在 CATANA 中对 62 MeV 质子束的场内和场外微剂量学特性进行研究。

Centre of Medical and Radiation Physics, University of Wollongong, Wollongong, NSW, Australia.

NSTLI Nuclear Stewardship, Australian Nuclear Science and Technology Organization, Lucas Heights, NSW, Australia.

Med Phys. 2021 Aug;48(8):4532-4541. doi: 10.1002/mp.14905. Epub 2021 Jun 23.

PURPOSE

A 5 and 10 μm thin silicon on insulator (SOI) 3D mushroom microdosimeter was used to characterize both the in-field and out-of-field of a 62 MeV proton beam.

METHODS

The SOI mushroom microdosimeter consisted of an array of cylindrical sensitive volumes (SVs), developed by the Centre for Medical Radiation Physics, University of Wollongong, was irradiated with 62 MeV protons at the CATANA (Centro di AdroTerapia Applicazioni Nucleari Avanzate) facility in Catania, Italy, a facility dedicated to the radiation treatment of ocular melanomas. Dose mean lineal energy, ( ), values were obtained at various depths in PMMA along a pristine and spread out Bragg peak (SOBP). The measured microdosimetric spectra at each position were then used as inputs into the modified Microdosimetric Kinetic Model (MKM) to derive the RBE for absorbed dose in a middle of the SOBP 2Gy (RBE ). Microdosimetric spectra were obtained with both the 5 and 10 μm 3D SOI microdosimeters, with a focus on the distal part of the BP. The in-field and out-of-field measurement configurations along the Bragg curve were modeled in Geant4 for comparison with experimental results. Lateral out-of-field measurements were performed to study secondary particles' contribution to normal tissue's dose, up to 12 mm from the edge of the beam field, and quality factor and dose equivalent results were obtained.

RESULTS

Comparison between experimental and simulation results showed good agreement between one another for both the pristine and SOBP beams in terms of and RBED. Though a small discrepancy between experiment and simulation was seen at the entrance of the Bragg curve, where experimental results were slightly lower than Geant4. The dose equivalent value measured 12 mm from the edge of the target volume was 1.27 ± 0.15 mSv/Gy with a value of 2.52 ± 0.30, both of which agree within uncertainty with Geant4 simulation.

CONCLUSIONS

These results demonstrate that SOI microdosimeters are an effective tool to predict RBED in-field as well as dose equivalent monitoring out-of-field to provide insight to probability of second cancer generation.

目的

使用 5μm 和 10μm 厚的硅衬底绝缘体（SOI）3D 蘑菇微剂量计来描述 62MeV 质子束的场内和场外剂量分布。

方法

SOI 蘑菇微剂量计由一组圆柱状敏感体积（SV）组成，由伍伦贡大学医学辐射物理中心开发，在意大利卡塔尼亚的 CATANA（先进核应用放射治疗中心）设施中用 62MeV 质子照射，该设施专门用于眼部黑色素瘤的放射治疗。在 PMMA 中沿原始布拉格峰（SOBP）和展宽布拉格峰（SOBP）获得不同深度处的剂量平均线性能量（）值。然后，将每个位置的测量微剂量谱用作输入，输入到改进的微剂量动力学模型（MKM）中，以获得 SOBP 中间 2Gy 吸收剂量的相对生物效应（RBE）。使用 5μm 和 10μm 厚的 3D SOI 微剂量计获得微剂量谱，重点研究 SOBP 的远端部分。沿着布拉格曲线的场内和场外测量配置在 Geant4 中进行建模，以便与实验结果进行比较。进行侧向场外测量以研究次级粒子对正常组织剂量的贡献，直至离束场边缘 12mm 处，并获得品质因数和剂量当量结果。

结果

实验结果与模拟结果之间的比较表明，在原始和 SOBP 束方面，和 RBE 都有很好的一致性。尽管在布拉格曲线入口处实验结果略低于 Geant4，但实验结果与模拟结果之间存在很小的差异。从靶体积边缘测量到的剂量当量值为 1.27±0.15mSv/Gy，值为 2.52±0.30，这两个值与 Geant4 模拟值在不确定度范围内一致。