用geant4 DNA工具包研究不同能量质子对DNA的直接损伤

Q4 Health Professions
Z. A. Ganjeh, M. Eslami-Kalantari, M. E. Loushab, A. Mowlavi
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引用次数: 1

摘要

背景:计算了在0.1~40MeV质子能量范围内,直接单链断裂(SSBs)和双链断裂(DSBs)的总产额。虽然该领域的其他研究没有使用能量低于0.5MeV的质子,但我们的结果显示了这些质子有趣而复杂的行为。材料和方法:使用Geant4 DNA工具包进行模拟。模拟了DNA几何结构的原子模型。在细胞核入口处用Z轴方向上的源进行模拟,质子在0.1MeV步进中的能量为0.1-1MeV,在10MeV步进中为5MeV和10-40MeV。结果:计算出的SSB产率从0.1MeV质子能的60.08(GbpGy)下降到0.5MeV质子能量的49.52(GbpGy)−1,然后在40MeV时增加到54.35(GbpGy)。DSB产率从0.1MeV质子能量的4.32(GbpGy)降低到40MeV质子的1.03(GbpGy)。对于小于0.5MeV的能量,DSB产率约为56%,而对于其他能级,则为44%。至于SSB的产率,35%的断裂来自能量小于0.5MeV的质子,65%来自更高的能量。结论:发现能量小于0.5MeV的质子范围小于细胞大小(10μm),并且100%的能量沉积在细胞区域。那么,具有这些能量的质子是增加
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation of the direct DNA damages irradiated by protons of different energies using geant4-DNA toolkit
Background: The total yields of direct Single-Strand Breaks (SSBs) and Double -Strand Breaks (DSBs) in proton energies varying from 0.1 to 40 MeV were calculated. While other studies in this field have not used protons with energy less than 0.5 MeV, our results show interesting and complicated behavior of these protons. Materials and Methods: The simulation has been done using the Geant4-DNA toolkit. An atomic model of DNA geometry was simulated. Simulations were performed with a source in the Z-axis direction at the cell nucleus entrance with protons at energies of 0.1-1 MeV in 0.1 MeV steps, 5 MeV, and 10-40 MeV in 10 MeV steps. Results: The calculated SSB yields decreased from 60.08 (GbpGy) for 0.1 MeV proton energy to 49.52 (GbpGy) −1 for 0.5 MeV proton energy, and then it increased to 54.35 (GbpGy) in 40 MeV. The DSB yields decreased from 4.32 (GbpGy) for 0.1 MeV proton energy to 1.03 (GbpGy) for 40-MeV protons. The DSB yields for energies less than 0.5 MeV was about 56%, and for the other energy levels, it was 44%. As for SSB yields, 35% of the breaks arose from protons with an energy of fewer than 0.5 MeV and 65% from higher energies. Conclusion: It was found that the proton ranges with an energy less than 0.5 MeV are smaller than the cell size (10 μm), and 100% of the energy is deposited in the cell region. Then protons with these energies are the best choice to increase the number of
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来源期刊
Iranian Journal of Radiation Research
Iranian Journal of Radiation Research RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
0.67
自引率
0.00%
发文量
0
审稿时长
>12 weeks
期刊介绍: Iranian Journal of Radiation Research (IJRR) publishes original scientific research and clinical investigations related to radiation oncology, radiation biology, and Medical and health physics. The clinical studies submitted for publication include experimental studies of combined modality treatment, especially chemoradiotherapy approaches, and relevant innovations in hyperthermia, brachytherapy, high LET irradiation, nuclear medicine, dosimetry, tumor imaging, radiation treatment planning, radiosensitizers, and radioprotectors. All manuscripts must pass stringent peer-review and only papers that are rated of high scientific quality are accepted.
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