Isfahan University of Medical Sciences

Science Communicator Platform

Stay connected! Follow us on X network (Twitter):
Share By
Essential Considerations for Accurate Evaluation of Photoneutron Contamination in Radiotherapy Publisher Pubmed



Karimi AH1 ; Brkic H2, 3 ; Shahbazigahrouei D4 ; Haghighi SB5 ; Jabbari I6
Authors

Source: Applied Radiation and Isotopes Published:2019


Abstract

Nowadays, high-energy X-rays produced by medical linear accelerators (LINACs) are widely used in many Radiation Therapy (RT) centers. High-energy photons (> 8 MeV) produce undesired neutrons in the LINAC head which raise concerns about unwanted neutron dose to the patients and RT personnel. Regarding the significance of radiation protection in RT, it is important to evaluate photoneutron contamination inside the RT room. Unfortunately, neutron dosimeters used for this purpose have limitations that can under the best conditions cause to > 10% uncertainty. In addition to this uncertainty, the present Monte Carlo (MC) study introduces another uncertainty in measurements (nearly up to 20%) when neutron ambient dose equivalent (H n * (10)) is measured at the patient table or inside the maze and the change in neutron energy is ignored. This type of uncertainty can even reach 35% if H n * (10) is measured by dosimeters covered by a layer of 10 B as converter. So, in these cases, neglecting the change in neutron energy can threaten the credibility of measured data and one should attend to this energy change in order to reduce measurement uncertainty to the possible minimum. This study also discusses the change in neutron spectra and H n * (10) at the patient table caused by removing a typical RT room from MC simulations. Under such conditions, neutron mean energy (E n ) overestimated by 0.2–0.4 MeV at the patient table. Neutron fluence (φ n ) at the isocenter (IC) was underestimated by 23–54% for different field sizes that caused H n * (10) to be miscalculated up to 24%. This finding informs researchers that for accurate evaluation of H n * (10) at the patient table, simulating the RT room is an effective parameter in MC studies. © 2018 Elsevier Ltd
Related Docs
View other Related Docs
1. Photoneutron Contamination From an 18 Mv Saturne Medical Linear Accelerator in the Treatment Room, Radiation Protection Dosimetry (2013)
2. Feasibility of 18-Mv Grid Therapy From Radiation Protection Aspects: Unwanted Dose and Fatal Cancer Risk Caused by Photoneutrons and Scattered Photons, Computer Methods and Programs in Biomedicine (2022)
3. Photoneutron Shielding Design for an 18 Mv Saturne 20 Medical Linear Accelerator, Journal of Isfahan Medical School (2014)
Experts (# of related papers)
View all Related Experts
Daryoush Shahbazi-Gahrouei (6)
Ahmad Shanei (4)
Other Related Docs
4. Evaluation of Risk of Secondary Thyroid Cancer Caused by Neutron Dose Equivalent From Brain Tumor 3D-Conformal Radiation Therapy (3D-Crt), Journal of Isfahan Medical School (2020)
5. Measurement of Photoneutron Dose Produced by Wedge Filters of a High Energy Linac Using Polycarbonate Films, Journal of Radiation Research (2008)
6. The Influence of Brass Compensator Thickness and Field Size on Neutron Contamination Spectrum in 18Mv Elekta Sl 75/25 Medical Linear Accelerator With and Without Flattening Filter: A Monte Carlo Study, Journal of Biomedical Physics and Engineering (2018)
7. Monte Carlo Evaluation of Out-Of-Field Dose in 18 Mv Pelvic Radiotherapy Using a Simplified Female Mird Phantom, Biomedical Physics and Engineering Express (2022)
8. Determination of the Neutron Contamination During Brain Radiotherapy Using a Moderated-Boron Trifluoride Detector and the Mcnp Monte Carlo Code, Radiation Protection Dosimetry (2022)
9. Semi-Experimental Assessment of Neutron Equivalent Dose and Secondary Cancer Risk for Off-Field Organs in Glioma Patients Undergoing 18-Mv Radiotherapy, PLoS ONE (2022)
10. Measurement of Photoneutron Dose in the Linear Accelerator at the Radiation Therapy Section of Seyed-Al-Shohada Hospital, Isfahan, Iran, Journal of Isfahan Medical School (2012)
11. A Study of the Photoneutron Dose Equivalent Resulting From a Saturne 20 Medical Linac Using Monte Carlo Method, Nukleonika (2007)
12. Assessment of Skyshine Photon Dose Rates From 9 and 18 Mv Medical Linear Accelerators, International Journal of Radiation Research (2018)
13. The Effect of Field Modifier Blocks on the Fast Photoneutron Dose Equivalent From Two High-Energy Medical Linear Accelerators, Radiation Protection Dosimetry (2008)
14. Comparison of Three Methods of Calculation, Experimental and Monte Carlo Simulation in Investigation of Organ Doses (Thyroid, Sternum, Cervical Vertebra) in Radioiodine Therapy, Journal of Medical Signals and Sensors (2012)
15. Evaluation of Targeted Image-Guided Radiation Therapy Treatment Planning System by Use of American Association of Physicists in Medicine Task Group-119 Test Cases, Journal of Medical Signals and Sensors (2018)
16. Monte Carlo Simulation of Siemens Oncor Linear Accelerator With Beamnrc and Dosxyznrc Code, Journal of Medical Signals and Sensors (2013)
17. Determination of Breast-Absorbed Dose Using Conjugated View Method in Patients Undergoing Perfusion Scan With Radiotracer 99Mtc-Sestamibi, Journal of Isfahan Medical School (2016)
18. Comparison of Nuclear-Medicine-Technologist Absorb Dose in Myocardial Perfusion Scan Between Responsible for Injection and Imaging, Journal of Isfahan Medical School (2016)
19. Dosimetric Characteristics of 137Cs Sources Used in After Loading Selectron System by Monte Carlo Method, Iranian Journal of Radiation Research (2007)
20. Measurement of Ipsilateral Lung and Heart Dose in Radiotherapy of Left Sided Mastectomy Patients in Common Different Clinical Techniques: A Phantom Study, International Journal of Radiation Research (2018)