Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Updating the Planar Patterson-Parker Table for Ir-192 and Cs-137 Brachytherapy Sources Using the Most Recent TG-43U1 Recommended Dosimetric Parameters
EN
Z.
Naghshnezhad
Department of Medical Radiation Engineering, Shiraz University, Shiraz, Iran
znaghsh@gmail.com
R.
Faghihi
Department of Medical Radiation Engineering, Shiraz University, Shiraz, Iran
M. A.
Mosleh-Shirazi
Center for Research in Medical Physics and Biomedical Engineering, and Department of Radiotherapy, Shiraz University of Medical Sciences, Shiraz, Iran
A. S.
Meigooni
Comprehensive Cancer Center of Nevada, 3730 S. Eastern Dr., Las Vegas, NV, USA
Background: The Patterson-Parker table was created in 1934 to determine mg-hr required to deliver the prescribed dose to the treatment area. These tables were created using the dosimetric data for 226Ra that was determined in air and were utilized for dose calculations around implants with Ra-equivalent radionuclides such as 137Cs and 192Ir. Therefore, the differences of the tissue attenuation and anisotropy of these radionuclides and their impact on dose uniformity of the implants were ignored. Objective: In this study, the Patterson-Parker table has been updated for 137Cs and 192Ir sources using their recent dosimetric data. Furthermore, the dose uniformity for different loading schemes, as a function of the implant area, was tested. Methods: The updated Paterson-Parker tables were generated for 137Cs and 192Ir sources using their published dosimetric parameters that have been determined following the American Association of Physicists in Medicine (AAPM) Task group 43 (TG-43U1) recommendations. The accuracies of the updated tables were examined by two independent methods, Monte Carlo simulation technique and a commercially available treatment planning system. In addition to the dose values along the central axis of the implant, dose profiles along two orthogonal directions were evaluated for the selection of the optimal radioactivity distribution in an implant. Results: We found that the original Paterson-Parker loading scheme of the radioactivity as a function of the implant size has to be adjusted to achieve the optimal dose distribution (1000 cGy ±10%) in an implant. In addition, it was shown that the same implant size for the mg-hr required for 137Cs was not identical to that of 192Ir. Similarly, there were some differences between the updated table and the published Paterson-Parkers tables. Independent Monte Carlo simulations and treatment planning data had excellent agreement with the updated data. Conclusion: The conventional version of Paterson-Parker tables are not useful for the two commonly used brachytherapy sources. The updated version of the tables should be used instead.
Paterson-Parker table,TG-43,Dosimetry,Ir-192,Cs-137
https://jbpe.sums.ac.ir/article_43024.html
https://jbpe.sums.ac.ir/article_43024_fc5f962418a62368526ebcd17ea2eb49.pdf
Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Genetic Feedforward-Feedback Controller for Functional Electrical Stimulation Control of Elbow Joint Angle
EN
N.
Hesam Shariati
Biomedical Engineering Faculty, Amirkabir University of Technology, Tehran, Iran.
negin_hsh@aut.ac.ir
A.
Maleki
Electrical and Computer Engineering Faculty, Semnan University, Semnan, Iran.
A.
Fallah
Biomedical Engineering Faculty, Amirkabir University of Technology, Tehran, Iran.
Background: Functional electrical stimulation (FES) is the most commonly used system for restoring functions after spinal cord injury (SCI). Objective: In this study we investigated feedback PID and feedforward-feedback P-PID controllers for regulating the elbow joint angle. Methods: The controllers were tuned based on a nonlinear muculoskeletal model containing two links, one joint with one degree of freedom and two muscles in the sagittal plane that was simulated in MATLAB using Sim Mechanics and Simulink toolboxes. The first tune of the PID and P-PID controllers was done by trial and error. Then, the coefficients were optimized by genetic algorithm (GA). For checking the robustness of the controllers, we compared the amount of rise time, settling time, maximum overshoot and steady state error under three conditions: the first was when the initial angle of the joint was fixed and only the desired angles changed; the second was with a fixed step as input and various initial angles; and the last condition was with different maximum forces for muscle.Results: Genetic controllers had better performance than the trial and error tuned controllers. The amounts of settling time were not so different for the controllers in condition 1 but had more variations in condition 2 and had really better results in genetic P-PID in condition 3. The overshoot was pretty less in PIDs than in P-PIDs and the steady state error was almost zero for all of the controllers. Conclusion: Genetic controllers had a better performance than the trial and error tuned controllers. The rise time was much less in P-PIDs than in PIDs.
Functional electrical stimulation,Feedforward-feedback,PID controller,genetic algorithm
https://jbpe.sums.ac.ir/article_43027.html
https://jbpe.sums.ac.ir/article_43027_04a616d780757c123a5d0cd6a69ad40b.pdf
Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Natural Radioactivity in Drinking Water of Drilled Wells in Zanjan, Northwestern Iran
EN
F.
Saghatchi
Department of Radiology, Faculty of Paramedical and Health, Zanjan University of Medical Sciences, Zanjan, Iran
saloutim@yahoo.com
M.
Salouti
Department of Biology, Faculty of Sciences, Zanjan Branch, Islamic Azad University, Zanjan, Iran
Background: Many radioactive compounds may be released into the environment and hence into the drinking water supplies due to the human activities. Radionuclides can also enter the food chain if the contaminated water is used for drinking or irrigation purposes. Objective: To estimate the annual effective dose of natural radioactive materials like 226Ra and 40K in drinking water of wells in Zanjan, nortwestern Iran. Methods: 82% of drinking water in Zanjan comes from drilled wells. Water samples from the main sites of drinking water from different parts of Zanjan were collected. The amount of 226Ra and 40K were measured by gamma-ray spectrometry using a NaI (Tl) detector. The annual effective dose of the radioactive materials was calculated for children (2–7 years old) and adults (≥17 years old) with annual water intake of 350 and 500 L, respectively. The annual effective dose received by residents of the city due to consumption of the contaminated drinking water was also calculated. Results: The mean±SD concentrations of 226Ra and 40K were 32.4±7.8 and 20.5±27.4 Bq/L, respectively. The mean±SD annual effective dose received by residents of the city due to consumption of the contaminated drinking water was 7.13±1.76 and 4.59±1.12 mSv/y for children and adults, respectively. Conclusion: The level of radioactive compounds in water of drilled wells in Zanjan is significantly higher than the ICRP permissible limit of 1 mSv/y.
Natural radioactivity,226Ra,40K,Drinking water,Drilled wells,Annual effective dose
https://jbpe.sums.ac.ir/article_43028.html
https://jbpe.sums.ac.ir/article_43028_fedeb05c6e62beaafa0f3d335e24aada.pdf
Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Radio-Protective Effects of Some bis-Thiosemicarbazone Compounds
EN
A. R.
Shirazi
Department of Medical Physics and Biomedical Engineering, Faculty of Medicine, Tehran University of Medical Sciences, Tehran, Iran
shirazia@sina.tums.ac.ir
Z.
Mehdipour
Department of Medical Radiation Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
A. R.
Jalilian
Radiopharmaceutical Research and Development Lab, Nuclear Science and Technology Research Institute (NSTRI), Tehran, Iran
E.
Mihandoost
Department of Medical Radiation Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
Background: GTS, PTSM and ATSM are bis-thiosemicarbazone ligands used in the preparation of copper radiopharmaceuticals. Chemical structure of these materials indicates that they should have radio-protective effects.Objective: To study the radio-protective effects of GTS, PTSM and ATSM. Methods: This study has focused on radio-protective effects of these compounds at different doses (20, 40 and 80 μg) and with time intervals of 1 and 4 h before the whole-body gamma-irradiation. The survival curves were plotted for different groups after one month post-irradiation. The effective doses of these compounds were also calculated from the survival study. In the next step, biochemical markers of hepatic function, aspartate aminotransferase (AST) and alanine aminotransferase (ALT) were determined in a hepatotoxicity study. Results: Administration of ATSM did not cause any serious side effects and hepatotoxicity in a mice model—AST and ALT enzyme levels in a group of animals that received 80 μg of ATSM showed no significant difference with that in the control group. However, AST and ALT enzymes rose significantly in those mice that received 40 μg of GTS compared to the control group even 7 days post-injection. Conclusion: It seems that ATSM is a better candidate on which to carry out further research for protection against irradiation.
Radio-protective agents,ATSM,PTSM,GTS,AST,ALT
https://jbpe.sums.ac.ir/article_43029.html
https://jbpe.sums.ac.ir/article_43029_a6871513b0448cc02ef4b583d6cb3d8c.pdf
Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Hybrid Phantom Applications to Nuclear Medicine
EN
E.
Hoseinian Azghadi
PhD Student of Nuclear Physics, Physics Department, School of Sciences, Ferdowsi University of Mashhad, Mashhad, Iran
eliehssnn@yahoo.com
L.
Rafat Motavalli
Assistant Professor of Nuclear Physics, Physics Department, School of Sciences, Ferdowsi University of Mashhad, Mashhad, Iran
H.
Miri Hakimabad
Associate Professor of Nuclear Physics, Physics Department, School of Sciences, Ferdowsi University of Mashhad, Mashhad, Iran
Annually, many people are irradiated for diagnostic and therapeutic purposes. Assessment of radiation dose and its related risks to patients are important issues in radiation protection dosimetry. The complex mathematical calculations of the absorbed and effective doses are now done with computers. The calculations are performed with the help of anthropomorphic computational models of human body called phantoms and Monte Carlo codes (MCNP). There are various types of phantoms, yet the latest type is hybrid phantom which has been introduced to the scientific community in recent years. Hybrid phantom is the connection between mathematical and voxel phantoms. They retain both the anatomic realism of voxel phantoms and the flexibility of mathematical phantoms. Using hybrid phantoms, the absorbed doses can be determined for any patients before they are exposed to radiation. Then, the energy of the emitted particles and irradiation geometry can be determined for any special purposes. We constructed hybrid phantoms for Iranian patients to be used in different applications such as testing new radiopharmaceuticals or cancer treatments with high LET radiation. Herein, we report on our findings.
Computational phantoms,Hybrid phantoms,Dosimetry,Nuclear medicine
https://jbpe.sums.ac.ir/article_43026.html
https://jbpe.sums.ac.ir/article_43026_2075e636578c8ff6af113ac68e7699f0.pdf
Shiraz University of Medical Sciences
Journal of Biomedical Physics and Engineering
2251-7200
2
1
2012
03
01
Photothermal Effect of Laser on Mole Removal: Analytical Model and Laser Suitability
EN
H.
Nadgaran
Physics Department, Laser and Optics Center, Shiraz University, Shiraz 71454, Iran
maryam19258@gmail.com
M.
Mahmoodi
Physics Department, Science and Research Branch, Islamic Azad University, Fars, Iran
Photothermal,Laser,Mole,Analytical,Laser Suitability
https://jbpe.sums.ac.ir/article_43025.html
https://jbpe.sums.ac.ir/article_43025_eb2604aa352d9c750d30ab4d1554a365.pdf