the positive aspects for the structure and the flow of work are predominant so that the inauguration of a quality management system in the different departments of a hospital are recommendable. (orig.)

A concise guide to nuclear medicine

CERN Document Server

Elgazzar, Abdelhamid H

2011-01-01

Nuclear medicine is an important component of modern medicine. This easy-to-use book is designed to acquaint readers with the basic principles of nuclear medicine, the instrumentation used, the gamut of procedures available, and the basis for selecting specific diagnostic or therapeutic procedures and interpreting results. After an introductory chapter on the history, technical basis, and scope of nuclear medicine, a series of chapters are devoted to the application of nuclear medicine techniques in the different body systems. In addition, the use of nuclear medicine methods within oncology is

White paper of nuclear medicine

International Nuclear Information System (INIS)

2012-10-01

This document aims at proposing a synthetic presentation of nuclear medicine in France (definition, strengths and weaknesses, key figures about practices and the profession, stakes for years to come), a description of the corresponding education (speciality definition, abilities and responsibilities, diploma content, proposition by the European Society of Radiology and by the CNIPI, demography of the profession), and an overview of characteristics of nuclear medicine (radio-pharmacy, medical physics, paramedical personnel in nuclear medicine, hybrid imagery, therapy, relationships with industries of nuclear medicine, relationships with health authorities)

Asian School of Nuclear Medicine

International Nuclear Information System (INIS)

Sundram, F.X.

2007-01-01

A number of organisations are involved in the field of nuclear medicine education. These include International Atomic Energy Agency (IAEA), World Federation of Nuclear Medicine and Biology (WFNMB), Asia-Oceania Federation of Nuclear Medicine and Biology (AOFNMB), Society of Nuclear Medicine (SNM in USA), European Association of Nuclear Medicine (EANM). Some Universities also have M.Sc courses in Nuclear Medicine. In the Asian Region, an Asian Regional Cooperative Council for Nuclear Medicine (ARCCNM) was formed in 2000, initiated by China, Japan and Korea, with the main aim of fostering the spread of Nuclear Medicine in Asia. The Asian School of Nuclear Medicine (ASNM) was formed in February 2003, with the ARCCNM as the parent body. The Aims of ASNM are: to foster Education in Nuclear Medicine among the Asian countries, particularly the less developed regions; to promote training of Nuclear Medicine Physicians in cooperation with government agencies, IAEA and universities and societies; to assist in national and regional training courses, award continuing medical education (CME) points and provide regional experts for advanced educational programmes; and to work towards awarding of diplomas or degrees in association with recognised universities by distance learning and practical attachments, with examinations. There are 10 to 12 teaching faculty members from each country comprising of physicists, radio pharmacists as well as nuclear medicine physicians. From this list of potential teaching experts, the Vice-Deans and Dean of ASNM would then decide on the 2 appropriate teaching faculty member for a given assignment or a course in a specific country. The educational scheme could be in conjunction with the ARCCNM or with the local participating countries and their nuclear medicine organisations, or it could be a one-off training course in a given country. This teaching faculty is purely voluntary with no major expenses paid by the ASNM; a token contribution could be

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... are small, diagnostic nuclear medicine procedures result in low radiation exposure, acceptable for diagnostic exams. Thus, the radiation risk is very low compared with the potential benefits. Nuclear medicine diagnostic ...

Nuclear medicine resources manual

International Nuclear Information System (INIS)

2006-02-01

Over the past decade many IAEA programmes have significantly enhanced the capabilities of numerous Member States in the field of nuclear medicine. Functional imaging using nuclear medicine procedures has become an indispensable tool for the diagnosis, treatment planning and management of patients. However, due to the heterogeneous growth and development of nuclear medicine in the IAEA's Member States, the operating standards of practice vary considerably from country to country and region to region. This publication is the result of the work of over 30 international professionals who have assisted the IAEA in the process of standardization and harmonization. This manual sets out the prerequisites for the establishment of a nuclear medicine service, including basic infrastructure, suitable premises, reliable supply of electricity, maintenance of a steady temperature, dust exclusion for gamma cameras and radiopharmacy dispensaries. It offers clear guidance on human resources and training needs for medical doctors, technologists, radiopharmaceutical scientists, physicists and specialist nurses in the practice of nuclear medicine. The manual describes the requirements for safe preparation and quality control of radiopharmaceuticals. In addition, it contains essential requirements for maintenance of facilities and instruments, for radiation hygiene and for optimization of nuclear medicine operational performance with the use of working clinical protocols. The result is a comprehensive guide at an international level that contains practical suggestions based on the experience of professionals around the globe. This publication will be of interest to nuclear medicine physicians, radiologists, medical educationalists, diagnostic centre managers, medical physicists, medical technologists, radiopharmacists, specialist nurses, clinical scientists and those engaged in quality assurance and control systems in public health in both developed and developing countries

Fundamentals of nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Alazraki, N.P.; Mishkin, F.S.

1988-01-01

The book begins with basic science and statistics relevant to nuclear medicine, and specific organ systems are addressed in separate chapters. A section of the text also covers imaging of groups of disease processes (eg, trauma, cancer). The authors present a comparison between nuclear medicine techniques and other diagnostic imaging studies. A table is given which comments on sensitivities and specificities of common nuclear medicine studies. The sensitivities and specificities are categorized as very high, high, moderate, and so forth.

Fundamentals of nuclear medicine

International Nuclear Information System (INIS)

Alazraki, N.P.; Mishkin, F.S.

1988-01-01

The book begins with basic science and statistics relevant to nuclear medicine, and specific organ systems are addressed in separate chapters. A section of the text also covers imaging of groups of disease processes (eg, trauma, cancer). The authors present a comparison between nuclear medicine techniques and other diagnostic imaging studies. A table is given which comments on sensitivities and specificities of common nuclear medicine studies. The sensitivities and specificities are categorized as very high, high, moderate, and so forth

UK nuclear medicine survey, 1989/90

International Nuclear Information System (INIS)

Elliott, A.T.; Shields, R.A.

1993-01-01

A postal survey of UK nuclear medicine departments was carried out to obtain information on activity during the year 1989/90. A rise of 14% in the number of administrations of radiopharmaceuticals was found compared to 1982: a rise of 22% in imaging studies was offset by a 30% decrease in the number of nonimaging investigations. The estimated total number of administrations in the UK was 430 000. (author)

Quality approach in in vivo nuclear medicine - Certification V2010 - Methodological guide

International Nuclear Information System (INIS)

Abdelmoumene, Nafissa; Ferreol, Dominique; Blondet, Emmanuelle; Bonardel, Gerald; Bourrel, Francois; Broglia, Jean Marc; Guilabert, Nadine; Israel, Jean-Marc; Machacek, Catherine; Martineau, Antoine; Remy, Herve; Rousseliere, Francis; Abelmann, Caroline

2013-01-01

This document first presents the different components of the activity in in-vivo nuclear medicine: techniques (functional imagery, vectorized internal radiotherapy, cases outside the nuclear medicine department), team composition and missions, radiation protection regulations, benefits and risks. Then, it addresses the quality approach: quality management system defined according to a process-oriented approach, documentation. It proposes a sheet to assess the implementation of the quality approach. This sheet contains 129 criteria which are related to management (strategy, activity steering and coordination), to support functions (management of human resources and abilities, management of radioactive sources and wastes, radio-pharmacy within the nuclear medicine department, management of medical devices, information system), to patient taking on (management of appointments and patient identification, imagery examination justification, patient reception, patients presenting risks and peculiar situations, checking before radio-pharmaceutical drug administering, taking on for diagnosis purpose, taking for therapeutic purposes), and to assessment, analysis and improvement (management of undesirable events associated with cares, quality follow-up for continuous improvement)

Extremity exposure in nuclear medicine: Preliminary results of a European study

International Nuclear Information System (INIS)

Merce, M. S.; Ruiz, N.; Barth, I.; Carnicer, A.; Donadille, L.; Ferrari, P.; Fulop, M.; Ginjaume, M.; Gualdrini, G.; Krim, S.; Mariotti, F.; Ortega, X.; Rimpler, A.; Vanhavere, F.; Baechler, S.

2011-01-01

The Work Package 4 of the ORAMED project, a collaborative project (2008-11) supported by the European Commission within its seventh Framework Programme, is concerned with the optimisation of the extremity dosimetry of medical staff in nuclear medicine. To evaluate the extremity doses and dose distributions across the hands of medical staff working in nuclear medicine departments, an extensive measurement programme has been started in 32 nuclear medicine departments in Europe. This was done using a standard protocol recording all relevant information for radiation exposure, i.e. radiation protection devices and tools. This study shows the preliminary results obtained for this measurement campaign. For diagnostic purposes, the two most-used radionuclides were considered: 99m Tc) and 18 F. For therapeutic treatments, Zevalin R and DOTATOC (both labelled with 90 Y) were chosen. Large variations of doses were observed across the hands depending on different parameters. Furthermore, this study highlights the importance of the positioning of the extremity dosemeter for a correct estimate of the maximum skin doses. (authors)

Digital Nuclear Medicine

International Nuclear Information System (INIS)

Erickson, J.J.; Rollo, F.D.

1982-01-01

This book is meant ''to provide the most comprehensive presentation of the technical as well as clincial aspects of computerized nuclear medicine''. It covers basic applications, and advice on acquisition and quality control of nuclear medicine computer systems. The book evolved from a series of lectures given by the contributors during the computer preceptorship program at their institution, Vanderbilt University in Nashville

Nuclear medicine in Uzbekistan: Past, present and future

International Nuclear Information System (INIS)

Rasulova, N.; Khodjibekova, M.; Myasnik, B.; Pirnazarov, M.; Atadjanova, M.

2007-01-01

Full text: Uzbekistan is one of the biggest countries in Middle Asia with a population of about 26.5 million. Nuclear Medicine in Uzbekistan has a long history. The first Nuclear Medicine Departments were organized in the 1950s and spread quickly in the 1960's when the number grew to 22 nuclear medicine centres in whole country. They were equipped with probe renogram, scanners, multiprobes and anger gamma cameras. As far as the Nuclear Medicine Department of Republic Specialized Center of Surgery is concerned, it was organized in 1976 and the first equipment of the institution was the anger gamma camera, ''Nuclear Chicago,'' as well as the probe renogram and multiple probes. At that time, the spectre of Nuclear Medicine examinations included: renoscintigraphy with I-131 hippuran, thyroid scintigraphy with I-131, MUGA, hepatic scintigraphy with sulphur colloid and HIDA, lung perfusion and ventilation, lymphoscintigraphy of low extremities, radiography (investigation of central hemodynamic), dynamic brain perfusion, bone scintigraphy of bone transplant, selective radionuclide angiography (examination of peripheral microcirculation) and phleboscintigraphy of low extremities. Unfortunately, the situation changed during the first years of Uzbekistan independence (1991) due to the economic situation. The number of Nuclear Medicine Departments decreased to 10. However, the NM Department of Republic Specialised Center of Surgery never stopped its clinical and research work. Nonetheless, the number of examinations performed significantly dropped. A new era of Nuclear Medicine in Uzbekistan was started in 2000 when the IAEA approved the TC project ''Introduction of SPECT in Uzbekistan''. With the great help of IAEA, the Republic Specialised Center of Surgery received a single head SPECT gamma camera (E-CAM Siemens). Furthermore, under the next TC project ''Implementation of NM in Uzbekistan,'' the same Center received a second SPECT dual head gamma camera (Nucline Spirit

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Because nuclear medicine procedures are able to pinpoint molecular activity within the body, they offer the potential ... or imaging device that produces pictures and provides molecular information. In many centers, nuclear medicine images can ...

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... child is taking as well as vitamins and herbal supplements and if he or she has any ... What are the limitations of Children's (Pediatric) Nuclear Medicine? Nuclear medicine procedures can be time consuming. It ...

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... MRI. top of page What are some common uses of the procedure? Children's (pediatric) nuclear medicine imaging ... at birth) or that develop during childhood. Physicians use nuclear medicine imaging to evaluate organ systems, including ...

Handbooks in radiology: Nuclear medicine

International Nuclear Information System (INIS)

Datz, F.L.

1988-01-01

This series of handbooks covers the basic facts, major concepts and highlights in seven radiological subspecialties. ''Nuclear Medicine'' is a review of the principles, procedures and clinical applications that every radiology resident and practicing general radiologist should know about nuclear medicine. Presented in an outline format it covers all of the organ systems that are imaged by nuclear medicine

Physical aspects of quality assurance in nuclear medicine and radiotherapy, regulatory approach of the National Nuclear Safety Center

International Nuclear Information System (INIS)

Gonzalez C, D.; Fuente P, A. de la; Quevedo G, J.R.; Lopez F, Y.; Varela C, C.

2006-01-01

The physical aspects of the quality guarantee in Nuclear Medicine and Radiotherapy its are of cardinal importance to guarantee the quality of the diagnoses and treatments that are carried out to the patients in this type of services. The OIEA, the OMS and other scientific and professional organizations have contributed significantly to the elaboration of recommendations, Protocols, etc. applicable in the quality control programs and safety of the Nuclear Medicine and Radiotherapy departments. In spite of the great effort developed in this sense the Installation of the programs of quality control and safety of the Nuclear Medicine and Radiotherapy departments can fail if the same ones are not based in three decisive elements that are: the existence of national regulations, the existence of the infrastructure required for it and the existence of enough qualified personnel to develop this programs. The present work shows the regulatory focus that on this topic, it has followed the National Center of Nuclear Safety of Cuba (CNSN). The same left of strengthen all the existent Synergies in the different organizations of the country and it went in two fundamental directions: installation of the regulatory requirements that govern this activity and the Authorization of a Cuban Entity, specialized in carrying out audits to the quality control and safety programs of the Nuclear Medicine and Radiotherapy departments. After 4 work years in this direction, the results confirm the validity of the experience developed by the CNSN, at the moment all the services of Nuclear Medicine and Radiotherapy of Cuba possess quality control and safety programs, these programs are annually Auditing by an Authorized entity by the CNSN and the Inspectors of the Regulatory Authority, control, during the inspections, the one execution of the established requirements in the national regulations. The work developed so far can serve, modestly, of reference to others countries of Latin America that

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... Tell your doctor about your child’s recent illnesses, medical conditions, medications and allergies. Depending on the type ... Nuclear Medicine? Nuclear medicine is a branch of medical imaging that uses small amounts of radioactive material ...

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... Nuclear Medicine Children’s (pediatric) nuclear medicine imaging uses small amounts of radioactive materials called radiotracers, a special ... is a branch of medical imaging that uses small amounts of radioactive material to diagnose and determine ...

Nuclear Medicine Annual, 1989

International Nuclear Information System (INIS)

Freeman, L.M.; Weissmann, H.S.

1989-01-01

Among the highlights of Nuclear Medicine Annual, 1989 are a status report on the thyroid scan in clinical practice, a review of functional and structural brain imaging in dementia, an update on radionuclide renal imaging in children, and an article outlining a quality assurance program for SPECT instrumentation. Also included are discussions on current concepts in osseous sports and stress injury scintigraphy and on correlative magnetic resonance and radionuclide imaging of bone. Other contributors assess the role of nuclear medicine in clinical decision making and examine medicolegal and regulatory aspects of nuclear medicine

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... Nuclear Medicine? Nuclear medicine is a branch of medical imaging that uses small amounts of radioactive material to ... a radiologist or other physician. To locate a medical imaging or radiation oncology provider in your community, you ...

The main rules regarding the management of solid waste and liquid effluent contaminated during use at nuclear medicine departments; Les principales regles de gestion des dechets solides et des effluents liquides contamines dans les services de medecine nucleaire

Energy Technology Data Exchange (ETDEWEB)

Boudouin, E. [Autorite de Surete Nucleaire, Direction des rayonnements ionisants et de la sante, 75 - Paris (France)

2011-02-15

This article describes the key requirements applicable to the management of contaminated medical waste and effluent from hospitals and health care centres, and more especially from nuclear medicine departments that use radionuclides for the purposes of diagnosis (in vivo or in vitro) or in patient treatment. It also presents the key management regulations, making a distinction between contaminated solid waste and contaminated liquid waste from such nuclear medicine departments. (author)

Nuclear medicine. 1 part. Manual

International Nuclear Information System (INIS)

Shlygina, O.E.; Borisenko, A.R.

2006-01-01

Current manual is urged to give wide-scale readers a submission on a key principles and methods of nuclear medicine, and it opportunities and restrictions in diagnostics and treatment of different diseases. Nuclear medicine is differing first of all by combination of diverse knowledge fields: special knowledge of a doctor, knowledge of physical processes bases, related with radiation, grounds of radiopharmaceutics, dosimetry. In the base of the book the 5th edition of 'Nuclear medicine' manual in 2 parts of German authors - Schicha, G.; Schober, O. is applied. In the book publishing the stuff of the Institute of Nuclear Physics of the National Nuclear Center of Republic of Kazakhstan has been worked. Modifications undergo practically all chapters: especially the second one, forth and sixth was enlarged. The 1 part of the book was published due to support of IAEA within the Technical cooperation project 'Implementation of Nuclear Medicine and Biophysics Center' (KAZ/6/007). The manual second part - devoted to applications of nuclear medicine methods for diagnostics and treatment - will be published in 2007

Veterinary nuclear medicine

International Nuclear Information System (INIS)

Kallfelz, F.A.; Comar, C.L.; Wentworth, R.A.

1974-01-01

A brief review is presented of the expanding horizons of nuclear medicine, the equipment necessary for a nuclear medicine laboratory is listed, and the value of this relatively new field to the veterinary clinician is indicated. Although clinical applications to veterinary medicine have not kept pace with those of human medicine, many advances have been made, particularly in the use of in vitro techniques. Areas for expanded applications should include competitive protein binding and other in vitro procedures, particularly in connection with metabolic profile studies. Indicated also is more intensive application by the veterinarian of imaging procedures, which have been found to be of such great value to the physician. (U.S.)

Radiation protection in nuclear medicine

International Nuclear Information System (INIS)

Corstens, F.

1989-01-01

Aspects of radiation protection in nuclear medicine and the role of the Dutch Society for Nuclear Medicine in these are discussed. With an effective dose-equivalence of averaged 3 mSv per year per nuclear medical examination and about 200.000 examinations per year in the Netherlands, nuclear medicine contributes only to a small degree to the total averaged radiation dose by medical treating. Nevertheless from the beginning, besides to protection of environment and personnel, much attention has been spent by nuclear physicians to dose reduction with patients. Replacing of relatively long living radionuclides like 131 I by short living radionuclides like 99m Tc is an example. In her education and acknowledgement policy the Dutch Society for Nuclear Medicine spends much attention to aspects of radiation reduction. (author). 3 tabs

Optimization of radiation protection (OPR) of workers in nuclear medicine department occupationally to ionizing radiation

International Nuclear Information System (INIS)

Ugrinska, Ana; Crcareva, Biljana; Andonovski, Boris

2010-01-01

Occupational radiation exposure of nuclear medicine personnel arise either from external irradiation during the handling or from the entry of radioactive substances in the body; the major source of external irradiation is the patient that has received a radiopharmaceutical for diagnostic or therapeutic purposes. In this study we present the dosimetry monitoring of the personnel at the Institute of Pathophysiology and Nuclear Medicine in Skopje (IPNM) before and after the implementation the methods of ORP. Twenty-seven employees were optimized with standard TLD card, monthly, expressed as whole body personal dose in the period of use of dosimeter. Annual Effective Doses (AED) are presented for years: 2001, 2004, 2005, 2006, 2007, 2008. In the year 2005, after measurement from Technical Service Organization, IPNM Radiation Protection Officer (RPO) designed and implemented new recommendation and modality such as: designation of areas, introducing ambiental dose measurements, classification of employees, personnel rotation, risk assessment, occupational dose constraints, education of personnel, compliance with written procedures and establishing the Programme for Radiation Protection (RP). ORP measures were applied during the year of 2006, so the results of 2001, 2004 and 2005 correspond to unopimized RP. We were evaluated three groups: radiopharmacy laboratory (RPL), nuclear medicine technologist (NMT) and medical doctors. The third group was further divided according to the AED in group with AED bellow 1.6 mSv (MD1), and group with AED above this level (MD2). The average AED in the NMT group for 2005 was 3.59 mSv, while in 2008 it was 1.8 mSv; for MD1 group in 2005 was 1.5 mSv and in MD2 was 3.0 mSv. The average AED in 2008 for MD1 was 1.1 mSv, while MD2 group comprised of only one subject with annual effective dose of 1.76 mSv. The most exposed groups were nuclear medicine technologists (NMT) and medical doctors routinely involved in everyday nuclear medicine

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... What are some common uses of the procedure? Children's (pediatric) nuclear medicine imaging is performed to help diagnose childhood disorders that are congenital (present at birth) or that develop during childhood. Physicians use nuclear medicine imaging to ...

Nuclear energy and medicine

International Nuclear Information System (INIS)

1988-01-01

The applications of nuclear energy on medicine, as well as the basic principles of these applications, are presented. The radiological diagnosis, the radiotherapy, the nuclear medicine, the radiological protection and the production of radioisotopes are studied. (M.A.C.) [pt

Children's (Pediatric) Nuclear Medicine

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Full Text Available ... referring physician. top of page What are the benefits vs. risks? Benefits The information provided by nuclear medicine examinations is ... risk is very low compared with the potential benefits. Nuclear medicine diagnostic procedures have been used for ...

Exposure of ionizing radiation to non-radiation workers from nuclear medicine patients

International Nuclear Information System (INIS)

Janssen, J.; Smart, R.C.; McKay, E.

1999-01-01

Full text: Occasionally, patients are required to have several tests in one day. They may be injected with radio-isotopes in the morning, have other investigations during the absorption period and then return to nuclear medicine for imaging later in the day. Recently, the NSW Department of Health issued a circular concerning exposure to sonographers from ionizing radiation emitted from nuclear medicine patients. The object of this study is to establish a model of emissions from nuclear medicine patients and to measure the exposure to other health workers who may be in close contact with these patients. Dose rate measurements were acquired for patients injected with 99 Tc m and 67 Ga for the following studies: heart, thyroid, lung, bone, biliary and lymphoma. Measurements were taken at 10 cm increments to 1 m and at time intervals of 0,1,2 and 24 h post-injection. In addition, 5 sonographers were issued with TLDs to be worn on the waist and fingers for a period of 3 months. The dose limit for a non-radiation worker is 1000 μSv (ICRP 60). The external dose rate measurements indicate that, assuming a sonographer is seated approximately 30 cm from a patient injected with 800 MBq 99 Tc m -HDP for a bone scan, 1 h post-injection, the sonographer would receive a dose of 11 μSv for a 30 min ultrasound scan. In practice, only 4 nuclear medicine patients were scanned in the ultrasound department during the 5 week monitoring period and the sonographers' TLDs recorded no radiation dose. In conclusion, the average exposure to sonographers from nuclear medicine patients is well within the limits recommended by the ICRP. However, in accordance with the ALARA principle where practicable, any ultrasound examination should be performed prior to nuclear medicine studies

Technetium{sup 99m} shortage: Practical solutions to manage lack of the radio-isotope in nuclear medicine departments; Penurie de technetium{sup 99m}: des pistes pratiques pour gerer les periodes de crise dans les services de medecine nucleaire

Energy Technology Data Exchange (ETDEWEB)

Biechlin-Chassel, M.L. [Radiopharmacie, service de pharmacie, centre hospitalier de Chambery, 73 - Chambery (France); Francois-Joubert, A. [Service de medecine nucleaire, centre hospitalier de Chambery, 73 - Chambery (France); Bolot, C. [Service de radiopharmacie, service pharmaceutique, centre de medecine nucleaire, groupement hospitalier Est, 69 - Bron (France); Desruet, M.D. [Radiopharmacie, service de medecine nucleaire, CHU de Grenoble, 38 - Grenoble (France); Bourrel, F. [Services de pharmacie et medecine nucleaire, centre hospitalier d' Avignon, 84 - Avignon (France); Pelegrin, M. [Institut de recherche en cancerologie (IRCM), 34 - Montpellier (France); Inserm U896, universite Montpellier 1, 34 - Montpellier (France); CRLC Val d' Aurelle Paul-Lamarque, 34 - Montpellier (France); Couret, I. [Service de medecine nucleaire, hopital Lapeyronie, 34 - Montpellier (France); Lao, S. [Service de medecine nucleaire, CHU Hopital de l' Archet, 06 - Nice (France); Quelven, I. [Faculte de medecine, 87 - Limoges (France)

2010-11-15

Technetium{sup 99m} ({sup 99m}Tc) shortage crisis regularly affect nuclear medicine activity and oblige the community to find solutions in order to perform most of the prescribed exams and avoid systematic substitutions by other non-nuclear medicine techniques. Firstly, some practical solutions can be set up in radiopharmacy departments such as using more than two generators together, realizing fractionated elutions, preparing radiopharmaceuticals with elutions providing from different generators.. Then, it could be interesting to have a reflexion in nuclear medicine departments to convene patients the days when {sup 99m}Tc supply is sufficient, to pool some exams or to make substitutions with more available isotopes. (authors)

Results of the evaluation of the radiation protection in several nuclear medicine departments and recommendations for its optimization

International Nuclear Information System (INIS)

Bejerano, Gladys Lopez; Jova Sed, Luis; Diaz, Efren; jova@cphr.edu.cu

2001-01-01

For the evaluation of the radiological safety in several Nuclear Medicine departments a survey was processed and applied that gathers the related mainly to: aspect of the licensing and fulfillment of the establish in this, the program of individual radiologic monitoring and his evaluation, functions that serve to the radiologic protection system, program of qualification and training of the personnel, equipment and mean of radiation protection, program of monitoring of the area of work, characteristic of the premises, management of remainder radioactive, program of quality control, aspect related to the radiation protection in the procedure of diagnosis with the investigation; as well as to pregnant patients and those related to the investigation to accidental medical exhibitions. In the work a systematization of the main results had been done, insisting on the evaluation of the doses received by the workers occupational exposed. A comparison of the activities administered to the patients by different departments and the internationally recommended ones, explaining the found differences. In addition the main recommendations were exposed to obtain in these departments an optimization of the radiological safety

Staff and patient absorbed doses due to diagnostic nuclear medicine procedures

International Nuclear Information System (INIS)

Tabei, F.; Neshandar Asli, I.; Aghamiri, S.M.; Arbabi, K.

2004-01-01

Background: annual patient effective dose equivalent can be considered as a quantitative physical parameter describing the activities performed in each nuclear medicine department. annual staff dose equivalent could be also considered as a parameter describing the amount of radiation risk for performing the activities. We calculated the staff to patient dose equivalent ratio to be used as a physical parameter for quantification of ALARA law in nuclear medicine department. Materials and methods: as a part of nationwide study, this paper reports the staff and patient absorbed dose equivalents from diagnostic nuclear medicine examinations performed in four nuclear medicine department during 1999-2002. The type and frequency of examinations in each department were determined directly from hospital medical reports. Staff absorbed doses equivalents were calculated from regular personal dosimeter reports. Results: the total number of examinations increased by 16.7 % during these years. Annual patient collective dose equivalent increased about 13.0 % and the mean effective dose equivalent per exam was 3.61 ± 0.07 mSv. Annual total staff absorbed dose equivalent (total of 24 radiation workers) in four departments increased from 40.45 mSv to 47.81 mSv during four years that indicates an increase of about 20.6 %. The average of annual ratios of staff to patient effective dose equivalents in four departments were 1.83 x 10 -3 , 1.04 x 10 -3 , 3.28 x 10 -3 and 3.24 x 10 -3 , respectively, within a range of 0.9 x 10 -3 - 4.17 x 10 -3 . The mean value of ratios in four years was about 2.24 x 10 -3 ± 1.09 x 10 -3 that indicates the staff dose of about two 1000 th of patient dose. Conclusion: The mean value of ratios in four years was about 1.89 x 10 -3 ± 0.95 x 10 -3 indicating the staff dose of about one 1000 th of the patient dose. The staff to patient absorbed dose equivalent ratio could be used as a quantitative parameter for describing ALARA law in radiation protection and

Pediatric radiation exposure from diagnostic nuclear medicine examinations in Tehran

International Nuclear Information System (INIS)

Neshandar Asli, I.; Tabeie, F.

2005-01-01

As a part of a nationwide survey to estimate population exposure to radiation from diagnostic nuclear medicine in Iran, this paper presents the pediatric population radiation exposure due to nuclear medicine examinations in Tehran. Patients and methods: the effective dose equivalent, H E , was used to calculate the collective effective dose in pediatric patients undergoing nuclear medicine procedures, and the corresponding data were obtained from thirty out of thirty seven active nuclear medicine departments in Tehran. Results: annually about 5.26% of nuclear medicine examinations were performed on patients under 15 years of age in Tehran. The most frequent was renal examinations (38.2%), followed y thyroid (27.4%) and bone (26.7%). The annual collective H E for patients under 15 was 19.03 human-Sv, which contributed 3.96% to the collective H E for all patients. The contribution of renal, bone and thyroid examinations to the pediatric collective H E were 24.6% 48.8% and 13.5% respectively. The mean effective dose equivalent per pediatric patient was 3.75 mSv.Conclusion: Among the three most frequent examinations, the bone with a relative frequency of 27.4% constituted 48.8% of the collective H E , which was the highest absorbed dose per examination. The mean effective dose per examination for patients younger than 15 years was 67.9% of the adults

Assessment of knowledge of general practitioners about nuclear medicine

International Nuclear Information System (INIS)

Zakavi, R.; Derakhshan, A.; Pourzadeh, Z.

2002-01-01

Nuclear medicine is an important department in most of scientific hospitals in the world. Rapid improvement in the filed of nuclear medicine needs continuing education of medical students. We tried to evaluate the knowledge of general practitioners in the flied of nuclear medicine, hoping that this study help mangers in accurate planning of teaching programs. Methods and materials: We prepared a questionnaire with 14 questions regarding applications of nuclear medicine techniques in different specialities of medicine. We selected questions as simple as possible with considering the most common techniques and best imaging modality in some disease. One question in nuclear cardiology, one in lung disease, two questions in thyroid therapy, another two in gastrointestinal system, two in genitourinary system and the last two in nuclear oncology. Also 4 questions were about general aspects of nuclear medicine. We have another 4 questions regarding the necessity of having a nuclear medicine subject during medical study, the best method of teaching of nuclear medicine and the preferred method of continuing education. Also age, sex, graduation date and university of education of all subjects were recorded. Results: One hundred (General practitioners) were studied. including, 58 male and 42 female with age range of 27-45 years did . About 60% of cases were 27-30 years old and 40 cases were older than 40. Seventy two cases were graduated in the last 5 years. Mashad University was the main university of education 52 cases with Tehran University (16 cases) and Tabriz University (6 cases) in the next ranks. Also 26 cases were graduated from other universities. From four questions in the field of general nuclear nedione 27% were correctly answered to all questions, 37% correctly answered two questions and 10% had correct answered only one question. No correct answer was noted in 26% . correct answer was noted in 80% the held of nuclear cardiology and in 72% in the field of lung

Radioisotopes in nuclear medicine

International Nuclear Information System (INIS)

Samuel, A.M.

2002-01-01

Full text: A number of advances in diverse fields of science and technology and the fruitful synchronization of many a new development to address the issues related to health care in terms of prognosis and diagnosis resulted in the availability of host of modern diagnostic tools in medicine. Nuclear medicine, a unique discipline in medicine is one such development, which during the last four decades has seen exponential growth. The unique contribution of this specialty is the ability to examine the dynamic state of every organ of the body with the help of radioactive tracers. This tracer application in nuclear medicine to monitor the biological molecules that participate in the dynamic state of body constituents has led to a whole new approach to biology and medicine. No other technique has the same level of sensitivity and specificity as obtained in radiotracer technique in the study of in-situ chemistry of body organs. As modem medicine becomes oriented towards molecules rather than organs, nuclear medicine will be in the forefront and will become an integral part of a curative process for regular and routine application. Advances in nuclear medicine will proceed along two principal lines: (i) the development of improved sensitive detectors of radiation, powerful and interpretable data processing, image analysis and display techniques, and (ii) the production of exotic and new but useful radiopharmaceuticals. All these aspects are dealt with in detail in this talk

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... resume his/her normal activities after the nuclear medicine scan. If the child has been sedated, you will receive specific instructions ... usually mild. Nevertheless, you should inform the nuclear medicine personnel of any allergies your child may have or other problems that may have ...

Hand exposure to ionising radiation of nuclear medicine workers

International Nuclear Information System (INIS)

Wrzesien, M.; Olszewski, J.; Jankowski, J.

2008-01-01

The specific nature of work in nuclear medicine departments involves the use of isotopes and handling procedures, which contribute to the considerable value of an equivalent dose received, in particular, by the fingertips. Standard nuclear medicine department uses ring dosemeters placed usually at the base of the middle finger. The main aim of the study was to find out whether a relationship exists between the doses recorded by thermoluminescent detectors placed at various locations on the radio-pharmacists' hands and the doses recorded by the ring detectors, and to determine the character of that relationship. The correction factor represents a correction value to be used to calculate the doses which might be received by locations on the hand from the dose recorded by the ring dosemeter. The dose recorded by the ring dosemeter is on the average five times lower than that received by the fingertips of thumb, index and middle fingers. (authors)

Nuclear medicine in Ghana

International Nuclear Information System (INIS)

Affram, R.K.; Kyere, K.; Amuasi, J.

1991-01-01

The background to the introduction and application of radioisotopes in medicine culminating in the establishment of the nuclear Medicine Unit at the Korle Bu Teaching Hospital, Ghana, has been examined. The Unit has been involved in important clinical researches since early 1970s but routine application in patient management has not always been possible because of cost per test and lack of continuous availability of convertible currency for the purchase of radioisotopes which are not presently produced by the National Nuclear Research Institute at Kwabenya. The capabilities and potentials of the Unit are highlighted and a comparison of Nuclear Medicine techniques to other medical diagnostic and imaging methods have been made. There is no organised instruction in the principles of medical imaging and diagnostic methods at both undergraduate and postgraduate levels in Korle Bu Teaching Hospital which has not promoted the use of Nuclear Medicine techniques. The development of a comprehensive medical diagnostic and imaging services is urgently needed. (author). 18 refs., 3 tabs

Radionuclides for nuclear medicine: a nuclear physicists' view

Czech Academy of Sciences Publication Activity Database

Cantone, M.; Haddad, F.; Harissopoulos, S.; Jensen, M.; Jokinen, A.; Koster, U.; Lebeda, Ondřej; Ponsard, B.; Ratzinger, U.; Stora, T.; Tarkanyi, F.; Van Duppen, P.

2013-01-01

Roč. 40, 2 Supplement (2013), S257-S257 ISSN 1619-7070. [Annual Congress of the European Association of Nuclear Medicine (EANM). 19.10.2013-23.10.2013, Lyon] Institutional support: RVO:61389005 Keywords : nuclear physics for medicine * EANM * medical radionuclides Subject RIV: BG - Nuclear, Atomic and Molecular Physics, Colliders

The application of nuclear-medicine methods in veterinary medicine

International Nuclear Information System (INIS)

Simpraga, M.; Kraljevic, P.; Dodig, D.

1996-01-01

X-radiography and ultrasound imaging are well established and widely used in veterinary practice, but it is not the same situation with radioisotope imaging. In veterinary practice the above mentioned methods of nuclear medicine are developed only in two countries in Europe. That is not doubt due, so bar, to the difficulties in obtaining satisfactory supply of radioisotopes and to the relatively high cost of scanning equipment. However, in collaboration with the Department of Radiation Protection and Nuclear Medicine of the Medical Faculty in Zagreb, Croatia, we have chance to develop the use of those methods in clinical veterinary practice in Zagreb. That is way in this paper an overview of the application of radioisotopes imaging in veterinary medicine is given. In small animals skeletal changes, lung perusions, brain lesions, space occupying lesions in the liver and its function and hearth function can be usefully searched by a gamma camera and its associated computer. In equine practice scintigraphy of bones, liver, hearth, pulmonary circulation and ventilation is described. The largest amount of radioactive material is used during gamma camera scanning of the skeletons of horses. In this cases the radiation dose 1-2 m from the animal is approximately 3 μSv/h. That is why the protection of personal involved in radioisotope scanning in veterinary medicine must be also regulated by low of radiation protection. Also, the animals should be confined to a controlled area for 2-3 days after scanning before being returned to their owners. After this period the area must be cleaned. (author)

Managing medical treatment waste and effluent: the point of view of a nuclear medicine practitioner

International Nuclear Information System (INIS)

Karcher, G.

2011-01-01

The nuclear medicine department of the Nancy CHU hospital is one of the largest in France: 16.000 patients are welcomed each year and 4.000 persons undergo a tomography there. 5 shielded and isolated rooms, dedicated to Iodine 131 treatment, allow the care of 150 to 200 patients each year. The head of the nuclear medicine department gives his meaning about the new regulation on the management of radioactive effluents. According to him, regulations are necessary but the values of the imposed thresholds have to be scientifically justified. Another point is that a lot of money is spent on radiation protection issues while the radioactive risks are almost null, which leads to wasting money. The elaboration of the radioprotection regulations must be made not as a whole but on a specific basis according to the domain: nuclear power plants, research reactors or nuclear medicine, it applies. (A.C.)

Developments in nuclear medicine

International Nuclear Information System (INIS)

Elias, H.

1977-01-01

The article reports on the first international meeting about radiopharmaceutical chemistry in the Brookhaven National Laboratory, Long Island/USA, from 21st to 24th September, 1976. The meeting report is preceded by the explanation of the terms 'radiopharmaceutical chemistry' and 'nuclear medicine' and a brief survey of the history. The interdisciplinary connection of the spheres of nuclear physics, nuclear chemistry, biochemistry, nuclear medicine, and data processing is also briefly shown. This is necessary before radiodiagnosis can be made for a patient. (RB) [de

Nuclear medicine in developing nations

International Nuclear Information System (INIS)

Nofal, M.M.

1985-01-01

Agency activities in nuclear medicine are directed towards effectively applying techniques to the diagnosis and management of patients attending nuclear medicine units in about 60 developing countries. A corollary purpose is to use these techniques in investigations related to control of parasitic diseases distinctive to some of these countries. Through such efforts, the aim is to improve health standards through better diagnosis, and to achieve a better understanding of disease processes as well as their prevention and management. Among general trends observed for the region: Clinical nuclear medicine; Radiopharmaceuticals; Monoclonal antibodies; Radioimmunoassay (RIA); Nuclear imaging

Radiation protection in nuclear medicine

International Nuclear Information System (INIS)

Chougule, Arun

2014-01-01

The branch of medical science that utilizes the nuclear properties of the radioactivity and stable nuclides to make diagnostic evaluation of anatomical and/or physiological conditions of the body and provide therapy with unsealed radioactive sources is called Nuclear Medicine (NM). The use of unsealed radionuclides in medicine is increasing throughout the world for diagnosis and treatment. As per UNSCEAR report more than 6 million nuclear medicine procedures are conducted in a year. However we know that radiation is double edged sword and if not used carefully will be harmful to patient as well as staff and therefore a nuclear medicine procedure should be undertaken only after proper justification and optimization. Nuclear medicine procedures are different than the X-ray diagnostic procedures as in NM, radioisotope is administered to patient and patient becomes radioactive. The NM staff is involved in unpacking radioactive material, activity measurements, storage of sources, internal transports of sources, preparation of radiopharmaceuticals, administration of radiopharmaceutical, examination of the patient, care of the radioactive patient, handling of radioactive waste and therefore receives radiation dose. This talk will discuss the various steps for radiation safety of patient, staff and public during Nuclear Medicine procedures so as to implementing the ALARA concept. (author)

Nuclear Medicine Practice in Kenya

International Nuclear Information System (INIS)

Ndrirangu, T.T.

2017-01-01

Nuclear medicine is a medical specialty that relies on the use of nuclear technology in the diagnosis and treatment (therapy) of diseases. Nuclear medicine uses the principle that a certain radiopharmaceutical (tracer) will at a certain point in time have a preferential uptake by a particular body, tissue or cell. Unlike other radiation applications for medical use, nuclear medicine uses open (unsealed) sources of radiation. The tracer is introduced into the body of the patient through several routes (oral, intravenous, percutaneous, intradermally, inhalation, intracapsular etc) and s/he becomes the source of radiation. Early diagnosis of diseases coupled with associated timely therapeutic intervention will lead to better prognosis. In a country with an estimated population of 42 million in 2017, Kenya has only two (2) nuclear medicine facilities (units) that is Kenyatta National Hospital - Public facility and Aga Khan University Hospital which is a Private facility. Being a relatively new medical discipline in Kenya, several measures have been taken by the clinical nuclear medicine team to create awareness at various levels. Kenya does not manufacture radiopharmaceuticals. We therefore have to import them from abroad and this makes them quite expensive, and the process demanding. There is no local training in nuclear medicine and staff have to be sent abroad for training, making this quite expensive and cumbersome and the IAEA has been complimenting in this area. With concerted effort by all stakeholders at the individual, national and international level, it is possible for Kenya to effectively sustain clinical nuclear medicine service not only as a diagnostic tool in many disease entities, but also play an increasingly important role in therapy

Check-up and follow-up of papillary and follicular thyroid carcinoma in the department of nuclear medicine at Ibn Sina hospital Rabat

International Nuclear Information System (INIS)

Ben Rais Aouad, N.; Ghfir, I.; Guerrouj, H.; Fellah, S.; Rahali, J.; Ksyar, R.; Missoum, F.; Bssis, A.; Azrak, S.

2009-01-01

In the department of nuclear medicine at Ibn Sina university hospital. Thyroid carcinoma follow-up strategy has been modified and includes cervical ultrasonography and thyroglobulin measurement. The role of radio-iodine scanning in the management of differentiated thyroid carcinoma is decreasing. Papillary and follicular carcinoma have good prognosis but late metastases exist and can lead to death. A lifelong follow-up is therefore mandatory. The main goal of follow-up is to detect earlier persistent or recurrent disease. (authors)

Nuclear medicine

International Nuclear Information System (INIS)

Reichelt, H.G.

1980-01-01

Nuclear medicine as a complex diagnostical method is used mainly to detect functional organic disorders, to locate disorders and for radioimmunologic assays (RIA) in vitro. In surgery, its indication range comprises the thyroid (in vivo and in vitro), liver and bile ducts, skeletal and joint diseases, disorders of the cerebro-spinal liquor system and the urologic disorders. In the early detection of tumors, the search for metastases and tumor after-care, scintiscanning and the tumor marcher method (CEA) can be of great practical advantage, but the value of myocardial sciritiscanning in cardiac respectively coronary disorders is restricted. The paper is also concerned with the radiation doses in nuclear medicine. (orig.) [de

Nuclear Medicine at Charles Sturt University

International Nuclear Information System (INIS)

Swan, H.; Sinclair, P.; Scollard, D.

1998-01-01

Full text: A distance educational programme for upgrading of Certificate, Associate Diploma and Diploma to a Bachelor of Applied Science degree commenced in second semester of 1997 with approximately 15 Australian students and 15 Canadian students. The first graduation will occur in 1998. Formal links with the Michener Institute in Toronto have allowed Canadian students access to study resources during the course. All students entering the course are accredited or registered with their respective professional societies. The short conversion programme for those with three year diplomas includes Nuclear Medicine Physics and Instrumentation, Imaging Pathology, Clinical Neuroscience and Research Method subjects. An inaugural undergraduate degree programme in Nuclear Medicine Technology commences in first semester of 1998 on the Riverina Campus at Wagga Wagga. An intake of 15 students is anticipated. This small group of rural based students will have the benefits of international expertise. The programme has a strong clinical practice component including time on campus to supplement the practicum in departments. Physiology studies continue through to third year to complement the professional subjects. Active participation is solicited from those departments involved with aspects of the practicum well before students are placed. A fully functional teaching laboratory has been constructed containing a well equipped radiopharmacy, gamma camera room and computer laboratory using modern applications software to provide the students with a solid background in their chosen field

Knowledge Management in Nuclear Medicine

International Nuclear Information System (INIS)

Abaza, A.

2017-01-01

The last two decades have seen a significant increase in the demand for medical radiation services following the introduction of new techniques and technologies that has led to major improvements in the diagnosis and treatment of human diseases. The diagnostic and therapeutic applications of nuclear medicine techniques play a pivotal role in the management of these diseases, improving the quality of life of patients by means of an early diagnosis allowing opportune and proper therapy. On the other hand, inappropriate or unskilled use of these technologies can result in potential health hazards for patients and staff. So, there is a need to control and minimize these health risks and to maximize the benefits of radiation in medicine. The present study aims to discuss the role of nuclear medicine technology knowledge and scales in improving the management of patients, and raising the awareness and knowledge of nuclear medicine staff regarding the use of nuclear medicine facilities. The practical experience knowledge of nuclear medicine staff in 50 medical centers was reviewed through normal visiting and compared with the IAEA Published documents information. This review shows that the nuclear medicine staff has good technology knowledge and scales during managing patients as compared to IAEA Published information regarding the radiation protection measures and regulation. The outcome of the study reveals that competent authority can improve radiation safety in medical settings by developing and facilitating the implementation of scientific evidence-based policies and recommendations covering nuclear medicine technology focusing in the public health aspects and considering the risks and benefits of the use of radiation in health care. It could be concluded that concerted and coordinated efforts are required to improve radiation safety, quality and sustain ability of health systems

Safety assessment of nuclear medicine practice using the Risk Matrix Method

International Nuclear Information System (INIS)

Cruz, Dumenigo; Cruz, Yoanis; Soler, Karen; Guerrero, Mayka

2013-01-01

This paper presents the main results from the application of the methodology of Risk Matrices in a hypothetical service / department of the Nuclear medicine that realize metabolic radiotherapy treatment and diagnostic studies with 131 I and 99 m Tc and 18 F. We could identify major equipment failures and human errors that could potentially lead to a accident in practice. For each analyzed initiating events evaluated the frequency of occurrence, identified key existing defenses to avoid the accident and assessed the potential consequences of an accident if this comes to fruition. With this methodology we could identify which accident sequences increased risk and to propose means to reduce the risk in such cases. As a result of this work was developed the 'RMA Nuclear Medicine' computer tools that will apply this methodology in nuclear medicine services that need to do similar risk assessments

The liquidation of liquid radioactive waste on nuclear medicine departments

International Nuclear Information System (INIS)

Fueriova, A.

1995-01-01

The most serious problems for Clinic of Nuclear Medicine of National Oncological Institute, Bratislava (CNM) is the localization of CNM in the downtown, inside the hospital area with the dilution water deficit. This department is the only one in Slovak Republic performing therapeutical applications. To be able to perform the necessary amount of therapies and also to introduce a new therapeutical methods, in 1992-1994 the old liquidation waste disposal station (LWDS) was reconstructed with the aim to satisfy the newest requirements of radiation hygiene. LWDS is the 5-floor object partly underground which satisfied the requirements for liquidation of radioactive liquid waste from diagnostic procedures(annually 5000 patients) and also from 200 therapeutical applications annually (15 beds, 720 GBq iodine-131). The capacity of LWDS is able to store about 90 m 3 liquid radioactive waste. Part of the underground spaces are used for the storage of solid radioactive trash. The liquid waste from CNM is collected through isolated metal sewage system to the storage with continuous observation of water specific activity. According to the activity, the liquid waste is placed to the 5 decay storages with the volume about 15 m 3 . The six one serves for the case of technical accident. When the activity declines, the liquid waste is diluted with non active medical trash to the level which is acceptable by low about radiation hygiene protection. The storage walls are made from barium-concrete 25-50 cm thick which is enough for sufficient protection of operation staff and also for walking around persons. Double-layer high quality chemical material prevents the water leak and diffusion of radionuclides into the concrete. Technology consists of cast-iron drains, powerful slush pumps, operation valves, regulation technology from dosimetric system for continuous monitoring of specific activity, for managing system with powerful industrial computer

The liquidation of liquid radioactive waste on nuclear medicine departments

Energy Technology Data Exchange (ETDEWEB)

Fueriova, A [National Oncological Institue, Bratislava (Slovakia). Hospital St. Elis, Clinic of Nuclear Medicine

1996-12-31

The most serious problems for Clinic of Nuclear Medicine of National Oncological Institute, Bratislava (CNM) is the localization of CNM in the downtown, inside the hospital area with the dilution water deficit. This department is the only one in Slovak Republic performing therapeutical applications. To be able to perform the necessary amount of therapies and also to introduce a new therapeutical methods, in 1992-1994 the old liquidation waste disposal station (LWDS) was reconstructed with the aim to satisfy the newest requirements of radiation hygiene. LWDS is the 5-floor object partly underground which satisfied the requirements for liquidation of radioactive liquid waste from diagnostic procedures(annually 5000 patients) and also from 200 therapeutical applications annually (15 beds, 720 GBq iodine-131). The capacity of LWDS is able to store about 90 m{sup 3} liquid radioactive waste. Part of the underground spaces are used for the storage of solid radioactive trash. The liquid waste from CNM is collected through isolated metal sewage system to the storage with continuous observation of water specific activity. According to the activity, the liquid waste is placed to the 5 decay storages with the volume about 15 m{sup 3}. The six one serves for the case of technical accident. When the activity declines, the liquid waste is diluted with non active medical trash to the level which is acceptable by low about radiation hygiene protection. The storage walls are made from barium-concrete 25-50 cm thick which is enough for sufficient protection of operation staff and also for walking around persons. Double-layer high quality chemical material prevents the water leak and diffusion of radionuclides into the concrete. Technology consists of cast-iron drains, powerful slush pumps, operation valves, regulation technology from dosimetric system for continuous monitoring of specific activity, for managing system with powerful industrial computer.

Evolution of nuclear medicine: a historical perspective

International Nuclear Information System (INIS)

Ahmed, A.; Kamal, S.

1996-01-01

The field Nuclear Medicine has Completed its 100 yeas in 1996. Nuclear medicine began with physics, expanded into chemistry and instrumentation, and then greatly influenced various fields of medicine. The chronology of the events that formulated the present status of nuclear medicine involves some of the great pioneers of yesterday like Becquerel, Curie, Joliot, Hevesy, Anger, Berson and Yallow. The field of nuclear medicine has been regarded as the bridge builder between various aspects of health care and within next 20 years, nuclear medicine enters a new age of certainty, in which surgery, radiation and chemotherapy will only be used when a benefit in certain to result from the treatment. (author)

Pediatric nuclear medicine

International Nuclear Information System (INIS)

1986-01-01

This symposium presented the latest techniques and approaches to the proper medical application of radionuclides in pediatrics. An expert faculty, comprised of specialists in the field of pediatric nuclear medicine, discussed the major indications as well as the advantages and potential hazards of nuclear medicine procedures compared to other diagnostic modalities. In recent years, newer radiopharmaceuticals labeled with technetium-99m and other short-lived radionuclides with relatively favorable radiation characteristics have permitted a variety of diagnostic studies that are very useful clinically and carry a substantially lower radiation burden then many comparable X-ray studies. This new battery of nuclear medicine procedures is now widely available for diagnosis and management of pediatric patients. Many recent research studies in children have yielded data concerning the effacacy of these procedures, and current recommendations will be presented by those involved in conducting such studies. Individual papers are processed separately for the Energy Data Base

Pediatric nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

1986-01-01

This symposium presented the latest techniques and approaches to the proper medical application of radionuclides in pediatrics. An expert faculty, comprised of specialists in the field of pediatric nuclear medicine, discussed the major indications as well as the advantages and potential hazards of nuclear medicine procedures compared to other diagnostic modalities. In recent years, newer radiopharmaceuticals labeled with technetium-99m and other short-lived radionuclides with relatively favorable radiation characteristics have permitted a variety of diagnostic studies that are very useful clinically and carry a substantially lower radiation burden then many comparable X-ray studies. This new battery of nuclear medicine procedures is now widely available for diagnosis and management of pediatric patients. Many recent research studies in children have yielded data concerning the effacacy of these procedures, and current recommendations will be presented by those involved in conducting such studies. Individual papers are processed separately for the Energy Data Base.

Nuclear medicine tomorrow

International Nuclear Information System (INIS)

Marko, A.M.

1986-04-01

The purpose of this Workshop was to discuss and promote future nuclear medicine applications. Atomic Energy of Canada Limited (AECL) is determined to assist in this role. A major aim of this gathering was to form an interface that was meaningful, representative of the two entities, and above all, on-going. In the opening address, given by Mr. J. Donnelly, President of AECL, this strong commitment was emphasized. In the individual sessions, AECL participants outlined R and D programs and unique expertise that promised to be of interest to members of the nuclear medicine community. The latter group, in turn, described what they saw as some problems and needs of nuclear medicine, especially in the near future. These Proceedings comprise the record of the formal presentations. Additionally, a system of reporting by rapporteurs insured a summary of informal discussions at the sessions and brought to focus pertinent conclusions of the workshop attendees

Current role of the radiographers in imaging diagnostics, nuclear medicine and radiotherapy in modern departments

International Nuclear Information System (INIS)

Karidova, S.; Velkova, K.; Panamska, K.; Petkova, K.

2006-01-01

Full text: In the communication we set out to focus the attention of the medical staff and the public on the place and the constantly growing role (relative burden) of the radiographers in imaging diagnostics, nuclear medicine and radiotherapy in the field of modern medicine. The advanced radiographers level and rapid development of the contemporary equipment and apparatuses used in imaging diagnostics, nuclear medicine and radiotherapy, as well as the methods of their utilization, presuppose very good and constantly improving theoretical and practical training of the imaging technician. The radiographer fulfills responsible tasks under the guidance of the physician or independently and bears specific responsibilities. Having mastered the fundamentals of radiation protection, the imaging technician protects both himself and the patient from the impact of ionizing radiation. To be able to fulfill his/her constantly increasing duties and obligations, the imaging radiographer has acquired wide knowledge of general education subjects, subjects of general medicine and special subjects. The radiographer has a good knowledge of Latin and a modern foreign language, and he is also computer literate so as to be able to cope with the widely spread visualizing methods. The radiographer acquires additional post-graduate training to work in narrowly specialized fields as well as to improve his/her qualifications

Introductory physics of nuclear medicine. Third edition

International Nuclear Information System (INIS)

Chandra, R.

1987-01-01

The new third edition includes essential details and many examples and problems taken from the routine practice of nuclear medicine. Basic principles and underlying concepts are explained, although it is assumed that the reader has some current use as a bone densitometer. For resident physicians in nuclear medicine, residents in pathology, radiology, and internal medicine, and students of nuclear medicine technology, the third edition offers a simplified and reliable approach to the physics and basic sciences of nuclear medicine

Technetium in chemistry and nuclear medicine

International Nuclear Information System (INIS)

Deutsch, E.; Nicolini, M.; Wagner, H.N.

1983-01-01

This volume explores the potential of technetium radiopharmaceuticals in clinical nuclear medicine. The authors examine the capabilities of synthetic inorganic chemists to synthesize technetium radiopharmaceuticals and the specific requirements of the nuclear medicine practitioner. Sections cover the chemistry of technetium, the production of radiopharmaceuticals labeled with technetium, and the use of technetium radiopharmaceuticals in nuclear medicine

Recent history of nuclear medicine

International Nuclear Information System (INIS)

Potchen, E.J.; Gift, D.A.

1988-01-01

Diagnostic nuclear medicine's recent history is characterized both by significant change and by growing participation in efforts to quantify the impact of nuclear medicine procedures on clinical judgment and patient management, as well as to develop methods for studying the efficacy of diagnostic procedures in general. The replacement of many nuclear medicine procedures that at one time were considered essential standards of clinical care by newer, more efficient and effective modalities has been complimented by the continued development of increasingly sophisticated applications of scintigraphic tracer methods

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... you about nuclear medicine. Nuclear medicine offers the potential to identify disease in its earliest stage, often ... may be asked to wear a gown as well. Tell your doctor if there is any possibility ...

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... Nuclear Medicine Transcript Welcome to Radiology Info dot org Hello! I’m Dr. Ramji Rajendran, a radiation ... more about nuclear medicine, visit Radiology Info dot org. Thank you for your time! Spotlight Recently posted: ...

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... stage, often before symptoms occur or before abnormalities can be detected with other diagnostic tests. Nuclear medicine ... nuclear medicine exam, there are several things you can do to prepare. First, you may be asked ...

Accuracy determination of dose calibrators in Nuclear Medicine Centers using Tl-201

International Nuclear Information System (INIS)

Sattari, A.; Feizi, H.; Ghafoori, M.

2008-01-01

Full text: Correct administrated activity of radiopharmaceuticals is an important factor to ensure that administrated radiopharmaceutical is accurately measured and to avoid unnecessary exposure to patients. In this article, nuclear medicine group and Secondary Standard Dosimetry Laboratory (SSDL), has introduced a comparison study with 201 Tl to check the accuracy of dose calibrators in some nuclear medicine centers. First, the dose calibrator in cyclotron department was calibrated by SSDL using 133 Ba, 57 Co, 137 Cs and standard Europium sources. Then, 2ml produced 201 Tl solution containing 16±0.1 mCi was accurately sub-divided into a series of 10 ml Schott vials and delivered to 12 nuclear medicine centers that have been participated in this study. Participants were requested to assay their Schott vials in their dose calibrators at the same time and report the result on the especial sheet. Difference between the activities values reported by participants (A p ) with assayed activity on cyclotron department (Ac), defined as error value. In comparison of A c with A p , 10 centers (83%) has positive and 2 others (17%) has negative error. The range of positive error 2.6% -17.9% and range of negative error 5%-8.5%, by the average of 8.67 and %SD = 7.39 have been calculated. In conclusion, although nuclear medicine centers do calibration on their dose calibrators but establishment a regular audit system seems to be necessary. (author)

In vivo mutagenicity and clastogenicity of ionizing radiation in nuclear medicine

International Nuclear Information System (INIS)

Kelsey, K.T.

1991-01-01

The overall goal of our research was to investigate the mutagenic and clastogenic effects of exposure to low levels of ionizing radiation to human lymphocytes. Principally, we studied hospital patients referred to a nuclear medicine department for diagnostic cardiac imaging and nuclear medicine technologists who administer radionuclides. Emphasis in the first year, as described in the first progress report, was on optimization of the hprt mutation assay, measurement of mutant frequencies in patients imaged with thallium-201, and measurement of mutant frequencies in controls. Emphasis in the second and third years was on measurements of: (1) chromosome aberrations in patients imaged with thallium-201; (2) mutant frequencies in patients imaged with technetium-99; (3) mutant frequencies in nuclear medicine technicians and physical therapists; and (4) mutant frequencies in patients treated for Hodgkins disease with radiotherapy. The completed work has been published and is described below in more detail

Estimated collective effective dose to the population from nuclear medicine examinations in Slovenia

International Nuclear Information System (INIS)

Skrk, Damijan; Zontar, Dejan

2013-01-01

A national survey of patient exposure from nuclear medicine diagnostic procedures was performed by Slovenian Radiation Protection Administration in order to estimate their contribution to the collective effective dose to the population of Slovenia. A set of 36 examinations with the highest contributions to the collective effective dose was identified. Data about frequencies and average administered activities of radioisotopes used for those examinations were collected from all nuclear medicine departments in Slovenia. A collective effective dose to the population and an effective dose per capita were estimated from the collected data using dose conversion factors. The total collective effective dose to the population from nuclear medicine diagnostic procedures in 2011 was estimated to 102 manSv, giving an effective dose per capita of 0.05 mSv. The comparison of results of this study with studies performed in other countries indicates that the nuclear medicine providers in Slovenia are well aware of the importance of patient protection measures and of optimisation of procedures

Single-purpose nuclear medicine instruments

International Nuclear Information System (INIS)

Boucek, J.

Nuclear medicine requires the most up-to-date specialized technical facilities. The paper underlines the factor of reliability in purpose-designed equipment used for basic examinations. The possibility is also discussed of the automation of standard nuclear medicine instruments

[Introduction of a quality management system compliant with DIN EN 9001:2000 in a university department of nuclear medicine].

Science.gov (United States)

Jansen-Schmidt, V; Paschen, U; Kröger, S; Bohuslavizki, K H; Clausen, M

2001-12-01

In 1995, the management of the University Clinic Hamburg-Eppendorf proposed to establish a total quality assurance (QA) system. A revised QA-system has been introduced stepwise in the department of nuclear medicine since 1997, and certification was achieved in accordance with DIN EN ISO 9001:2000 on February 14, 2001. The QA-handbook is divided into two parts. The first part contains operational (diagnostic and therapeutic) procedures in so-called standard operating procedures (SOP). They describe the indication of procedures as well as the competences and time necessary in a standardized manner. Up to now, more than 70 SOPs have been written as a collaborative approach between technicians and physicians during daily clinical routine after analysing and discussing the procedures. Thus, the results were more clearly defined processes and more satisfied employees. The second part consists of general rules and directions concerning the security of work and equipment as well as radiation protection tasks, hygiene etc. as it is required by the law. This part was written predominantly by the management of the department of nuclear-medicine and the QA-coordinator. Detailed information for the patients, documentation of the work-flows as well as the medical report was adopted to the QM-system. Although in the introduction phase of a QA-system a vast amount of time is necessary, some months later a surplus for the clinical workday will become available. The well defined relations of competences and procedures will result in a gain of time, a reduction of costs and a help to ensure the legal demands. Last but not least, the QA-system simply helps to build up confidence and acceptance both by the patients and the referring physicians.

Nuclear medicine

International Nuclear Information System (INIS)

Casier, Ph.; Lepage, B.

1998-01-01

Except for dedicated devices for mobile nuclear cardiology for instance, the market is set on variable angulation dual heads cameras. These cameras are suited for all general applications and their cost effectiveness is optimized. Now, all major companies have such a camera in their of products. But, the big question in nuclear medicine is about the future of coincidence imaging for the monitoring of treatments in oncology. Many companies are focused on WIP assessments to find out the right crustal thickness to perform both high energy FDG procedures and low energy Tc procedures, with the same SPECT camera. The classic thickness is 3/8''. Assessments are made with 1/2'', 5/8'' or 3/4'' crystals. If FDG procedures proved to be of great interest in oncology, it may lead to the design of a dedicated SPECT camera with a 1'' crustal. Due to the short half of FDG, it may be the dawning of slip ring technology. (e.g. Varicam from Elscint). The three small heads camera market seems to be depressed. Will the new three large heads camera unveiled by Picker, reverse that trend? The last important topic in nuclear medicine is the emergence of new flat digital detectors to get rid of the old bulky ones. Digirad is the first company to manufacture a commercial product based on that technology. Bichron, Siemens and General Electric are working on that development, too. But that technology is very expensive and the market for digital detection in nuclear medicine is not as large as the market in digital detection in radiology. (author)

Cardiovascular nuclear medicine and MRI

International Nuclear Information System (INIS)

Reiber, J.H.C.; Wall, E.E. van der

1992-01-01

This book is based on a meeting of the Working Group on Nuclear Cardiology, which held March 22-23,1991 under the auspices of the European Society of Cardiology and the Interuniversity Cardiology Institute of the Netherlands, and on the Second International Symposium on Computer Applications in Nuclear Medicine and Cardiac Magnetic Resonance Imaging, which was held March 20-22,1991 in Rotterdam, the Netherlands. It covers almost every aspect of quantitative cardio-vascular nuclear medicine and magnetic resonance imaging. The main topics are: single photon emission computed tomography (technical aspects); new development in cardiovascular nuclear medicine; advances in cardiovascular imaging; cardiovascular clinical applications; and cardiac magnetic resonance imaging. (A.S.). refs.; figs.; tabs

Quality policy at nuclear medicine services

International Nuclear Information System (INIS)

Gil Martinez, Eduardo Manuel; Jimenez, Tomas

2007-01-01

In the present text we comment about a Quality Policy model to establish in a Nuclear Medicine Service. The need for a strict control in every process that take place in a Nuclear Medicine Service, requires of an exact planification in terms of Quality Policy, specific to the real needs of every Service. Quality Policy must be a live Policy, with capability of changes and must be known for every workers in a Nuclear Medicine Service. Although the 'model' showed in this text is concret for a specific Service type, it must be extrapolated to any Nuclear Medicine Service with the necessary changes (au)

A DICOM based PACS for nuclear medicine; Ein DICOM-basiertes PACS fuer die Nuklearmedizin

Energy Technology Data Exchange (ETDEWEB)

Lassmann, M.; Reiners, C. [Wuerzburg Univ. (Germany). Klinik und Poliklinik fuer Nuklearmedizin

2002-02-01

The installation of a radiology information system (RIS) connected to a hospital information system (HIS) and a picture archiving and communications system (PACS) seems mandatory for a nuclear medicine department in order to guarantee a high patient throughput. With these systems a fast transmission of reports, images to the in- and out-patients' wards and private practitioners is realized. Therefore, since April 2000, at the department of nuclear medicine of the university of Wuerzburg a completely DICOM based PACS has been implemented in addition to the RIS. With this system a DICOM based workflow is realized throughout the department of nuclear medicine for reporting and archiving. The PACS is connected to six gamma-cameras, a PET scanner, a bone densitometry system and an ultrasound device. The volume of image data archived per month is 4 GByte. Patient demographics are provided to the modalities via DICOM-Worklist. With these PACS components a department specific archive purely based on DICOM can be realized. During the installation process problems occurred mainly because of the complex DICOM standard for nuclear medicine. Related to that is the problem that most of the software implementations still contain bugs or are not adapted to the needs of a nuclear medicine department (particularly for PET). A communication software for the distribution of nuclear medicine reports and images based on techniques used for the worldwide web is currently tested. (orig.) [German] Fuer eine nuklearmedizinische Klinik ist ein Klinikinformationssystem (KIS) gekoppelt mit einem Radiologieinformationssystem (RIS) sowie einem Bildarchivierungs- und Verteilungssystem (PACS) unabdingbar, um einen schnellen Patientendurchsatz sowie die zeitnahe Uebermittlung von Befunden inklusive nuklearmedizinischen Bildern an zuweisende Stationen, Ambulanzen und externe Zuweiser zu gewaehrleisten. Daher wurde im April 2000 an der Klinik und Poliklinik fuer Nuklearmedizin der Universitaet

Conception of a computer for the nuclear medical department of the Augsburg hospital center

International Nuclear Information System (INIS)

Graf, G.; Heidenreich, P.

1984-01-01

A computer system based on the Siemens R30 process computer has been employed at the Institute of Nuclear Medicine of the Augsburg Hospital Center since early 1981. This system, including the development and testing of organ-specific evaluation programs, was used as a basis for the conception of the new computer system for the department of nuclear medicine of the Augsburg Hospital Center. The computer system was extended and installed according to this conception when the new 1400-bed hospital was opened in the 3rd phase of construction in autumn 1982. (orig.) [de

Nuclear medicine applications: Summary of Panel 4

International Nuclear Information System (INIS)

Wolf, A.P.

1988-01-01

Nuclear medicine is currently facing a desperate shortage of organic and inorganic chemists and nuclear pharmacists who also have advanced training in nuclear and radiochemistry. Ironically, this shortfall is occurring in the face of rapid growth and technological advances which have made the practice of nuclear medicine an integral part of the modern health care system. This shortage threatens to limit the availability of radiopharmaceuticals required in routine hospital procedures and to impede the development of new diagnostic and therapeutic agents. To redress this need and prevent a similar shortfall in the future, this panel recommends immediate action and a long-term commitment to the following: educating the public on the benefits of nuclear medicine; informing undergraduate and graduate chemistry students about career opportunities in nuclear medicine; offering upper level courses in nuclear and radiochemistry (including laboratory) in universities; establishing training centers and fellowships at the postgraduate level for specialized education in the aspects of nuclear and radiochemistry required by the nuclear medicine profession. 1 tab

Radiation management for infectious waste from nuclear medicine studies

International Nuclear Information System (INIS)

Kondo, Yuji; Takeuchi, Yasuyuki; Masumoto, Kazuya

2003-01-01

An industrial waste management service has refused to collect medical waste from our hospital owing to radioactive contamination found in the waste in July 2000. An investigation revealed that the ''three-way stopcock'' and handling diapers used for radioisotope examination were the radioactive contaminants. We therefore reconsidered the system of medical waste maintenance especially for radioactive materials. Since February 2001, we have resumed radiation maintenance by following the manual for the handling diapers of patients administered radiopharmaceuticals issued by five organizations associated with Japan Radiological Society (JRS), Japanese Society of Radiological Technology (JSRT), the Japanese Society of Nuclear Medicine (JSNM), the Japanese Society of Nuclear Medicine Technology (JSNMT), and Japan Association on Radiological Protection in Medicine (JARPM). A major change was to check the radioactive waste at the individual departments and at a centralized check system. This eliminated the problem of dumping radioactive material into medical waste as well as resolving the concerns of the industrial waste management service. (author)

Nuclear medicine in China

International Nuclear Information System (INIS)

Wang, Shihchen; Liu, Xiujie

1986-01-01

Since China first applied isotopes to medical research in 1956, over 800 hospitals and research institutions with 4000 staff have taken up nuclear technology. So far, over 120 important biologically active materials have been measured by radioimmunoassay in China, and 44 types of RIA kit have been supplied commercially. More than 50,000 cases of hyperthyroidism have been treated satisfactorily with 131 I. Radionuclide imaging of practically all organs and systems of the human body has been performed, and adrenal imaging and nuclear cardiology have become routine clinical practice in several large hospitals. The thyroid iodine uptake test, renogram tracing and cardiac function studies with a cardiac probe are also commonly used in most Chinese hospitals. The active principles of more than 60 medicinal herbs have been labelled with isotopes in order to study the drug metabolism and mechanism of action. Through the use of labelled neurotransmitters or deoxyglucose, RIA, radioreceptor assay and autoradiography, Chinese researchers have made remarkable achievements in the study of the scientific basis of acupuncture analgesia. In 1980 the Chinese Society of Nuclear Medicine was founded, and since 1981 the Chinese Journal of Nuclear Medicine has been published. Although nuclear medicine in China has already made some progress, when compared with advanced countries, much progress is still to be made. It is hoped that international scientific exchange will be strengthened in the future. (author)

Dose measurement received by the exposed occupationally personnel of the nuclear medicine department of the INCan

International Nuclear Information System (INIS)

Sanchez U, N. A.

2011-01-01

Personal dose equivalent (PDE) values were determined for occupational exposed workers (OEW) at the Nuclear Medicine Department (NMD) of Instituto Nacional de Cancerologia (INCan), Mexico, using TLD-100 thermoluminescent dosemeters. OEW at NMD, INCan make use of radiopharmaceuticals for diagnosis and treatment of diseases. Radionuclides associated to a pharmaceutical compound used at this Department are 131 I, 18 F, 67 Ga, 99m Tc, 111 In and 201 Tl with main gamma emission energies between 93 and 511 keV. Dosemeter calibration was performed at the metrology department of Instituto Nacional de Investigaciones Nucleares, Mexico. Every occupational worker used dark containers with three dosemeters which were replaced monthly for a total of 5 periods. Additionally, control dosemeters were also placed at a site free of radioactive sources in order to determine the background radiation. Results were adjusted to find PDE/day and estimating annual PDE values in the range between 2 mSv (background) and a maximum of 9 mSv. Two of the 16 members of the OEW receive high estimated annual doses (6-9 mSv), other 5 receive annual doses between 3 and 5 mSv, other 3 between 2.5 and 3 mSv, and the rest receive dose values consistent with background radiation. These values are dependent on their daily activities and it is clear that the maximum doses are received by those OEW who perform nursing duties and receive radiopharmaceuticals for daily use. All obtained values are well within the established annual OEW dose limit stated in the General Regulation of Radiological Protection, Mexico (50 mSv) as well as within the lower limit recommended by the International Commission on Radiation Protection, report no. 60 (20 mSv). Additionally, consistence was found between measured monthly values and those reported by the firm that performs the monthly service. These results verify the adequate compliance of the NMD at INCan, Mexico with the standards given by the national regulatory

Essentials of nuclear medicine imaging

CERN Document Server

Mettler, Fred A. Jr

2012-01-01

Essentials of Nuclear Medicine Imaging, by Drs. Fred A Mettler and Milton J Guiberteau, provides the practical and comprehensive guidance you need to master key nuclear imaging techniques. From physics, instrumentation, quality control, and legal requirements to hot topics such as sodium fluoride, radiopharmaceuticals, and recommended pediatric administered doses and guidelines, this sixth edition covers the fundamentals and recent developments in the practice of nuclear medicine.

Nuclear Medicine in Surgical Oncology

International Nuclear Information System (INIS)

Ndirangu, D.T.

2009-01-01

Defines nuclear medicine as a branch that utilizes nuclear technology for diagnosis and treatment of diseases.The principles of nuclear medicine are; it uses the principle that a certain radiopharmaceutical (tracer) will at a certain point in time have a preferential uptake by a particular body or tissue. it is imaged by use the use of detectors mounted in gamma cameras or PET (Position emission tomography) devices

Regulatory problems in nuclear medicine

International Nuclear Information System (INIS)

Vandergrift, J.F.

1987-01-01

Governmental involvement in the practice of medicine has increased sharply within the past few years. The impact on health care has, for the most part, been in terms of financial interactions between health care facilities and federally funded health services programs. One might say that this type of governmental involvement has indirect impact on the medical and/or technical decisions in the practice of nuclear medicine. In other areas, however, governmental policies and regulations have had a more direct and fundamental impact on nuclear medicine than on any other medical specialty. Without an understanding and acceptance of this situation, the practice of nuclear medicine can be very frustrating. This chapter is thus written in the hope that potential frustration can be reduced or eliminated

Peptide radiopharmaceuticals in nuclear medicine

International Nuclear Information System (INIS)

Blok, D.; Vermeij, P.; Feitsma, R.I.J.; Pauwels, E.J.K.

1999-01-01

This article reviews the labelling of peptides that are recognised to be of interest for nuclear medicine or are the subject of ongoing nuclear medicine research. Applications and approaches to the labelling of peptide radiopharmaceuticals are discussed, and drawbacks in their development considered. (orig.)

Development of molecular nuclear medicine

International Nuclear Information System (INIS)

Tang Ganghua

2002-01-01

The basic theory of molecular nuclear medicine is briefly introduced. The hot areas of molecular nuclear medicine including metabolic imaging and blood flow imaging, radioimmunoimaging and radioimmunotherapy, radioreceptor imaging and receptor-radioligand therapy, and imaging gene expression and gene radiation therapy are emphatically described

Promoting nuclear medicine in developing countries

International Nuclear Information System (INIS)

Ganatra, R.; Nofal, M.

1986-01-01

After a short review of the applications of nuclear medicine in diagnosis and treatment of diseases or in medical research the ways and the means of IAEA's support in helping developing countries to set up nuclear medicine capabilities in their hospitals are described. Some trends and new directions in the field of nuclear medicine and the problems related to the implementation of these techniques in developing countries are presented

Ambient radiation dose reduction within a newly remodeled Nuclear Medicine Department

International Nuclear Information System (INIS)

Lai, Y.C.; Chen, Y.W.; Huang, Y.F.

2008-01-01

Full text: Ambient radiation levels at the patient waiting areas have been greatly reduced after remodeling of our Nuclear Medicine Department (NMD) based on the ALARA consideration. Complete ambient radiation monitoring of our NMD before remodeling had been characterized and published earlier by the same authors elsewhere. The NMD outpatients, with an initial dose of up to 740 MBq (20 mCi) per case, may wait around and incidentally congest in one place that could cause an unexpected higher exposure level in public access areas. In this new surveillance study after remodeling, the ambient radiation time-profile, peak dose rates and daily doses have been re-evaluated by using high sensitivity, digital survey dosimeters. As a preliminary result, with our newly improved facility in operation, we have demonstrated the NMD waiting room average daily dose has dropped from about 3.0 μSv to 0.42 μSv during most of busy days in comparison. The hourly peak dose rate detected in patient waiting areas has also reduced to a factor of more than two, from maximum dose rate of 40.4 μSv/h to 15.4 μSv/h, during one worst case scenario. The great reduction of the environment dose was achieved mainly by using larger room space with thicker lead wall, from previous 2-mm to new 5-mm in lead thickness, and by increasing patient waiting rooms/areas with less chairs available in each seating location. Other NMD administrative control measure of our dose reduction program has also been emphasized in better patient routing, scheduling and less waiting time for the diagnostic patients. (author)

Essentials of nuclear medicine physics and instrumentation

CERN Document Server

Powsner, Rachel A; Powsner, Edward R

2013-01-01

An excellent introduction to the basic concepts of nuclear medicine physics This Third Edition of Essentials of Nuclear Medicine Physics and Instrumentation expands the finely developed illustrated review and introductory guide to nuclear medicine physics and instrumentation. Along with simple, progressive, highly illustrated topics, the authors present nuclear medicine-related physics and engineering concepts clearly and concisely. Included in the text are introductory chapters on relevant atomic structure, methods of radionuclide production, and the interaction of radiation with matter. Fu

Handbook of nuclear medicine practice in developing countries

International Nuclear Information System (INIS)

1992-01-01

This ''Handbook of Nuclear Medicine Practices in the Developing Countries'' is meant primarily for those, who intend to install and practice nuclear medicine in a developing country. By and large, the conventional Textbooks of nuclear medicine do note cater to the special problems and needs of these countries. The Handbook is not trying to replace these textbooks, but supplement them with special information and guidance, necessary for making nuclear medicine cost-effective and useful in a hospital of a developing country. It is written mostly by those, who have made success in their careers in nuclear medicine, in one of these countries. One way to describe this Handbook will be that it represents the ways, in which, nuclear medicine is practised in the developing countries, described by those, who have a long and authentic experience of practising nuclear medicine in a developing country

Proceedings of 2nd Korea-China Congress of Nuclear Medicine and the Korean Society Nuclear Medicine Spring Meeting 2000

International Nuclear Information System (INIS)

2000-01-01

This proceedings contains articles of 2nd Korea-China Congress of Nuclear Medicine and 2000 spring meeting of the Korean Society Nuclear Medicine. It was held on May 17-19, 2000 in Seoul, Korean. This proceedings is comprised of 6 sessions. The subject titles of session are as follows: general nuclear medicine, neurology, oncology, radiopharmacy and biology, nuclear cardiology, nuclear cardiology: physics and instrumentation and so on. (Yi, J. H.)

Nuclear medicine

International Nuclear Information System (INIS)

James, A.E. Jr.; Squire, L.F.

1977-01-01

The book presents a number of fundamental imaging principles in nuclear medicine. The fact that low radiation doses are sufficient for the study of normal and changed physiological functions of the body is an important advancement brought about by nuclear medicine. The possibility of quantitative investigations of organs and organ regions and of an assessment of their function as compared to normal values is a fascinating new diagnostic dimension. The possibility of comparing the findings with other pathological findings and of course control in the same patient lead to a dynamic continuity with many research possibilities not even recognized until now. The limits of nuclear scanning methods are presented by the imprecise structural information of the images. When scintiscans are compared with X-ray images or contrast angiography, the great difference in the imaging of anatomical details is clearly seen. But although the present pictures are not optimal, they are a great improvement on the pictures that were considered clinically valuable a few years ago. (orig./AJ) [de

Is hybridic positron emission tomography/computerized tomography the only option? The future of nuclear medicine and molecular imaging.

Science.gov (United States)

Grammaticos, Philip; Zerva, Cherry; Asteriadis, Ioannis; Trontzos, Christos; Hatziioannou, Kostas

2007-01-01

As we all know, Nuclear Medicine is the medical science using nuclear radiation for diagnosis, treatment and research. Nuclear Medicine, in contrast to Radiology, makes use of unsealed sources of radiation. Nuclear Medicine a few years ago has partly offered Nuclear Cardiology, the most lucrative of all Nuclear Medicine "children" at that time, to Cardiology. Radiology, has succeeded in being recognized by the European Union Authorities as Clinical Radiology. The word "clinical" offers greater independence to Clinical Radiology and makes it difficult for such a specialty to relinquish any of its equipment i.e. the diagnostic CT scan or the newly developed fast angiography CT, to other specialties. Contrary to Clinical Radiology, Nuclear Medicine being a laboratory specialty in most countries seems to have no right to deny offering, after some period of "proper certified education", its PET camera to Clinical Radiologists. Nuclear Medicine by virtue of its unique diagnostic techniques and treatments, is and should be recognized as a "Clinical Specialty" The interference of other specialties in the fields of Nuclear Medicine is also indicated by the fact that in vitro techniques of Nuclear Medicine are often used by Endocrinologists and Oncologists in their own laboratories. Also in some hospitals the Director of the Radiology Department acts as the Director of Nuclear Medicine Laboratory. Finally at present, Radiologists wish after "proper certified education", to be on equal terms in charge of the new hybridic equipment, the PET/CT scanner. If that is followed to happen, Nuclear Medicine will be in a difficult position losing at least part of PET and consequently should ask for help from its "Overlords and Protectors" i.e. the National and the European Societies of Nuclear Medicine and the Society of Nuclear Medicine of the United States of America. Radiology as a specialty participating om equal terms with the PET camera will then include the study of: a) "open

Handbook of nuclear medicine practice in developing countries

Energy Technology Data Exchange (ETDEWEB)

NONE

1993-12-31

This ``Handbook of Nuclear Medicine Practices in the Developing Countries`` is meant primarily for those, who intend to install and practice nuclear medicine in a developing country. By and large, the conventional Textbooks of nuclear medicine do note cater to the special problems and needs of these countries. The Handbook is not trying to replace these textbooks, but supplement them with special information and guidance, necessary for making nuclear medicine cost-effective and useful in a hospital of a developing country. It is written mostly by those, who have made success in their careers in nuclear medicine, in one of these countries. One way to describe this Handbook will be that it represents the ways, in which, nuclear medicine is practised in the developing countries, described by those, who have a long and authentic experience of practising nuclear medicine in a developing country Figs, tabs

A nuclear medicine information system that allows reporting and sending images through intranet

International Nuclear Information System (INIS)

Anselmi, C.E.; Anselmi, O.E.

2002-01-01

A nuclear medicine information system that allows reporting and sending images through intranet. Aim: This system was developed in order to improve the processes of typing, correcting, verifying and distribution of the reports and images, improving the efficiency of the personnel in the nuclear medicine department and reducing the time between the creation of the report and its reading by the referring physician. Materials and Methods: The system runs a web server (Personal Web Server, Microsoft) which serves web pages written in hypertext markup language (HTML) and active server pages (ASP). The database utilized is Microsoft Access 97. The whole communication between the web server and the database is performed by the programs written in ASP. Integrating the images from the patients is done through a 486 ibm-pc running Red Hat Linux, which serves as an intermediary between the isolated nuclear medicine network and the hospital's network. Results: The time from report verification and referring physician reading has decreased from approximately 24 hours to 12 hours. It is possible to run queries in the system in order to get productivity reports or clinical research. Imaging storage allows for correlation of current and previous studies. Conclusion: Bureaucratic processes have diminished to a certain extent in the department. Reports are now online as soon as they are verified by the nuclear medicine physician. There is no need to install dedicated software in the viewing stations since the whole system runs in the server

Metabolic radiopharmaceutical therapy in nuclear medicine

International Nuclear Information System (INIS)

Reguera, L.; Lozano, M. L.; Alonso, J. C.

2016-01-01

In 1986 the National Board of Medical Specialties defined the specialty of nuclear medicine as a medical specialty that uses radioisotopes for prevention, diagnosis, therapy and medical research. Nowadays, treatment with radiopharmaceuticals has reached a major importance within of nuclear medicine. The ability to treat tumors with radiopharmaceutical, Radiation selective therapy has become a first line alternative. In this paper, the current situation of the different therapies that are sued in nuclear medicine, is reviewed. (Author)

E-film - an interactive clinical teaching tool for nuclear medicine

International Nuclear Information System (INIS)

Zohar, T.; VanEvery, B.

2002-01-01

Full text: With the advent of technology the old fashioned film library used by our Nuclear Medicine staff has been updated and remodelled from 'hard copy learning' with film and light boxes to 'soft-copy learning' using standard PC hardware and software. The new model 'e-film' is a web browser based image viewer written in HTML. It incorporates interesting case studies with interactive questions and answers based on pathology. The easy-to-use design involves selecting a Nuclear Medicine scan e g bone scan, and then the pathology of interest e g osteomyelitis. Each pathology selected has a normal and a number of abnormal cases, which can be viewed as static planar and dynamic images or as movies. The text displayed with each case study is a question with an answer that can be revealed when ready. A general learning tip pertaining to the scan type or particular pathology can also be revealed on request. Many of the case studies incorporate images from other modalities such as CT or MRI for comparison with the Nuclear Medicine images. Pre- and post- treatment scans can also be viewed to assess outcome 'e film' allows staff to search in a specific area of Nuclear Medicine and then test themselves on their understanding of the scan and relevant pathologies. Standard web browsers on PC's allow department-wide user accessibility of e-film via an intranet configuration. In summary, e-film is a convenient, time efficient way of learning with the potential of unlimited data expansion. Copyright (2002) The Australian and New Zealand Society of Nuclear Medicine Inc

Nuclear medicine in emergency

International Nuclear Information System (INIS)

Mansi, L.; Rambaldi, P.F.; Cuccurullo, V.; Varetto, T.

2005-01-01

The role of a procedure depends not only on its own capabilities but also on a cost/effective comparison with alternative technique giving similar information. Starting from the definition of emergency as a sudden unexpected occurrence demanding immediate action, the role of nuclear medicine (NM) is difficult to identify if it is not possible to respond 24h a day, 365 days a year, to clinical demands. To justify a 24 h NM service it is necessary to reaffirm the role in diagnosis of pulmonary embolism in the spiral CT era, to spread knowledge of the capabilities of nuclear cardiology in reliability diagnosis myocardial infraction (better defining admission and discharge to/from the emergency department), to increase the number of indications. Radionuclide technique could be used as first line, alternative, complementary procedures in a diagnostic tree taking into account not only the diagnosis but also the connections with prognosis and therapy in evaluating cerebral pathologies, acute inflammation/infection, transplants, bleeding, trauma, skeletal, hepatobiliary, renal and endocrine emergencies, acute scrotal pain

Course on internal dosimetry in nuclear medicine

International Nuclear Information System (INIS)

2004-01-01

This documentation was distributed to the participants in the Course of Internal Dosimetry in Nuclear Medicine organised by the Nuclear Regulatory Authority (ARN) of Argentina and held in Buenos Aires, Argentina, August 9-13, 2004. The course was intended for people from IAEA Member States in the Latin American and Caribbean region, and for professionals and workers in medicine, related with the radiation protection. Spanish and English were the languages of the course. The following subjects were covered: radioprotection of the patient in nuclear medicine; injuries by ionizing radiations; MIRD methodology; radiation dose assessment in nuclear medicine; small scale and microdosimetry; bone and marrow dose modelling; medical internal dose calculations; SPECT and image reconstruction; principles of the gamma camera; scattering and attenuation correction in SPECT; tomography in nuclear medicine

ECAT ART - a continuously rotating PET camera: performance characteristics, initial clinical studies, and installation considerations in a nuclear medicine department

International Nuclear Information System (INIS)

Bailey, D.L.; Young, H.; Bloomfield, P.M.; Meikle, S.R.; Glass, D.; Myers, M.J.; Spinks, T.J.; Watson, C.C.; Luk, P.; Peters, A.M.; Jones, T.

1997-01-01

Advances in image reconstruction techniques have permitted the development of a commercial, rotating, partial ring, fully 3D scanner, the ECAT ART. The system has less than one-half the number of bismuth germanate detectors compared with a full ring scanner with the equivalent field of view, resulting in reduced capital cost. The performance characteristics, implications for installation in a nuclear medicine department, and clinical utility of the scanner are presented in this report. The sensitivity (20 cm diameter x 20 cm long cylindrical phantom, no scatter correction) is 11400 cps.kBq -1 .ml -1 . This compares with 5800 and 40500 cps.kBq -1 .ml -1 in 2D and 3D respectively for the equivalent full ring scanner (ECAT EXACT). With an energy window of 350-650 keV the maximum noise equivalent count (NEC) rate was 27 kcps at a radioactivity concentration of ∝15 kBq .ml -1 in the cylinder. Spatial resolution is ∝6 mm full width at half maximum on axis degrading to just under 8 mm at a distance of 20 cm off axis. Installation and use within the nuclear medicine department does not appreciably increase background levels of radiation on gamma cameras in adjacent rooms and the dose rate to an operator in the same room is 2 μSv .h -1 for a typical fluorine-18 fluorodeoxyglucose ( 18 F-FDG) study with an initial injected activity of 370 MBq. The scanner has been used for clinical imaging with 18 F-FDG for neurological and oncological applications. Its novel use for imaging iron-52 transferrin for localising erythropoietic activity demonstrates its sensitivity and resolution advantages over a conventional dual-headed gamma camera. The ECAT ART provides a viable alternative to conventional full ring PET scanners without compromising the performance required for clinical PET imaging. (orig.). With 9 figs., 3 tabs

Where is high technology taking nuclear medicine

International Nuclear Information System (INIS)

Veall, N.

1985-01-01

The question is posed as to whether high technology in nuclear medicine might lead to the nuclear medicine practitioner possibly finishing up working for the machine rather than the improvement of health care in its widest sense. A brief examination of some pros and cons of high technology nuclear medicine is given. (U.K.)

Nuclear medicine and its radiological protection in China

International Nuclear Information System (INIS)

Wu, J.

2001-01-01

The China Society of Nuclear Medicine was established on 27 May 1980. Since then, nuclear medicine in clinical diagnosis and therapy has been developed rapidly in China. So far there are more than 4000 members of the Society, and more than 350 sets of SPECT and 12 sets of PET have been installed and are busily running in clinic nowadays and about 1 million patients with different types of diseases have obtained nuclear medicine imaging examinations per year. Concerning the nuclear medicine therapy, a lot of patients with many types of diseases obtained benefit from radioisotope therapy. Accordingly, several Policies and Regulations have been enacted by the Government for the radiological protection. Furthermore, a special book titled 'Standardization in Diagnostic and Therapeutic Nuclear Medicine' has been promulgated in June, 1997 by the Health Administration of People's Republic of China, and this book is distributed to almost every nuclear medicine physician and technician in China for their reference in routine nuclear medicine work or research. In this book three parts of the contents are covered: Policies and Regulations for the radiological protection, basic knowledge and clinical nuclear medicine applications. (author)

Your Radiologist Explains Nuclear Medicine

Medline Plus

Full Text Available ... can be detected with other diagnostic tests. Nuclear medicine imaging procedures use small amounts of radioactive materials – called radiotracers – that ... outweighs any risk. To learn more about nuclear medicine, visit Radiology Info dot org. Thank you for your ... of Use | Links | Site Map Copyright © 2018 Radiological Society of ...

Nuclear medicine at the crossroads

International Nuclear Information System (INIS)

Strauss, H.W.

1996-01-01

Many nuclear medicine procedures, originally developed more than 20 years ago, are now performed with new radiopharmaceuticals or instruments; it is therefore apposite to reappraise what we are doing and why we are doing it. The clinical utility of nuclear medicine is discussed with reference, by way of example, to gated blood pools scans and myocardial perfusion imaging; the importance of the referred population for the outcome of studies is stressed. Attention is drawn to the likelohood that the detection of ischemia would be enhanced by the administration of nitroglycerin prior to rest thallium injection. Emphasis is also placed on the increasing acceptance of dual-tracer studies. The significance of expression of p-glycoprotein by some tumors for sestamibi imaging is discussed, and advances in respect of fluorodeoxyglucose imaging are reviewed. The final section covers issues relating to the development of new procedures, such as the value of nuclear medicine in the detection and characterization of tissue oxygen levels and the possible future role of nuclear medicine in the management of sleeping and eating disorders. (orig.)

Nuclear medicine, a proven partnership

International Nuclear Information System (INIS)

Henderson, L. A.

2009-01-01

Full text:Ultrasonography is the modality of choice for demonstrating many cystic structures within the body. However nuclear medicine is often able to demonstrate functional disturbance where ultrasound and conventional radiography are unsuccessful. A case is presented in which a 16 day old male child presented to nuclear medicine with a right upper quadrant cyst found in ultrasound with exact location equivocal. Determining the location and nature of the cyst was essential to the treatment team for patient management. A hepatobiliary study was performed and evidence of a choledochal cyst was found. In partnership with ultrasound, nuclear medicine was able to identify a possibly malignant structure and consequently patient management was determined.

Guidelines for starting a nuclear medicine laboratory. Excerpts from a booklet published by Bhabha Atomic Research Centre, India

International Nuclear Information System (INIS)

1992-01-01

A nuclear medicine department caters to the need of all clinical departments, and, therefore, should be located at a central place. At the same time, because of radiation hazard associated with the use of radionuclides, planning of the departments should be done in such a way that there is no radiation exposure to non-radiation workers and the general public, and also that radiation workers handling radioisotopes receive minimum exposure. When a decision to set up a nuclear medicine department is taken, the authorities are faced with a number of questions regarding the location, planning for the premises, equipment needed, availability of trained medical and paramedical personnel and the procedure for obtaining clearance from various authorities

Guidelines for starting a nuclear medicine laboratory. Excerpts from a booklet published by Bhabha Atomic Research Centre, India

Energy Technology Data Exchange (ETDEWEB)

NONE

1993-12-31

A nuclear medicine department caters to the need of all clinical departments, and, therefore, should be located at a central place. At the same time, because of radiation hazard associated with the use of radionuclides, planning of the departments should be done in such a way that there is no radiation exposure to non-radiation workers and the general public, and also that radiation workers handling radioisotopes receive minimum exposure. When a decision to set up a nuclear medicine department is taken, the authorities are faced with a number of questions regarding the location, planning for the premises, equipment needed, availability of trained medical and paramedical personnel and the procedure for obtaining clearance from various authorities

How does a quality audits work in national harmonization of activity measurement over nuclear medicine measurement in Cuba

International Nuclear Information System (INIS)

Varela, C.

2006-01-01

The National Control Center for Medical Devices (CCEEM) is a regulatory agency, belongs to the Cuban Ministry of Public Heath. It works to guarantee the safety and effectiveness of medical devices used into the National Health System (NHS) and the patient, and user protection. Quality Control assures that particular aspect will be satisfied, so since several years ago a national programme for the quality control of nuclear medicine instruments has been organized and established. A service was created in order to control periodically the state of the instrumentation in all the nuclear medicine departments, it is making annual quality control audits and participating in comparisons exercises organises by CCEEM. 3 comparisons exercises with CENTIS and services of NHS were made and eleven nuclear medicine departments were audited in order to perform a practical evaluation of this service, giving the two new regulations and general instructions to dose administration. The objects of the present work is shows, by those results, how does a quality audits work in National Harmonization of Activity Measurement over Nuclear Medicine Measurement in Cuba

Practice of nuclear medicine in a developing country

International Nuclear Information System (INIS)

Hasan, M.M.; Karim, M.A.; Nahar, N.; Haque, M.M.

2002-01-01

For more than a half a century nuclear medicine is contributing in the field of medicine. Still nuclear medicine is not widely available in many countries. Especially in developing countries due to many a reasons nuclear medicine could not flourish in that way. Availability of radioisotope, high cost of instrument and sophistication of the branch are the three main reasons behind. Even the countries where nuclear medicine is functioning for quite a long time, the facilities for proper function are still not adequate. Training of manpower, maintenance of instruments, regular supply of isotopes and kit and cost effectiveness are some of the major problems. We have seen some fast developments in nuclear medicine in last few decades. Development of gamma detecting systems with SPECT, positron emission detector (PET), supported computer technology and introduction of some newer radiopharmaceuticals for functional studies are few of the examples. The developing countries also have a problem to go on parallel with these rapid development of nuclear medicine in other part of the world. In last few decades we have also witnessed development of CT, MRI, Ultrasound and other imaging modalities as our competitor. Specially for developing countries these have posed as a major challenge for nuclear medicine. A better understanding between developed and developing nations is the key point of todays ultimate success in any sector. For real development of nuclear medicine and to give the majority of the people the benefit of nuclear medicine a better and more active co-operation is needed between all the countries. The paper presents the difficulties and some practical problems of practicing nuclear medicine in a developing country. And also appeals for global co-operation to solve the problems for better interest of the subject

Nuclear medicine in the Philippines

International Nuclear Information System (INIS)

Villadolid, Leland.

1978-01-01

This article traces the history of nuclear medicine in the country from the time the first radioisotope laboratory was set up by the Philippine General Hospital about 1955, to the not too satisfactory present facilities acquired by hospitals for diagnosis, treatment and investigation of diseases. It is in research, the investigation of disease that is nuclear medicine's most important area. The Philippine Atomic Energy Commission (PAEC) has pioneered in the conducting of courses in the medical uses of radioisotopes. The local training of nuclear manpower has been continued and updated and foreign fellowships are availed of through the cooperation of IAEA. Quite a number are already trained also in the allied fields that support the practice of nuclear medicine. However the brain drain has seriously affected the number of trained staff of medical units. Discussed and presented is the growth of the medical use of radioisotopes which are locally produced by PAEC. In order to benefit from the full advantage that nuclear medicine can do to a majority of Filipinos, the government should extend its financial support in acquiring such facilities to equip strategic hospitals in the country and support training programs. The Philippine has the expertise to start the expansion but only with adequate provision of funds will our capacity turn into reality. (RTD)

Nuclear tele medicine; Telemedicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Vargas, L.; Hernandez, F.; Fernandez, R. [Departamento de Medicina Nuclear, Imagenologia Diagnostica, Xalapa, Veracruz (Mexico)

2005-07-01

The great majority of the digital images of nuclear medicine are susceptible of being sent through internet. This has allowed that the work in diagnosis cabinets by image it can benefit of this modern technology. We have presented in previous congresses works related with tele medicine, however, due to the speed in the evolution of the computer programs and the internet, becomes necessary to make a current position in this modality of work. (Author)

Nuclear medicine

International Nuclear Information System (INIS)

Sibille, L.; Nalda, E.; Collombier, L.; Kotzki, P.O.; Boudousq, V.

2011-01-01

Nuclear medicine is a medical specialty using the properties of radioactivity. Radioactive markers associated with vectors are used as a tracer or radiopharmaceutical for diagnostic purposes and/or therapy. Since its birth more than half a century ago, it has become essential in the care of many patients, particularly in oncology. After some definitions, this paper presents the main nuclear techniques - imaging for diagnostic, radiopharmaceuticals as therapeutic agents, intra-operative detection, technique of radioimmunoassay - and the future of this field. (authors)

Experimental nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Dormehl, I C [Nuclear Development Corp. of South Africa (Pty.) Ltd., Pelindaba, Pretoria. Inst. of Life Sciences; Du Plessis, M; Jacobs, D J

1983-07-01

Exciting investigative research, widening the dimensions of conventional nuclear medicine, is being conducted in Pretoria where the development and evaluation of new radiopharmaceuticals in particular is attracting international attention. Additional to this, the development of new diagnostic techniques involving sophisticated data processing, is helping to place South Africa firmly in the front line of nuclear medical progress.

Physics and radiobiology of nuclear medicine

CERN Document Server

Saha, Gopal B

2010-01-01

From a distinguished author comes this new edition for technologists, practitioners, residents, and students in radiology and nuclear medicine. Encompassing major topics in nuclear medicine from the basic physics of radioactive decay to instrumentation and radiobiology, it is an ideal review for Board and Registry examinations. The material is well organized and written with clarity. The book is supplemented with tables and illustrations throughout. It provides a quick reference book that is concise but comprehensive, and offers a complete discussion of topics for the nuclear medicine and radi

[E-learning in nuclear medicine - a nationwide survey in Germany].

Science.gov (United States)

Freudenberg, L S; Nattland, A; Jonas, G; Beyer, T; Bockisch, A

2010-01-01

To assess available e-learning concepts and programmes for nuclear medicine at university hospitals in Germany. All (34) departments of nuclear medicine at German university hospitals were asked to participate in an anonymized online survey. Questions were categorized into four topics: 1.) clinic and education; 2.) on-site strategies for e-learning; 3.) available e-learning offers and 4.) free text comments on experiences and expectations. All input was reviewed descriptively; free text was analyzed analytically. The response rate was 56% (19/34). 13/19 responses indicated well-defined e-learning strategies, mainly to support frontal teaching courses. Future e-learning perspectives focus on clinical case studies with sufficient imaging materials. Only 7/19 university hospitals operate a centralized e-learning platform (e. g. Moodle). The acceptance of the available e-learning options by the students is considered relatively poor. Today e-learning concepts for nuclear medicine are available at selected university hospitals only. All responders wish to expand on e-learning but many report the lack of administrative support to do so. These data could be regarded as a basis for discussions of inter-university teaching scenarios.

Physics in nuclear medicine

CERN Document Server

Cherry, Simon R; Phelps, Michael E

2012-01-01

Physics in Nuclear Medicine - by Drs. Simon R. Cherry, James A. Sorenson, and Michael E. Phelps - provides current, comprehensive guidance on the physics underlying modern nuclear medicine and imaging using radioactively labeled tracers. This revised and updated fourth edition features a new full-color layout, as well as the latest information on instrumentation and technology. Stay current on crucial developments in hybrid imaging (PET/CT and SPECT/CT), and small animal imaging, and benefit from the new section on tracer kinetic modeling in neuroreceptor imaging.

Quality assurance in nuclear medicine

International Nuclear Information System (INIS)

Paras, P.

1978-01-01

Quality assurance practices must be followed throughout the entire nuclear medicine process, from the initial decision to perform a particular procedure, through the interpretation and reporting of the results. The various parameters that can be defined and measured in each area must be monitored by quality control tests to assure the excellence of the total nuclear medicine process. The presentation will discuss each of the major areas of nuclear medicine quality control and their interaction as a part of the entire system. Quality control testing results and recommendations for measurements of radioactivity distribution will be described with emphasis on imaging equipment and dose calibrating instrumentation. The role of the health physicist in a quality assurance program will be stressed. (author)

Draft report on the national seminar in nuclear medicine

International Nuclear Information System (INIS)

1977-01-01

The proceedings of the seminar on nuclear medicine have been conducted in four main sessions. In the first session a review of the current status of clinical nuclear medicine in India is reviewed. The use of radioisotopes in thyroid function studies, central nervous systems, liver disorders, lung and bone imaging, renal function studies, dynamic function studies, gastroenterology haematology etc. are described. The existing facilities and the future needs for radioimmunoassay and radiotherapy are discussed. In Session 2, the existing facilities in nuclear medicine in different states in India are reviewed. In Session 3, the available resources in nuclear medicine are reviewed. Radiation protection procedures are outlined. Various nuclear instruments developed at the Bhabha Atomic Research Centre, (BARC), Bombay, for use in nuclear medicine are briefly described. A list of radiopharmaceuticals developed by BARC and in current use, is given. The roles of the physicist, pharmacist and the nuclear medicine technologist in the hospitals having nuclear medicine units, are stressed. The importance of training and education for personnel in nuclear medicine and medical physics is pointed out. (A.K.)

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... physician who has specialized training in nuclear medicine will interpret the images and send a report to your referring physician. top of page What are the benefits vs. risks? Benefits The information provided by nuclear ...

Ninth Argentine congress on biology and nuclear medicine; fourth Southernmost sessions of ALASBIMN (Latin-American Association of Biology and Nuclear Medicine); first Spanish-Argentine congress on nuclear medicine; first Argentine sessions on nuclear cardiology

International Nuclear Information System (INIS)

1991-01-01

This work deals with all the papers presented at the 9. Argentine congress on biology and nuclear medicine; IV Southernmost sessions of ALASBIMN; I Spanish-Argentine congress on nuclear medicine and I Sessions Argentine sessions on nuclear cardiology held in Buenos Aires, Argentina, from October 14 - 18, 1991

Monte Carlo simulation in nuclear medicine

International Nuclear Information System (INIS)

Morel, Ch.

2007-01-01

The Monte Carlo method allows for simulating random processes by using series of pseudo-random numbers. It became an important tool in nuclear medicine to assist in the design of new medical imaging devices, optimise their use and analyse their data. Presently, the sophistication of the simulation tools allows the introduction of Monte Carlo predictions in data correction and image reconstruction processes. The availability to simulate time dependent processes opens up new horizons for Monte Carlo simulation in nuclear medicine. In a near future, these developments will allow to tackle simultaneously imaging and dosimetry issues and soon, case system Monte Carlo simulations may become part of the nuclear medicine diagnostic process. This paper describes some Monte Carlo method basics and the sampling methods that were developed for it. It gives a referenced list of different simulation software used in nuclear medicine and enumerates some of their present and prospective applications. (author)

Physical bases of nuclear medicine

International Nuclear Information System (INIS)

Isabelle, D.B.; Ducassou, D.

1975-01-01

The physical bases of nuclear medicine are outlined in several chapters devoted successively to: atomic and nuclear structures; nuclear reactions; radioactiity laws; a study of different types of disintegration; the interactions of radiations with matter [fr

Children in nuclear medicine

International Nuclear Information System (INIS)

Fischer, S.

2002-01-01

With each study in paediatric nuclear medicine one must try to reach a high quality standard with a minimum of radiation exposure to the child. This is true for the indication for the study and the interpretation of the results as well as the preparation, the image acquisition, the processing and the documentation. A continuous evaluation of all aspects is necessary to receive optimal, clinically relevant information. In addition it is important that the child keeps nuclear medicine in a good mind, especially when it has to come back for a control study. (orig.) [de

Nuclear medicine training and practice in Turkey.

Science.gov (United States)

Ozcan, Zehra; Bozkurt, M Fani; Erbas, Belkıs; Durak, Hatice

2017-05-01

Nuclear medicine applications in Turkey started in the early 1950s, grew as an independent medical discipline and finally were recognized by the Ministry of Health in 1973. Later on, the professional organization of nuclear medicine physicians and other related professionals including radiopharmacists and technologists under the Turkish Society of Nuclear Medicine were established in 1975. Recently after completing more than a half century in Turkey, nuclear medicine has proved to be a strong and evolving medical field with more than 600 physicians serving for the changing needs of clinical practice throughout these years. This article describes past and present facts in this field and attempts to provide insights into the future which hopefully will be brighter than before.

Assessment of radiation exposure of nuclear medicine staff using personal TLD dosimeters and charcoal detectors

Energy Technology Data Exchange (ETDEWEB)

Jimenez, F.; Garcia-Talavera, M.; Pardo, R.; Deban, L. [Valladolid Univ., Dept. de Quimica Analitica, Facultad de Ciencias (Spain); Garcia-Talavera, P.; Singi, G.M.; Martin, E. [Hospital Clinico Univ., Servicio de Medicina Nuclear, Salamanca (Spain)

2006-07-01

Although the main concern regarding exposure to ionizing radiation for nuclear medicine workers is external radiation, inhalation of radionuclides can significantly contribute to the imparted doses. We propose a new approach to assess exposure to inhalation of {sup 131}I based on passive monitoring using activated charcoal detectors. We compared the inhalation doses to the staff of a nuclear medicine department, based on the measurements derived from charcoal detectors placed at various locations, and the external doses monitored using personal TLD dosimeters. (authors)

Assessment of radiation exposure of nuclear medicine staff using personal TLD dosimeters and charcoal detectors

International Nuclear Information System (INIS)

Jimenez, F.; Garcia-Talavera, M.; Pardo, R.; Deban, L.; Garcia-Talavera, P.; Singi, G.M.; Martin, E.

2006-01-01

Although the main concern regarding exposure to ionizing radiation for nuclear medicine workers is external radiation, inhalation of radionuclides can significantly contribute to the imparted doses. We propose a new approach to assess exposure to inhalation of 131 I based on passive monitoring using activated charcoal detectors. We compared the inhalation doses to the staff of a nuclear medicine department, based on the measurements derived from charcoal detectors placed at various locations, and the external doses monitored using personal TLD dosimeters. (authors)

Developing and setting up of a nuclear medicine information management system

International Nuclear Information System (INIS)

Baghel, N.S.; Asopa, R.; Nayak, U.N.; Rajan, M.G.R.; Subhalakshmi, P.V.; Shailaja, A.; Rajashekharrao, B.; Karunanidhi, Y.R.

2010-01-01

Full text: With the advent and progress of information technology in the present decade, high-performance networks are being installed in hospitals to implement an effective and reliable Hospital Information Management Systems (HIMS). The Radiation Medicine Centre (RMC), is one of the earliest and largest nuclear medicine centres in India and several thousand patients undergo diagnostic as well as therapeutic procedures with different radiopharmaceuticals. The evolution towards a fully digital department of nuclear medicine is driven by expectations of not only improved patient management but also a well-defined workflow along with prompt and quality patient services. The aim was to develop and set up a practical and utility based Nuclear Medicine Information Management System (NMIMS) for various functional procedures at RMC. A customised NMIMS is developed with M/s ECIL using ASP.NET and SQL server technology facilitated by an IBM x3650 M3 Server, 18 thin-clients/desktop PCs and Windows 2008 server operating system and MS-SQL 2005 server software. The various modules have been developed to meet the requirements of different activities pertaining to patient appointment and scheduling, clinical assessment, radiopharmacy procedures, imaging and non-imaging studies and protocols, in-vitro laboratory tests, in-patient and out-patient treatment procedures, radiation protection and regulatory aspects and other routine operational procedures associated with patient management at RMC. The menus are developed as per scheduled workflow (SWF) in the department. The various aspects of SWF have been designed to ensure smooth, easy and trouble free patient management. Presently, the NMIMS has been developed excluding imaging data and we are in the process of setting up Picture Archiving Communication System (PACS) integrated to the existing database system, which will archive and facilitate imaging data in DICOM format in order to make a paperless department. The developed NMIMS

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... radioactive energy that is emitted from the patient's body and converts it into an image. The gamma camera itself does not emit any ... bear denotes child-specific content. Related Articles and Media General Nuclear ... (Pediatric) Nuclear Medicine Videos related ...

Nuclear medicine applications for the diabetic foot

International Nuclear Information System (INIS)

Hartshorne, M.F.; Peters, V.

1987-01-01

Although not frequently described in the podiatric literature, nuclear medicine imaging may be of great assistance to the clinical podiatrist. This report reviews in detail the use of modern nuclear medicine approaches to the diagnosis and management of the diabetic foot. Nuclear medicine techniques are helpful in evaluating possible osteomyelitis, in determining appropriate amputation levels, and in predicting response to conservative ulcer management. Specific indications for bone, gallium, and perfusion imaging are described

Radioisotopes for nuclear medicine: the future

International Nuclear Information System (INIS)

Carr, S.W.

1998-01-01

Full text: Nuclear medicine occupies an important niche in the spectrum of medical capability. Since its initial application on a routine basis over 30 years ago its importance has continued to grow. For example, it is expected that over 430,000 Australians will have a nuclear medicine procedure in 1998. Current procedures using nuclear medicine are mainly concerned with diagnosis of oncology, cardiology and neurology. The main radioisotope used in nuclear medicine is Tc 99m, which is produced by a 'so called' Mo-Tc 99m generator. Other isotopes which currently find routine use are Ga-67, Th-201 and I-131. The selective uptakes by particular organs or structures is facilitated by the use of 'cold kits' which after the chemistry of the radioisotope many of the recent advances have been concerned with increasing the selectivity for a particular organ structure. Several of these new agents show increased selectivity using antibody a peptide recognition units

Nuclear medicine training and practice in Turkey

Energy Technology Data Exchange (ETDEWEB)

Ozcan, Zehra [Ege University School of Medicine, Department of Nuclear Medicine, Izmir (Turkey); Bozkurt, M. Fani; Erbas, Belkis [Hacettepe University School of Medicine, Department of Nuclear Medicine, Ankara (Turkey); Durak, Hatice [Dokuz Eyluel University School of Medicine, Department of Nuclear Medicine, Izmir (Turkey)

2017-05-15

Nuclear medicine applications in Turkey started in the early 1950s, grew as an independent medical discipline and finally were recognized by the Ministry of Health in 1973. Later on, the professional organization of nuclear medicine physicians and other related professionals including radiopharmacists and technologists under the Turkish Society of Nuclear Medicine were established in 1975. Recently after completing more than a half century in Turkey, nuclear medicine has proved to be a strong and evolving medical field with more than 600 physicians serving for the changing needs of clinical practice throughout these years. This article describes past and present facts in this field and attempts to provide insights into the future which hopefully will be brighter than before. (orig.)

Nuclear medicine training and practice in Turkey

International Nuclear Information System (INIS)

Ozcan, Zehra; Bozkurt, M. Fani; Erbas, Belkis; Durak, Hatice

2017-01-01

Nuclear medicine applications in Turkey started in the early 1950s, grew as an independent medical discipline and finally were recognized by the Ministry of Health in 1973. Later on, the professional organization of nuclear medicine physicians and other related professionals including radiopharmacists and technologists under the Turkish Society of Nuclear Medicine were established in 1975. Recently after completing more than a half century in Turkey, nuclear medicine has proved to be a strong and evolving medical field with more than 600 physicians serving for the changing needs of clinical practice throughout these years. This article describes past and present facts in this field and attempts to provide insights into the future which hopefully will be brighter than before. (orig.)

The situation of chinese nuclear medicine technologists and strategy in future

International Nuclear Information System (INIS)

Zhang Yongxue

2001-01-01

Nuclear medicine technologists is an important part of nuclear medicine professionals, and play an important role in the progress of nuclear medicine. The professional quality of nuclear medicine technologists must adapt to the development of nuclear medicine. There is a relatively great gap between China mainland and developed countries in the field of nuclear medicine. In future, it is urgent to improve the professional quality and the educational level of nuclear medicine technologists

Teaching and training programmes in nuclear medicine for medical and paramedical personnel at the Radiation Medicine Centre, Bhabha Atomic Research Centre

International Nuclear Information System (INIS)

Sharma, S.M.; Raikar, U.R.

1986-01-01

Prior to 1976, the Radiation Medicine Centre had conducted 12 short courses of five weeks' duration on medical uses of radioisotopes. A total of 162 medical and scientific personnel attended the courses from various parts of India. Owing to the rapid advances made in nuclear medicine these courses were becoming inadequate, and in 1973 the Centre introduced one-year full time training courses for doctors and science graduates, peparing them for examinations for the Diploma in Radiation Medicine (DRM) and the Diploma in Medical Radioisotope Techniques (DMRIT) of the University of Bombay. By March 1984, 64 doctors and 53 technologists had obtained the DRM and DMRIT. A recent survey indicated that 70% of the DRM physicians and 68% of the DMRIT technologists are employed in nuclear medicine departments. Besides the formal one-year training courses, the Centre has conducted advanced courses of two weeks' duration on scintigraphy and thyroid function tests. The Radiation Medicine Centre has been the regional reference centre in nuclear medicine for the World Health Organization and International Atomic Energy Agency for more than ten years. The Centre has trained sponsored personnel from other countries of the region. The Centre has also organized seven symposia, workshops and seminars, four of them in collaboration with WHO and one with the IAEA. (author)

Radiation physics for nuclear medicine

CERN Document Server

Hoeschen, Christoph

2011-01-01

The field of nuclear medicine is expanding rapidly, with the development of exciting new diagnostic methods and treatments. This growth is closely associated with significant advances in radiation physics. In this book, acknowledged experts explain the basic principles of radiation physics in relation to nuclear medicine and examine important novel approaches in the field. The first section is devoted to what might be termed the "building blocks" of nuclear medicine, including the mechanisms of interaction between radiation and matter and Monte Carlo codes. In subsequent sections, radiation sources for medical applications, radiopharmaceutical development and production, and radiation detectors are discussed in detail. New frontiers are then explored, including improved algorithms for image reconstruction, biokinetic models, and voxel phantoms for internal dosimetry. Both trainees and experienced practitioners and researchers will find this book to be an invaluable source of up-to-date information.

Computers for use in nuclear medicine

International Nuclear Information System (INIS)

Surova, H.

1991-01-01

Brief information is presented on computers for nuclear medicine that are currently available on the market. The treatment is based on print material by various manufacturers and commercial organizations and on the publication ''Nuclear Medicine Computers - A Personal Comparison Chart'' of May 1991, issued by the Reilly Publishing Company. (Z.S.)

Nuclear tele medicine

International Nuclear Information System (INIS)

Vargas, L.; Hernandez, F.; Fernandez, R.

2005-01-01

The great majority of the digital images of nuclear medicine are susceptible of being sent through internet. This has allowed that the work in diagnosis cabinets by image it can benefit of this modern technology. We have presented in previous congresses works related with tele medicine, however, due to the speed in the evolution of the computer programs and the internet, becomes necessary to make a current position in this modality of work. (Author)

Current Status of The Korean Society of Nuclear Medicine

International Nuclear Information System (INIS)

Koh, Chang Soon

1977-01-01

As the application of nuclear medicine to clinics became generalized and it held an important position, the Korean Society of Nuclear Medicine was founded in 1961, and today it has become known as one of the oldest nuclear medicine societies not only to Asian nations but also to other advanced countries all over the world. Now it has 100 or so regular members composed of students of each medicine filed unlike other medical societies. Only nuclear medicine research workers are eligible for its membership. The Korean Society of Nuclear Medicine holds its regular general meeting and symposium twice per annom respectively in addition to occasional group gatherings and provincial lectures on nuclear medicine. With an eye to exchanging information on symposium, research and know-how, KSNM issued its initial magazine in 1967. Every year two editions are published. Year after year the contents of treatises are getting elevated with researches on each field including the early study on morphology-greatly improved both in quality and quantity. Of late, a minute and fixed quantity of various matters by dynamical research and radioimmunoassay of every kind has become visibly active. In particular, since KSNM, unlike other local societies, keeps close and frequent contact with the nuclear medicine researchers of world-wide fame, monographs by eminent scholars of the world are carried in its magazine now internationally and well received in foreign countries. Now the magazine has been improved to such an extent that foreign authors quote its contents. KSNM invited many a foreign scholar with a view to exchanging the knowledge of nuclear medicine. Sponsored by nuclear energy institute, the nuclear medicine symposium held in Seoul in October of 1966 was a success with Dr. Wagner participating, a great scholar of world wide fame: It was the first international symposium ever held in Korea, and the Korea Japan symposium held in Seoul 1971 was attended by all distinguished nuclear

Digital filtering in nuclear medicine

International Nuclear Information System (INIS)

Miller, T.R.; Sampathkumaran, S.

1982-01-01

Digital filtering is a powerful mathematical technique in computer analysis of nuclear medicine studies. The basic concepts of object-domain and frequency-domain filtering are presented in simple, largely nonmathemaical terms. Computational methods are described using both the Fourier transform and convolution techniques. The frequency response is described and used to represent the behavior of several classes of filters. These concepts are illustrated with examples drawn from a variety of important applications in nuclear medicine

Nuclear medicine. La medecine nucleaire

Energy Technology Data Exchange (ETDEWEB)

Blanquet, P; Blanc, D

1976-01-01

The applications of radioisotopes in medical diagnostics are briefly reviewed. Each organ system is considered and the Nuclear medicine procedures pertinent to that system are discussed. This includes, the principle of the test, the detector and the radiopharmaceutical used, the procedure followed and the clinical results obtained. The various types of radiation detectors presently employed in Nuclear Medicine are surveyed, including scanners, gamma cameras, positron cameras and procedures for obtaining tomographic presentation of radionuclide distributions.

Physical aspects of quality assurance in nuclear medicine and radiotherapy, regulatory approach of the National Nuclear Safety Center; Aspectos fisicos de garantia de calidad en medicina nuclear y radioterapia. Enfoque regulatorio del centro Nacional de Seguridad Nuclear

Energy Technology Data Exchange (ETDEWEB)

Gonzalez C, D.; Fuente P, A. de la; Quevedo G, J.R.; Lopez F, Y. [CNSN, Calle 28 No. 504 e/5 y 7, Ave. Miramar, La Habana (Cuba); Varela C, C. [CCEEM, Calle 4 No. 455 e/19 y 21, Ave. Vedado, La Habana (Cuba)]. e-mail: cruz@orasen.co.cu

2006-07-01

The physical aspects of the quality guarantee in Nuclear Medicine and Radiotherapy its are of cardinal importance to guarantee the quality of the diagnoses and treatments that are carried out to the patients in this type of services. The OIEA, the OMS and other scientific and professional organizations have contributed significantly to the elaboration of recommendations, Protocols, etc. applicable in the quality control programs and safety of the Nuclear Medicine and Radiotherapy departments. In spite of the great effort developed in this sense the Installation of the programs of quality control and safety of the Nuclear Medicine and Radiotherapy departments can fail if the same ones are not based in three decisive elements that are: the existence of national regulations, the existence of the infrastructure required for it and the existence of enough qualified personnel to develop this programs. The present work shows the regulatory focus that on this topic, it has followed the National Center of Nuclear Safety of Cuba (CNSN). The same left of strengthen all the existent Synergies in the different organizations of the country and it went in two fundamental directions: installation of the regulatory requirements that govern this activity and the Authorization of a Cuban Entity, specialized in carrying out audits to the quality control and safety programs of the Nuclear Medicine and Radiotherapy departments. After 4 work years in this direction, the results confirm the validity of the experience developed by the CNSN, at the moment all the services of Nuclear Medicine and Radiotherapy of Cuba possess quality control and safety programs, these programs are annually Auditing by an Authorized entity by the CNSN and the Inspectors of the Regulatory Authority, control, during the inspections, the one execution of the established requirements in the national regulations. The work developed so far can serve, modestly, of reference to others countries of Latin America that

The state of the art of nuclear medicine in 1980

International Nuclear Information System (INIS)

Tamat, S.R.

1982-01-01

The second congress of World Federation of Nuclear Medicine and Biology proved that nuclear medicine is returning to physiology. Around 1951, when motorized detector was introduced and when GM tube was replaced by scintillation crystal detector, physiologic nuclear medicine moved to anatomic nuclear medicine. Since 1970, when research on cardiology developed, nuclear medicine has been returning to physiology. Since 1963 Kuhl has been doing research on quantitative tomography which develops to emission computerized tomography emphasizing the physiological aspects of medicine. The recent contribution of nuclear medicine to medical science is the concept that human body is a unity of dynamic structure consisting of millions of cubes moving physio-chemically. (RUW)

SPECT/CT co-registration of nuclear medicine studies and technologists: challenges and victories

International Nuclear Information System (INIS)

Cameron, P.J.

2002-01-01

Full text: A dual modality SPECT/CT gamma camera was installed in the Department of Nuclear Medicine at Fremantle Hospital, WA in 2000. The challenges were satisfying the requirements of the Radiological Advisory Council of WA with respect to room modifications and presence of a radiographer during CT acquisitions and once installation was complete, learning to operate the camera in dual modality mode. The victories are making CT/SPECT acquisitions a simple and routine procedure and the impact of the co-registered studies in both diagnostic and therapeutic applications in our practice. Copyright (2002) The Australian and New Zealand Society of Nuclear Medicine Inc

The developments and applications of molecular nuclear medicine

International Nuclear Information System (INIS)

Fang Shengwei; Xi Wang; Zhang Hong

2009-01-01

Molecular nuclear medicine including PET and SPECT is one of the most important parts of the molecular imaging. The combinations of molecular unclear medicine with CT, MRI, ultrasound or optical imaging and synthesis of multimodality radiopharmaceuticals are the major trends of the development of nuclear medicine. Molecular nuclear medicine has more and more and more important value on the monitoring of response to biology involved gene therapy or stem cell therapy and the developments of new drug. (authors)

Nuclear medicine program progress report for quarter ending December 31, 1996

Energy Technology Data Exchange (ETDEWEB)

Knapp, F.F. Jr.; Beets, A.L.; Boll, R.; Luo, H.; McPherson, D.W.; Mirzadeh, S.

1997-03-20

In this report the authors describe the use of an effective method for concentration of the rhenium-188 bolus and the results of the first Phase 1 clinical studies for bone pain palliation with rhenium-188 obtained from the tungsten-188/rhenium-188 generator. Initial studies with therapeutic levels of Re-188-HEDP at the Clinic for Nuclear Medicine at the University of Bonn, Germany, have demonstrated the expected good metastatic uptake of Re-188-HEDP in four patients who presented with skeletal metastases from disseminated prostatic cancer with good pain palliation and minimal marrow suppression. In addition, skeletal metastatic targeting of tracer doses of Re-188(V)-DMSA has been evaluated in several patients with metastases from prostatic cancer at the Department of Nuclear Medicine at the Canterbury and Kent Hospital in Canterbury, England. In this report the authors also describe further studies with the E-(R,R)-IQNP ligand developed in the ORNL Nuclear Medicine Program as a potential imaging agent for detection of changes which may occur in the cerebral muscarinic-cholinergic receptors (mAChR) in Alzheimer`s and other diseases.

Investigation of public exposure resulted from the radioiodine delay tank facility of nuclear medicine department

Energy Technology Data Exchange (ETDEWEB)

Yusof, Mohd Fahmi Mohd, E-mail: mfahmi@usm.my; Ali, Abdul Muhaimin Mat; Abdullah, Reduan; Idris, Abdullah Waidi [School of Health Sciences, Universiti Sains Malaysia, 16150 Kota Bharu, Kelantan (Malaysia)

2016-01-22

The study is carried out to assess the exposure rate that could contribute to public exposure in a radioiodine ward delay tank facility of Radiotherapy, Oncology and Nuclear Medicine, Department, Hospital Universiti Sains Malaysia (HUSM). The exposure rate at several locations including the delay tank room, doorway and at the public walking route was measured using Victoreen 415P-RYR survey meter. The radioactive level of the {sup 131}I waste was measured using Captus 3000 well counting system. The results showed that exposure rate and total count of the delay tank sample increased when the radioiodine ward was fully occupied with patient and reduced when the ward was vacant. Occupancy of radioiodine ward for two consecutive weeks had dramatically increased the exposure rate around the delay tank and radioactive level of {sup 131}I waste. The highest exposure rate and radioactive level was recorded when the ward was occupied for two consecutive weeks with 177.00 µR/h and 58.36 kcpm respectively. The exposure rate decreased 15.76 % when the door of the delay tank room was closed. The exposure rate at public walking route decreased between 15.58 % and 36.92 % as the distance increased between 1 and 3 m.

Distribution of nuclear medicine service in Brazil

International Nuclear Information System (INIS)

Silva, Ana Carolina Costa da; Duarte, Alessandro; Santos, Bianca Maciel dos

2011-01-01

The Brazil does not posses a good distribution of nuclear medicine service por all his territory. This paper shows the difference among country regions as far the number of clinics of nuclear medicine as is concerning, and also doctors licensed in the area and radioprotection supervisors, both licensed by the Brazilian Nuclear Energy Commission (CNEN)

Computers in nuclear medicine: introductory concepts

International Nuclear Information System (INIS)

Weber, D.A.

1978-01-01

Computers play an important role in image and data processing in nuclear medicine. Applications extend from relatively simple mathematical processing of in vitro specimen assays to more sophisticated image reconstruction procedures for emission tomography. The basic concepts and terminology associated with computer applications in image and data processing in nuclear medicine are presented here

Radiation doses to the staff of a nuclear cardiology department

International Nuclear Information System (INIS)

Tsapaki, V.; Koutelou, M.; Theodorakos, A.; Kouzoumi, A.; Kitziri, S.; Tsiblouli, S.; Vardalaki, E.; Kyrozi, E.; Kouttou, S.

2002-01-01

The last years, new radiopharmaceuticals are used in a Nuclear Medicine (NM) Department. Nowadays, Single Photon Emission Computed Tomography (SPECT) is a method of routine imaging, a fact that has required increased levels of radioactivity in certain patient examinations. The staff that is more likely to receive the greatest radiation dose in a NM Department is the technologist who deals with performance of patient examination and injection of radioactive material and the nurse who is caring for the patients visiting the Department some of which being totally helpless. The fact that each NM Dept possesses equipment with certain specifications, deals with various kind of patients, has specific design and radiation protection measures which can differ from other NM Depts and uses various examination protocols, makes essential the need to investigate the radiation doses received by each member of the staff, so as to continuously monitor doses and take protective measures if required, control less experienced staff and ensure that radiation dose levels are kept as low as possible at all times. The purpose of the current study was to evaluate radiation dose to the nuclear cardiology department staff by thermoluminescent dosemeters (TLDs) placed on the the skin at thyroid and abdominal region as well as evaluating protection measures taken currently in the Dept

Estimation dose in patients of nuclear medicine. Implementation of a calculi program and methodology

International Nuclear Information System (INIS)

Prieto, C.; Espana, M.L.; Tomasi, L.; Lopez Franco, P.

1998-01-01

Our hospital is developing a nuclear medicine quality assurance program in order to comply with medical exposure Directive 97/43 EURATOM and the legal requirements established in our legislation. This program includes the quality control of equipment and, in addition, the dose estimation in patients undergoing nuclear medicine examinations. This paper is focused in the second aspect, and presents a new computer program, developed in our Department, in order to estimate the absorbed dose in different organs and the effective dose to the patients, based upon the data from the ICRP publication 53 and its addendum. (Author) 16 refs

Nuclear medicine imaging. An encyclopedic dictionary

International Nuclear Information System (INIS)

Thie, Joseph A.

2012-01-01

The rapidly growing and somewhat complex area of nuclear medicine imaging receives only limited attention in broad-based medical dictionaries. This encyclopedic dictionary is intended to fill the gap. More than 400 entries of between one and three paragraphs are included, defining and carefully explaining terms in an appropriate degree of detail. The dictionary encompasses concepts used in planar, SPECT, and PET imaging protocols and covers both scanner operations and popular data analysis approaches. In spite of the mathematical complexities in the acquisition and analysis of images, the explanations given are kept simple and easy to understand; in addition, many helpful concrete examples are provided. Nuclear Medicine Imaging: An Encyclopedic Dictionary will be ideal for those who wish to obtain a rapid grasp of a concept beyond a definition of a few words but do not want to resort to a time-consuming search of the reference literature. The almost tutorial-like style accommodates the needs of students, nuclear medicine technologists, and varieties of other medical professionals who interface with specialists within nuclear medicine.

[Implementation of a quality management system according to the UNE-UN-ISO 9001:2008 standard in a nuclear medicine department].

Science.gov (United States)

Poblete García, V M; Talavera Rubio, M P; Palomar Muñoz, A; Pilkington Woll, J P; Cordero García, J M; García Vicente, A M; Bellón Guardia, M; González García, B; Cañuelo Merino, T; Núñez García, A; Peiró Valgañón, V; Soriano Castrejón, A M

2013-01-01

To describe the process of implementing a quality management system according to UNE-EN-ISO 9001:2008 standard in a Nuclear Medicine Department. In February 2008, the committee on internal quality of the Department was established, naming a responsible physician. The general operating plan was drawn up, following the requirements established by the ISO 9001:2008 standard. It defined the scope of the standard, defining, preparing and transcribing the various activities of our Department. Four training sessions were carried out. A total of nine general and two specific procedures were documented in which all the activities performed in our Department were included. Personnel records of each worker were created, including their profiles and training plan. A record of the equipment and service providers was created, as well as issues with the latter. Satisfaction surveys were obtained from external (patients) and internal customers (faculty applicants). Targets for improvement and activity markers were established. Two audits were performed to complete the process, one internal and one external. The Department was accredited in April 2010. The quality accreditation process is a tool that requires reflection on how we do things and how they can be improved. It makes it possible to measure what we do, to analyze and introduce improvement measures, and therefore, to achieve a higher level of quality in the service we provide our customers. The involvement of the Department workers with a commitment to team performance was essential. Copyright © 2011 Elsevier España, S.L. and SEMNIM. All rights reserved.

Quality control of nuclear medicine instruments, 1991

International Nuclear Information System (INIS)

1996-12-01

This document gives detailed guidance on the quality control of various instruments used in nuclear medicine. A first preliminary document was drawn up in 1979. A revised and extended version, incorporating recommended procedures, test schedules and protocols was prepared in 1982. The first edition of 'Quality Control of Nuclear Medicine Instruments', IAEA-TECDOC-317, was printed in late 1984. Recent advances in the field of nuclear medicine imaging made it necessary to add a chapter on Camera-Computer Systems and another on SPECT Systems

Quality control of nuclear medicine instruments 1991

International Nuclear Information System (INIS)

1991-05-01

This document gives detailed guidance on the quality control of various instruments used in nuclear medicine. A first preliminary document was drawn up in 1979. A revised and extended version, incorporating recommended procedures, test schedules and protocols was prepared in 1982. The first edition of ''Quality Control of Nuclear Medicine Instruments'', IAEA-TECDOC-317, was printed in late 1984. Recent advances in the field of nuclear medicine imaging made it necessary to add a chapter on Camera-Computer Systems and another on SPECT Systems. Figs and tabs

SARIS: a tool for occupational radiation protection improvement in a Nuclear Medicine Department

International Nuclear Information System (INIS)

Lopez Diaz, A.

2015-01-01

Self-assessment is an organization's internal process to review its current status. The IAEA has developed the SARIS system (Self-Assessment of the Regulatory Infrastructure for Safety) with the objective to improve and encourage the compliment of safety requirements and recommendations of the international safety standards. With the purpose to improve the effectiveness and efficiency of the occupational radiation protection structure in the Nuclear Medicine Department (from 'Hermanos Ameijeiras' Hospital), we applied 3 questionnaires of the Occupational Radiation Protection Module of SARIS. During the answering phase we provided factual responses to questions, appended all necessary documentary evidence and avoided opinion that cannot be objectively supported by evidence. In the analysis phase we identified the strengths and weaknesses, the opportunities for improvement and the risks if action is not taken. We look the expert's opinion and made recommendations to prepare an action plan for improvement. The Cuban regulations have more strengths than weakness. The major weakness founded was: the documental evidence of the knowledge about the legislative safety responsibility of the management structure and workers could be improved. Upon completion of the self-assessment analysis phase, was developed an action plan, trying to cover all the discovered weakness, making emphasis in the improvement of all documental issue related to radiation safety responsibilities. Were defined the responsibilities and activities in the short, medium and long terms. The SARIS self-assessment tools let us to learn more about our organization and provided us the key elements for the organization's continuous development and improvement. (Author)

22. French language symposium on nuclear medicine

International Nuclear Information System (INIS)

1981-01-01

The 80 papers presented in summary form at the Congress are given. These papers cover three main topics: broncho-pulmonary investigation with radioaerosols; role of nuclear medicine in pharmacokinetics; role of Nuclear Medicine in metabolic investigations [fr

The 3rd Sino-Japan nuclear medicine conference

International Nuclear Information System (INIS)

1999-01-01

The 3rd Sino-Japan Nuclear Medicine Conference was hold on May 11-13, 1999 in Xi'an of China by Chinese Society of Nuclear Medicine, Japanese Society of Nuclear Medicine, Chinese Medicine Association and Japan-China Medicine Association. 62 articles were published in the proceeding of the conference. The contents of the articles include development and application of the radioisotopes (such as Tc-99, I-125, I-131, F-18, In-111, Tl-201, Ga-67, Sm-153, Re-188) and its radiopharmaceuticals, but application also include radiotherapy and diagnosis in the oncology and pathology by SPECT and PET

Report on the second Congress of the Russian nuclear medicine society and on International conference Current problems of nuclear medicine and radiopharmaceuticals

International Nuclear Information System (INIS)

Lishmanov, Yu.B.; Chernov, V.I.

2001-01-01

Information on the work of Second Congress of Russian Nuclear Medicine Society and International Conference - Current problems of nuclear medicine and radiopharmaceuticals, - held in Obninsk in October, 2000, is adduced. Reports presented in the conference are dedicated to various aspects of application of radionuclide methods to cardiology, angiology, oncology, surgery, hematology, endocrinology, pediatrics and neurology. Problems in the development of radiopharmaceutical, training and skill advancement of experts, dosimetry and radiation safety in nuclear medicine were discussed. Congress considered the organizational problems in Russian nuclear medicine [ru

Quality control in nuclear medicine

International Nuclear Information System (INIS)

Kostadinova, I.

2007-01-01

Nuclear medicine comprises diagnosis and therapy of the diseases with radiopharmaceuticals. The ambition of all specialists in our country is their activity to reach European standards. In this connection, a Commission for external audit was formed to evaluate the quality of work in the centers of nuclear medicine. This Commission create a long-lasting programme based on the objective European criteria and the national standard of nuclear medicine, having in mind to increase quality of the work and the expert evaluation of activity in every center. The program comprises measures for quality control of instrumentation, radiopharmaceuticals, performed investigations, obtained results and the whole organization from the receiving of the isotopes to the results of the patients. The ambition is most of the centers to fulfill the requirements. As a conclusion it could be said that not only the quality of everyday nuclear medicine work is enough to increase the prestige of the specialty. It is also necessary we to have understanding expert and financial support from corresponding institutions, incl. Ministry of health for a delivery of a new, contemporary instrumentation with new possibilities. Thus it would be possible Bulgarian patients to reach the high technology apparatuses for an early functional diagnosis of the diseases and optimal treatment, which possibility have the patients from the developed countries. (author)

Hand Dose in Nuclear Medicine Staff Members

International Nuclear Information System (INIS)

Taha, T.M.; Shahein, A.Y.; Hassan, R.

2009-01-01

Measurement of the hand dose during preparation and injection of radiopharmaceuticals is useful in the assessment of the extremity doses received by nuclear medicine personnel. Hand radiation doses to the occupational workers that handling 99m Tc-labeled compounds, 131 I for diagnostic in nuclear medicine were measured by thermoluminescence dosimetry. A convenient method is to use a TLD ring dosimeter for measuring doses of the diagnostic units of different nuclear medicine facilities . Their doses were reported in millisieverts that accumulated in 4 weeks. The radiation doses to the hands of nuclear medicine staff at the hospitals under study were measured. The maximum expected annual dose to the extremities appeared to be less than the annual limit (500 mSv/y) because all of these workers are on rotation and do not constantly handle radioactivity throughout the year

Lessons from other areas of medical imaging - nuclear medicine

International Nuclear Information System (INIS)

McCready, V.R.

1981-01-01

Ultrasound and nuclear medicine are similar in that they both have been developed for clinical use in the past decade. Unlike X-ray techniques the success or failure of ultrasound and nuclear medicine depend more upon both the operator and the method of display. Since both ultrasound and nuclear medicine use relatively complicated methods of gathering and displaying information some of the lessons learnt during the development of nuclear medicine can be equally applied to ultrasound techniques. (Auth.)

Nuclear medicine in Uzbekistan and current status of radionuclide therapy in the country

International Nuclear Information System (INIS)

Rasulova, N.; Khodjibekova, M.

2005-01-01

Full text: The population of Uzbekistan is 26 million and to cater to this population we have only two nuclear medicine departments; one at the Clinical Centre for Surgery and the other at the Institute of Endocrinology, both situated in Tashkent, the capital city of Uzbekistan. Over the years through its own initiatives and through the support provided by several International Organizations including the IAEA, Uzbekistan has been able to marginally improve its nuclear medicine services. SPECT imaging was introduced through generous support from IAEA in the year 2001. As a result of this, the country is now able to provide modern in vivo nuclear medicine service to the population in a limited scale. At the Clinical Centre for Surgery we are able to provide gamma camera and SPECT imaging services to patients suffering from various nephro-urological, cardiac, neuro and oncological disorders. The other nuclear medicine centre at the Institute of Endocrinology does not have any modern imaging system. However it has been engaged in providing radionuclide therapy service for thyroid diseases like thyroid cancer and hyperthyroidism. From the year 1983 to 1999 the country has reported a total number of 6374 cases of Thyroid Cancer. This number is growing each year, for example the incidence of thyroid cancer in 1989 was 1.95 per 100,000, which has grown to 2.39 per 100,000 in 1999. While the Institute of Endocrinology provides therapeutic service to thyroid diseases, the main role of the Nuclear Medicine Department of Republic Specialized Center of Surgery is in following-up of patients after therapy by performing large dose I-131 whole body imaging, screening for metastases and for assessment of results of radioactive iodine therapy. Besides treating thyroid diseases with I-131 limited services are also available for treatment of polycythemia vera rubra with P-32 and radionuclide therapy for metastatic bone pain. Radionuclide therapy is growing rapidly around the world

Protection of the patient in nuclear medicine

International Nuclear Information System (INIS)

1987-01-01

In ICRP Publication 52, the 'Protection of the Patient in Nuclear Medicine', is concerned with exposures of patients resulting from the administration of radiopharmaceuticals for diagnostic, therapeutic and research purposes. The report includes guidelines for nuclear medicine physicians, radiologists, medical physicists and technologists on the factors that influence absorbed doses to patients from different types of nuclear medicine examinations. Other topics in the report include education and training, estimates of absorbed dose, design of facilities, instrumentation, quality assurance and control and preparation, quality assurance and control of radiopharmaceuticals. (U.K.)

Research and career opportunities for chemists in nuclear medicine

International Nuclear Information System (INIS)

Welch, M.J.

1989-01-01

Two recent publications [Training Requirements for Chemists in Nuclear Medicine, Nuclear Industry, and Related Areas: Report of a Workshop National Academy Press, Washington, D.C., 1988, and Report of the Society of Nuclear Medicine Manpower Committee, Journal of Nuclear Medicine, January, 1989] have emphasized the opportunities for Chemists in Nuclear Medicine. These opportunities exist in Medical Centers, the Radiopharmaceutical Drug Industry as well as the Ethical Drug Industry of particular importance of the need for organic and inorganic chemists with knowledge and experience in radiochemistry to develop and prepare the radiopharmaceuticals needed for the Nuclear Medicine community. The number of positions available at present and anticipated in the future will be compared and the number of training programs listed. Examples of the types of opportunities in this area will be given

Interventional studies in nuclear medicine

International Nuclear Information System (INIS)

Saha, G.B.; Swanson, D.P.; Hladik, W.B. III

1987-01-01

Pharmacological interventions in nuclear medicine studies have been in practice for a long time. The triiodothyronine (T/sub 3/) suppression, Thyroid-stimulating hormone (TSH) stimulation, and perchlorate discharge tests are common examples of well-established diagnostic interventional studies. In recent years, pharmacologic and physiologic interventions in other nuclear medicine procedures have drawn considerable attention. The primary purpose of these interventions is to augment, complement or, more often, differentiate the information obtained from conventional nuclear medicine diagnostic studies. Pharmacologic interventions involve the administration of a specific drug before, during, or after the administration of radiopharmaceutical for a given study. The change in information due to intervention of the drug offers clues to differentiating various disease conditions. These changes can be brought about by physiologic interventions also, e.g., exercise in radionuclide ventriculography. In the latter interventions, the physiologic function of an organ is enhanced or decreased by physical maneuvers, and the changes observed can be used to differentiate various disease conditions

Highlights of articles published in annals of nuclear medicine 2016

International Nuclear Information System (INIS)

Jadvar, Hossein

2017-01-01

This article is the first installment of highlights of selected articles published during 2016 in the Annals of Nuclear Medicine, an official peer-reviewed journal of the Japanese Society of Nuclear Medicine. A companion article highlighting selected articles published during 2016 in the European Journal of Nuclear Medicine and Molecular Imaging, which is the official peer-reviewed journal of the European Association of Nuclear Medicine, will also appear in the Annals Nuclear Medicine. This new initiative by the respective journals will continue as an annual endeavor and is anticipated to not only enhance the scientific collaboration between Europe and Japan but also facilitate global partnership in the field of nuclear medicine and molecular imaging. (orig.)

Highlights of articles published in annals of nuclear medicine 2016

Energy Technology Data Exchange (ETDEWEB)

Jadvar, Hossein [University of Southern California, Division of Nuclear Medicine, Department of Radiology, Keck School of Medicine, Los Angeles, CA (United States)

2017-10-15

This article is the first installment of highlights of selected articles published during 2016 in the Annals of Nuclear Medicine, an official peer-reviewed journal of the Japanese Society of Nuclear Medicine. A companion article highlighting selected articles published during 2016 in the European Journal of Nuclear Medicine and Molecular Imaging, which is the official peer-reviewed journal of the European Association of Nuclear Medicine, will also appear in the Annals Nuclear Medicine. This new initiative by the respective journals will continue as an annual endeavor and is anticipated to not only enhance the scientific collaboration between Europe and Japan but also facilitate global partnership in the field of nuclear medicine and molecular imaging. (orig.)

Quality assurance of nuclear medicine instruments

International Nuclear Information System (INIS)

Soni, P.S.

1998-01-01

Quality assurance in nuclear medicine refers collectively to all aspects of a nuclear medicine programme that may contribute directly or indirectly to the quality of the results obtained. For examples, patients scheduling; preparation and dispensing of radiopharmaceutical; the protection of patients, staff and the general public against radiation hazards and accidents caused by faulty instruments; methodology, data interpretation and record keeping

Mentoring and the Nuclear Medicine Technologist.

Science.gov (United States)

Burrell, Lance

2018-06-08

The goal of this article is to give an overview of mentoring for nuclear medicine technologists (NMT). Mentoring is an integral part of the training and practice in the field of nuclear medicine technology. There is a great need for NMTs to continue involvement in mentorship so that we can develop and maintain the talent and leadership that the field needs. In this article, definitions of mentorship will be provided. Then, how mentoring can work; including different methods and techniques will be covered. Next, the benefits of mentoring will be discussed. Finally, advice for improved application will be presented. Throughout, this article will discuss how mentoring applies to the NMT. Copyright © 2018 by the Society of Nuclear Medicine and Molecular Imaging, Inc.

Nuclear techniques in medicine

International Nuclear Information System (INIS)

Basson, J.K.

1984-01-01

The use of nuclear techniques in medicine has, also in South Africa, increased enormously, especially as regards diagnosis and reseach. In 1983 in vivo tests with radioisotopes were carried out and also in vitro tests, mainly by radioimmunoassay. Therapy with open and sealed radioactive sources was concentrated mainly on cancer treatments. In 1983 NUCOR supported 83 research projects in the life sciences. Imaging of organs or tissues in the body with nuclear techniques has developed into the most important application of nuclear medicine, with the development of even more specific labelled compounds as the main objective. Radioimmunoassay is at an exciting watershed, now that labelled monoclonal antibodies with high specificity for early diagnosis (also in cancer) and even localised radiotherapy have become available. The establishment of the 200 MeV open-sector cyclotron by the National Accelerator Centre also for medical purposes will, in addition to the large-scale production of the protonrich isotopes, also make a substantial contribution to radiotherapy with nuclear particles such as neutrons, protons and helium-3

Poster - 03: How to manage a nuclear medicine PET-CT for radiation oncology patients

Energy Technology Data Exchange (ETDEWEB)

Hinse, Martin; Létourneau, Étienne; Duplan, Danny; Piché, Émilie; Rivière, Rose Nerla; Bouchard, Guillaume [Centre Intégré de Cancérologie de Laval (Canada)

2016-08-15

Purpose: Development of an adapted multidisciplinary procedure designed to optimize the clinical workflow between radiation therapy (RT) and nuclear medicine (NM) for a PET-CT located in the NM department. Methods : The radiation oncologist (RO) prescribes the PET-CT exam and the clinical RT therapist gives all the necessary information to the patient prior to the exam. The immobilization accessories are prepared in the RT department. The RT and NM therapists work together for radiotracer injection, patient positioning and scan acquisition. The nuclear medicine physician (NMP) will study the images, draw Biological Target Volumes (BTVs) and produce a full exam report. Results : All tasks related to a planning PET-CT are done within 48 hours from the request by the RO to the reception of the images with the NMP contours and report. Conclusions : By developing a complete procedure collectively between the RT and NM departments, the patient benefits of a quick access to a RT planning PET-CT exam including the active involvement of every medical practitioners in these fields.

Nuclear criticality safety department training implementation

International Nuclear Information System (INIS)

Carroll, K.J.; Taylor, R.G.; Worley, C.A.

1996-01-01

The Nuclear Criticality Safety Department (NCSD) is committed to developing and maintaining a staff of qualified personnel to meet the current and anticipated needs in Nuclear Criticality Safety (NCS) at the Oak Ridge Y-12 Plant. The NCSD Qualification Program is described in Y/DD-694, Qualification Program, Nuclear Criticality Safety Department This document provides a listing of the roles and responsibilities of NCSD personnel with respect to training and details of the Training Management System (TMS) programs, Mentoring Checklists and Checksheets, as well as other documentation utilized to implement the program. This document supersedes Y/DD-696, Revision 2, dated 3/27/96, Training Implementation, Nuclear Criticality Safety Department. There are no backfit requirements associated with revisions to this document

Nuclear Medicine Imaging Devices. Chapter 11

Energy Technology Data Exchange (ETDEWEB)

Lodge, M. A.; Frey, E. C. [Russell H. Morgan Department of Radiology and Radiological Sciences, Johns Hopkins University, Baltimore, MD (United States)

2014-12-15

Imaging forms an important part of nuclear medicine and a number of different imaging devices have been developed. This chapter describes the principles and technological characteristics of the main imaging devices used in nuclear medicine. The two major categories are gamma camera systems and positron emission tomography (PET) systems. The former are used to image γ rays emitted by any nuclide, while the latter exploit the directional correlation between annihilation photons emitted by positron decay. The first section of this chapter discusses the principal components of gamma cameras and how they are used to form 2-D planar images as well as 3-D tomographic images (single photon emission computed tomography (SPECT)). The second section describes related instrumentation that has been optimized for PET data acquisition. A major advance in nuclear medicine was achieved with the introduction of multi-modality imaging systems including SPECT/computed tomography (CT) and PET/CT. In these systems, the CT images can be used to provide an anatomical context for the functional nuclear medicine images and allow for attenuation compensation. The third section in this chapter provides a discussion of the principles of these devices.

Diagnostic reference activities for nuclear medicine procedures in Australia and New Zealand

International Nuclear Information System (INIS)

Smart, R.C.; Towson, J.E.

2000-01-01

In July 1998 a survey of diagnostic nuclear medicine procedures in Australia and New Zealand was undertaken on behalf of the Australian and New Zealand Society of Nuclear Medicine (ANZSNM) and the Australasian Radiation Protection Society (ARPS) in order to establish diagnostic reference activities. A total of 96 responses were received representing 154 practices, comprising 45 public hospital departments, 21 private hospital departments, 87 private practices and 1 unspecified practice. The survey requested the usual activities administered for a standard adult, the method used to determine the activity for children and the minimum activities used for paediatric patients. Data was obtained for 80 different imaging procedures and for 17 non-imaging tracer studies. For those procedures for which information was available from 10 or more practices, 68 in total, the reference activity was calculated as the 75th percentile of the distribution of activities. The Most Common Activity, the Reference Activity, together with the effective dose in both male and female patients, is tabulated for all these procedures. Copyright (2000) Australasian Radiation Protection Society Inc

1. A brief history of nuclear medicine

International Nuclear Information System (INIS)

Dienstbier, Z.

1989-01-01

The milestones of history of nuclear medicine are dealt with. A brief account is given of the history of nuclear medicine abroad, and a more in-depth treatment is devoted to Czechoslovakia, where the beginning of this branch of science dates to 1951. (Z.S.)

Nuclear medicine in the countries of Latin America

International Nuclear Information System (INIS)

Touya, Eh.

1987-01-01

The role of nuclear medicine in protection of health in Latin America states is shown. Nuclear medicine methods are applied in Latin America countries for diagnosis of coronary disease, cancer, malfunctioning of separate organs and transplants, kidney transplants in particular. The present situation in protection of health in the region is evaluated. It is emphasized that nuclear medicine should play its role in the course of public health improvement in those countries

Case assessments for nuclear medicine registrars

International Nuclear Information System (INIS)

Farlow, D.

1994-01-01

Westmead Hospital set some of the recent nuclear medicine cases for registrar training. These case assessments have been completed by the registrars and he thought it might be interesting for the general nuclear medicine community to attempt the cases themselves and compare their answers with the model reports and patient follow-ups. Edited versions of two cases and model answers are presented. 35 refs

Imaging in nuclear medicine

International Nuclear Information System (INIS)

Giussani, Augusto; Hoeschen, Christoph

2013-01-01

Presents the most recent developments in nuclear medicine imaging, with emphasis on the latest research findings. Considers the latest advances in imaging systems, image reconstruction, noise correction, and quality assurance. Discusses novel concepts, including those developed within the framework of the EURATOM FP7 MADEIRA project. Lists rules of thumb for imaging of use to both beginners and experienced researchers. This volume addresses a wide range of issues in the field of nuclear medicine imaging, with an emphasis on the latest research findings. Initial chapters set the scene by considering the role of imaging in nuclear medicine from the medical perspective and discussing the implications of novel agents and applications for imaging. The physics at the basis of the most modern imaging systems is described, and the reader is introduced to the latest advances in image reconstruction and noise correction. Various novel concepts are then discussed, including those developed within the framework of the EURATOM FP7 MADEIRA research project on the optimization of imaging procedures in order to permit a reduction in the radiation dose to healthy tissues. Advances in quality control and quality assurance are covered, and the book concludes by listing rules of thumb for imaging that will be of use to both beginners and experienced researchers.

Imaging in nuclear medicine

Energy Technology Data Exchange (ETDEWEB)

Giussani, Augusto [BfS - Federal Office for Radiation Protection, Oberschleissheim (Germany). Dept. of Radiation Protection and Health; Hoeschen, Christoph (eds.) [Helmholtz Zentrum Muenchen - German Research Center for Environmental Health, Neuherberg (Germany). Research Unit Medical Raditation Physics and Diagnostics

2013-08-01

Presents the most recent developments in nuclear medicine imaging, with emphasis on the latest research findings. Considers the latest advances in imaging systems, image reconstruction, noise correction, and quality assurance. Discusses novel concepts, including those developed within the framework of the EURATOM FP7 MADEIRA project. Lists rules of thumb for imaging of use to both beginners and experienced researchers. This volume addresses a wide range of issues in the field of nuclear medicine imaging, with an emphasis on the latest research findings. Initial chapters set the scene by considering the role of imaging in nuclear medicine from the medical perspective and discussing the implications of novel agents and applications for imaging. The physics at the basis of the most modern imaging systems is described, and the reader is introduced to the latest advances in image reconstruction and noise correction. Various novel concepts are then discussed, including those developed within the framework of the EURATOM FP7 MADEIRA research project on the optimization of imaging procedures in order to permit a reduction in the radiation dose to healthy tissues. Advances in quality control and quality assurance are covered, and the book concludes by listing rules of thumb for imaging that will be of use to both beginners and experienced researchers.

Nuclear medicine statistics

International Nuclear Information System (INIS)

Martin, P.M.

1977-01-01

Numerical description of medical and biologic phenomena is proliferating. Laboratory studies on patients now yield measurements of at least a dozen indices, each with its own normal limits. Within nuclear medicine, numerical analysis as well as numerical measurement and the use of computers are becoming more common. While the digital computer has proved to be a valuable tool for measurment and analysis of imaging and radioimmunoassay data, it has created more work in that users now ask for more detailed calculations and for indices that measure the reliability of quantified observations. The following material is presented with the intention of providing a straight-forward methodology to determine values for some useful parameters and to estimate the errors involved. The process used is that of asking relevant questions and then providing answers by illustrations. It is hoped that this will help the reader avoid an error of the third kind, that is, the error of statistical misrepresentation or inadvertent deception. This occurs most frequently in cases where the right answer is found to the wrong question. The purposes of this chapter are: (1) to provide some relevant statistical theory, using a terminology suitable for the nuclear medicine field; (2) to demonstrate the application of a number of statistical methods to the kinds of data commonly encountered in nuclear medicine; (3) to provide a framework to assist the experimenter in choosing the method and the questions most suitable for the experiment at hand; and (4) to present a simple approach for a quantitative quality control program for scintillation cameras and other radiation detectors

Computers. A perspective on their usefulness in nuclear medicine

International Nuclear Information System (INIS)

Loken, M.K.; Williams, L.E.; Ponto, R.A.; Ganatra, R.D.; Raikar, U.; Samuel, A.M.

1977-01-01

To date, many symposia have been held on computer applications in nuclear medicine. Despite all of these efforts, an appraisal of the true utility of computers in the day-to-day practice of nuclear medicine is yet to be achieved. Now that the technology of data storage and processing in nuclear medicine has reached a high degree of sophistication, as evidenced by many reports in the literature, the time has come to develop a perspective on the proper place of computers in nuclear medicine practice. The paper summarizes various uses of a dedicated computer (Nuclear Data Med II) at our two institutions and comments on its clinical utility. (author)

Historic images in nuclear medicine

DEFF Research Database (Denmark)

Hess, Søren; Høilund-Carlsen, Poul Flemming; Alavi, Abass

2014-01-01

In 1976, 2 major molecular imaging events coincidentally took place: Clinical Nuclear Medicine was first published in June, and in August researchers at the Hospital of the University of Pennsylvania created the first images in humans with F-FDG. FDG was initially developed as part of an evolution...... set in motion by fundamental research studies with positron-emitting tracers in the 1950s by Michel Ter-Pegossian and coworkers at the Washington University. Today, Clinical Nuclear Medicine is a valued scientific contributor to the molecular imaging community, and FDG PET is considered the backbone...

Basics of radiobiology and nuclear medicine

International Nuclear Information System (INIS)

Kostadinova, I.; Hadjidekova, V.; Georgieva, R.

2002-01-01

The authors successively reveal the topics of the biological impact of radiation (radiobiology) and the diagnostic and the therapeutic application of radiopharmaceuticals (nuclear medicine). Data on the influence of radiation on subcellular, cellular, tissue and organ level are given, on early and late radiation changes, as well. Indication for the application of the different radionuclide methods in the diagnosis of the diseases in the endocrinology, nephrology, cardiology, gastroenterology, haematology of lungs, bones, tumors are pointed out and the main trends of the growing therapeutical use of nuclear medicine are presented. The aim is to teach students the nuclear medicine methods in the complex investigation of the patients, his preliminary preparation and the biological impact of radiation and its risk. Self assessment test for students are proposed and a literature for further reading

Course on internal dosimetry in nuclear medicine; Curso de dosimetria interna en medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

NONE

2004-07-01

This documentation was distributed to the participants in the Course of Internal Dosimetry in Nuclear Medicine organised by the Nuclear Regulatory Authority (ARN) of Argentina and held in Buenos Aires, Argentina, August 9-13, 2004. The course was intended for people from IAEA Member States in the Latin American and Caribbean region, and for professionals and workers in medicine, related with the radiation protection. Spanish and English were the languages of the course. The following subjects were covered: radioprotection of the patient in nuclear medicine; injuries by ionizing radiations; MIRD methodology; radiation dose assessment in nuclear medicine; small scale and microdosimetry; bone and marrow dose modelling; medical internal dose calculations; SPECT and image reconstruction; principles of the gamma camera; scattering and attenuation correction in SPECT; tomography in nuclear medicine.

Department of Nuclear Safety Research and Nuclear Facilities annual report 1995

Energy Technology Data Exchange (ETDEWEB)

Majborn, B.; Brodersen, K.; Damkjaer, A.; Floto, H.; Jacobsen, U.; Oelgaard, P.L. [eds.

1996-03-01

The report presents a summary of the work of the Department of Nuclear Safety Research and Nuclear Facilities in 1995. The department`s research and development activities are organized in three research programmes: Radiation Protection, Reactor Safety, and Radioanalytical Chemistry. The nuclear facilities operated by the department include the Research Reactor DR3, the Isotope Laboratory, the Waste Treatment Plant, and the Educational Reactor DR1. Lists of staff and publications are included together with a summary of the staff`s participation in national and international committees. (au) 5 tabs., 21 ills.

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... variety of diseases, including many types of cancers, heart disease, gastrointestinal, endocrine, neurological disorders and other abnormalities within the body. Because nuclear medicine procedures are ...

Challenges for nuclear medicine in the 1990s

International Nuclear Information System (INIS)

Ell, P.J.

1992-01-01

This article discusses the problems facing nuclear medicine in the coming decade and outlines the areas in which new developments or expansion can be expected. The questions considered include legislative requirements, the need to educate the public and the medical profession on the strengths of nuclear medicine, approaches to cost-benefit analysis, and development of new technologies and new radiopharmaceuticals. There is also an evaluation of expansion in nuclear medicine using both existing methodology and new methodologies. (author)

Analysis of Personal Dosimetry for Nuclear Medicine Staff in Ten-Year Period

International Nuclear Information System (INIS)

Poropat, M.; Dodig, D.; Ciglar, M.; Tezak, S.

2011-01-01

The aim of this study was to assess the value of personal dosimetry for nuclear medicine personnel in our department in a ten-year period. We have analyzed personal doses for 80 employees in nuclear medicine in a ten year period that we divided into two five year periods (from 2000 to 2004 and from 2005 to 2009). The personnel was dived into 8 groups according to their working assignments due to different radiation exposure from various radioisotopes in different wards in nuclear medicine: nuclear medicine specialists, technologists in scintigraphy ward, personnel of physics ward, ward for radiochemistry and radioimmunology, clinical ward and ultrasound ward, cleaning personnel, administrative personnel. We have compared average dose per person in particular ward in two five year periods. All doses for all personnel were in the permissible limits prescribed by the authorities. Higher average dose per person in a first five year period was detected in two wards, scintigraphy ward and ward for radiochemistry and radioimmunology due to the nature of their working assignments (preparation and application of radiopharmaceuticals, contact with patients who have received radiopharmaceutical). The decrease in the average dose per person was noticed in a second five-year period, especially in the wards with personnel that had no prior education in ionizing radiation protection. The decrease of dose was from 7.5 % to 84.2 %. We think that the decrease of average dose per person in a second five-year period was not only the result of the increased personal protection measures but also the result of continuing education of nuclear medicine personnel that is obligatory by the Law for ionizing radiation protection from year 1999, and the results from a ten-year period show its positive effect on radiation protection. (author)

Quality assurance in nuclear medicine

International Nuclear Information System (INIS)

Kaul, A.

1986-01-01

'Quality Assurance in Nuclear Medicine' is the title of the English language original that has been translated into German. The manual very extensively deals with quality control of nuclear medical equipment. Tests are explained for checking radioactivity measuring devices, manual and automatic in-vitro sample measuring systems, in-vivo measuring systems with single or multiple detectors, rectlinear scanners, and gamma cameras, including the phantoms required for the methods. Other chapters discuss the quality control of radiopharmaceuticals, or the quality assurance in data recording and evaluation of results. Helpful comments on the organisation of quality assurance programms are given. The book is intended as a practical guide for introducing quality assurance principles in nuclear medicine in the Federal Republic of Germany. With 13 figs., 22 tabs [de

Patient absorbed dose and radiation risk in nuclear medicine

International Nuclear Information System (INIS)

Hetherington, E.; Cochrane, P.

1992-01-01

Since the introduction of technetium-99m labelled radiopharmaceuticals used as imaging agents in the nuclear medicine departments of Australian hospitals, patients have voiced concern about the effect of having radioactive materials injected into their bodies. The danger of X-ray exposure is widely known and well accepted, as is exposure to ultrasound, computed tomography scans and other imaging techniques. However, radioactivity is an unknown, and fear of the unknown can occasionally lead to patients refusing to undergo a nuclear medicine procedure. The authors emphasised that the radiation dose to a patient from a typical procedure would depend on the patient's medical history and treatment; the average dose being approximately 50 times the exposure received from the natural environmental background radiation. Furthermore, over an extended period the body can repair most minor damage caused by radiation, just as the body can repair the damage caused by sunburn resulting from too much exposure to sunlight. The risk of genetic effects as a result of a medical radiation dose is than very small

The practice of nuclear medicine in the Philippines

International Nuclear Information System (INIS)

San Luis, T.O.L.

1996-01-01

The advent of nuclear medicine in the early 1940's came with the use of radioiodine in the study of thyroid physiology and eventual treatment of hyperthyroidism. Instrumentation to detect radionuclides introduced into the human body, and the production of various radiopharmaceuticals as tracers or as therapy agents provided the impetus for the rapid development of nuclear medicine as a distinct specialty. In the Philippines, nuclear medicine formally began in 1956 with the establishment of the Radioisotope Laboratory at the Philippine General Hospital. Acquisition of nuclear instrumentation by various institutions, training of medical staff and personnel, sourcing of radiopharmaceuticals proceeded thereafter

Guidelines for patient information in nuclear medicine

International Nuclear Information System (INIS)

Anon.

2010-01-01

This guide for patients information in nuclear medicine is organised in the following manner: what is a medical examination in nuclear medicine, the preparation and the duration of the examination, the possible risks and the radiation doses, pregnancy, delayed menstruation and nursing and what to do after the examination. (N.C.)

Complementary alternative medicine and nuclear medicine

International Nuclear Information System (INIS)

Werneke, Ursula; McCready, V.Ralph

2004-01-01

Complementary alternative medicines (CAMs), including food supplements, are taken widely by patients, especially those with cancer. Others take CAMs hoping to improve fitness or prevent disease. Physicians (and patients) may not be aware of the potential side-effects and interactions of CAMs with conventional treatment. Likewise, their known physiological effects could interfere with radiopharmaceutical kinetics, producing abnormal treatment responses and diagnostic results. Nuclear medicine physicians are encouraged to question patients on their intake of CAMs when taking their history prior to radionuclide therapy or diagnosis. The potential effect of CAMs should be considered when unexpected therapeutic or diagnostic results are found. (orig.)

Nuclear medicine and related radionuclide applications in developing countries

International Nuclear Information System (INIS)

1986-01-01

The Symposium presentations were divided into sessions devoted to the following topics: Radioimmunoassay and related techniques (4 papers and 4 poster presentations); Radionuclide applications in the diagnosis of parasitic diseases (7 papers and 2 posters); Instrumentation (6 papers and 4 posters); Clinical nuclear medicine: liver, bones, thyroid, cardiovascular system, lungs, kidneys, brain (23 papers and 15 posters); Organization of nuclear medicine services in the developing countries (9 papers and 5 posters); Training in nuclear medicine (4 papers) and the panel discussion. Future of Nuclear Medicine in the developing countries. A separate abstract was prepared for each of these papers and posters

Introduction to nuclear medicine

International Nuclear Information System (INIS)

Denhartog, P.; Wilmot, D.M.

1987-01-01

In this chapter, the fundamentals of nuclear medicine, the advantages and disadvantages of this modality (compared with radiography and ultrasound), and some of the areas in diagnosis and treatment in which it has found widest acceptance will be discussed. Nuclear medicine procedures can be broadly categorized into three groups: in vivo imaging, usually requiring the injection of an organ-specific radiopharmaceutical; in vitro procedures, in which the radioactive agent is mixed with the patient's blood in a test tube; and in vivo nonimaging procedures, in which the patient receives the radiopharmaceutical (intravenously or orally) after which a measurement of the amount appearing in a particular biological specimen (blood, urine, stool) is performed. In vivo imaging procedures will be the principal topics of this chapter

Quality Management Audits in Nuclear Medicine Practices. 2. Ed

International Nuclear Information System (INIS)

2015-01-01

Quality management systems are essential and should be maintained with the intent to continuously improve effectiveness and efficiency, enabling nuclear medicine to achieve the expectations of its quality policy, satisfy its customers and improve professionalism. The quality management (QM) audit methodology in nuclear medicine practice, introduced in this publication, is designed to be applied to a variety of economic circumstances. A key outcome is a culture of reviewing all processes of the clinical service for continuous improvement in nuclear medicine practice. Regular quality audits and assessments are vital for modern nuclear medicine services. More importantly, the entire QM and audit process has to be systematic, patient oriented and outcome based. The management of services should also take into account the diversity of nuclear medicine services around the world and multidisciplinary contributions. The latter include clinical, technical, radiopharmaceutical, medical physics and radiation safety procedures

Patient preparation for nuclear medicine studies

International Nuclear Information System (INIS)

Stathis, V.J.; Cantrell, D.W.; Cantrell, T.J.

1987-01-01

In this chapter are described methods of patient preparation that can favorably affect the outcome of nuclear medicine studies in specific situations. Some of these practices may be considered essential to the success of the nuclear medicine procedure, whereas others may be thought of simply as a means of obtaining more valid or reliable information. Regardless of relative importance, each of the preparatory methods discussed can contribute to the quality of the respective study and can serve as a means of maximizing the value of nuclear medicine procedures. The specific patient preparation techniques discussed in this chapter may not be readily applicable to every practice setting or situation. These or similar procedures can be used or modified as necessary. It is important, however, that when new protocols are developed, the rationale and theoretical basis of each technique be considered

Children's (Pediatric) Nuclear Medicine

Medline Plus

Full Text Available ... Because the doses of radiotracer administered are small, diagnostic nuclear medicine procedures result in low radiation exposure, acceptable for diagnostic exams. Thus, the radiation risk is very low ...

Nuclear Criticality Safety Department Qualification Program

International Nuclear Information System (INIS)

Carroll, K.J.; Taylor, R.G.; Worley, C.A.

1996-01-01

The Nuclear Criticality Safety Department (NCSD) is committed to developing and maintaining a staff of highly qualified personnel to meet the current and anticipated needs in Nuclear Criticality Safety (NCS) at the Oak Ridge Y-12 Plant. This document defines the Qualification Program to address the NCSD technical and managerial qualification as required by the Y-1 2 Training Implementation Matrix (TIM). This Qualification Program is in compliance with DOE Order 5480.20A and applicable Lockheed Martin Energy Systems, Inc. (LMES) and Y-1 2 Plant procedures. It is implemented through a combination of WES plant-wide training courses and professional nuclear criticality safety training provided within the department. This document supersedes Y/DD-694, Revision 2, 2/27/96, Qualification Program, Nuclear Criticality Safety Department There are no backfit requirements associated with revisions to this document

The state of the art in nuclear medicine

International Nuclear Information System (INIS)

Scott, A.M.

1999-01-01

Recent improvements in the understanding of the physiologic and biologic mechanisms of health and disease have led to an expansion of nuclear medicine applications both in clinical studies and research. Advances in radiopharmaceutical development, instrumentation and computer processing have resulted in the implementation of Positron Emission Tomography for clinical studies, and improved treatments with radiopharmaceuticals particularly in cancer patients. There has also been a dramatic increase in the techniques available with nuclear medicine to detect and measure cellular biologic events in-vivo, which have important implications in clinical and basic science research. Nuclear medicine studies provide unique information on human physiology and remain an integral part of clinical medicine practice

Metabolic radiopharmaceutical therapy in nuclear medicine; Terapia metabolica mediante radiofarmacos en medicina nuclear

Energy Technology Data Exchange (ETDEWEB)

Reguera, L.; Lozano, M. L.; Alonso, J. C.

2016-08-01

In 1986 the National Board of Medical Specialties defined the specialty of nuclear medicine as a medical specialty that uses radioisotopes for prevention, diagnosis, therapy and medical research. Nowadays, treatment with radiopharmaceuticals has reached a major importance within of nuclear medicine. The ability to treat tumors with radiopharmaceutical, Radiation selective therapy has become a first line alternative. In this paper, the current situation of the different therapies that are sued in nuclear medicine, is reviewed. (Author)