Nanodosimetric investigation of the track structure of therapeutic carbon ion radiation part2: detailed simulation.

IF 1.3 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Biomedical Physics & Engineering Express Pub Date : 2024-11-21 DOI:10.1088/2057-1976/ad9152
Miriam Schwarze, Gerhard Hilgers, Hans Rabus
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Abstract

Objectivea previous study reported nanodosimetric measurements of therapeutic-energy carbon ions penetrating simulated tissue. The results are incompatible with the predicted mean energy of the carbon ions in the nanodosimeter and previous experiments with lower energy monoenergetic beams. The purpose of this study is to explore the origin of these discrepancies.Approachdetailed simulations using the Geant4 toolkit were performed to investigate the radiation field in the nanodosimeter and provide input data for track structure simulations, which were performed with a developed version of the PTra code.Main resultsthe Geant4 simulations show that with the narrow-beam geometry employed in the experiment, only a small fraction of the carbon ions traverse the nanodosimeter and their mean energy is between 12% and 30% lower than the values estimated using the SRIM software. Only about one-third or less of these carbon ions hit the trigger detector. The track structure simulations indicate that the observed enhanced ionization cluster sizes are mainly due to coincidences with events in which carbon ions miss the trigger detector. In addition, the discrepancies observed for high absorber thicknesses of carbon ions traversing the target volume could be explained by assuming an increase in thickness or interaction cross-sections in the order of 1%.Significancethe results show that even with strong collimation of the radiation field, future nanodosimetric measurements of clinical carbon ion beams will require large trigger detectors to register all events with carbon ions traversing the nanodosimeter. Energy loss calculations of the primary beam in the absorbers are insufficient and should be replaced by detailed simulations when planning such experiments. Uncertainties of the interaction cross-sections in simulation codes may shift the Bragg peak position.

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治疗性碳离子辐射轨道结构的纳米模拟研究。第 2 部分:详细模拟。
目的: 先前的一项研究报告了治疗能量碳离子穿透模拟组织的纳米模拟测量结果。测量结果与纳米剂量计中预测的碳离子平均能量不符,也与之前使用较低能量的单能量束进行的实验不符。本研究的目的是探索这些差异的根源:使用 Geant4 工具包进行了详细模拟,以研究纳米计量计中的辐射场,并为轨迹结构模拟提供输入数据。这些碳离子中只有大约三分之一或更少击中触发探测器。轨道结构模拟表明,观测到的电离簇尺寸增大主要是由于与碳离子错过触发探测器的事件相吻合。此外,假定碳离子穿越目标体积的吸收体厚度增加或相互作用截面增加 1%,就可以解释碳离子穿越目标体积的吸收体厚度高时观察到的差异。吸收器中主光束的能量损耗计算是不够的,在规划此类实验时应以详细的模拟来代替。模拟代码中相互作用截面的不确定性可能会移动布拉格峰的位置。
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来源期刊
Biomedical Physics & Engineering Express
Biomedical Physics & Engineering Express RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
2.80
自引率
0.00%
发文量
153
期刊介绍: BPEX is an inclusive, international, multidisciplinary journal devoted to publishing new research on any application of physics and/or engineering in medicine and/or biology. Characterized by a broad geographical coverage and a fast-track peer-review process, relevant topics include all aspects of biophysics, medical physics and biomedical engineering. Papers that are almost entirely clinical or biological in their focus are not suitable. The journal has an emphasis on publishing interdisciplinary work and bringing research fields together, encompassing experimental, theoretical and computational work.
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