铅笔束扫描质子治疗中能量特异性准直的LET增强。

IF 2 4区医学 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Journal of Applied Clinical Medical Physics Pub Date : 2024-12-07 DOI:10.1002/acm2.14477

Blake R. Smith, Daniel E. Hyer

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引用次数: 0

摘要

目的：通过计算表征PBS动态准直过程中的LET分布，并量化其对合成剂量分布的影响。方法：利用Geant4进行蒙特卡罗模拟，模拟了新型PBS准直器准直组件中低能质子散射的产生。通过IBA专用喷嘴系统模型模拟的单个光束场和复合场产生的能量、轨迹和剂量平均LET，可以创建定制的光谱统计。优化了复合剂量分布，以实现立方体和金字塔目标的均匀物理剂量覆盖，并计算了未准直和准直PBS递送的剂量平均LET分布，并用于生成rbe加权剂量分布。结果：对于准直光束，散射质子能量的影响强烈依赖于相对于光束中心轴的准直器位置。当提供均匀剖面时，剂量平均LET在目标内的分布几乎相同，并且在目标周围10 mm内增加1至2 keV / μ m $2 \,{\rm keV}/\mathrm{\umu}\mathrm{m}$。动态准直导致了更大的剂量平均LET变化：增加了1到3 keV / μ m之间的剂量平均LET $3 \,{\rm keV}/\mathrm{\umu}\mathrm{m}$ 10 \,{\rm keV}/\mathrm{\umu}\mathrm{m}$ 10 \,{\rm keV}/\mathrm{\umu}$ 10 \之外的剂量平均LET $10 \。生物剂量分布改善与能量特异性准直在减少侧半影。结论：相对于未准直的递送，PBS中能量特异性准直的存在可导致剂量平均LET变化。在一些临床情况下，能量特异性准直的放置和应用可能需要额外的规划考虑，基于其减少到外侧半影和增加高剂量一致性。未来的应用可能体现这些独特的剂量学特征，以重定向准直质子束中来自健康组织的高LET部分，同时增强靶内的剂量平均LET分布。

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The LET enhancement of energy-specific collimation in pencil beam scanning proton therapy

Purpose

To computationally characterize the LET distribution during dynamic collimation in PBS and quantify its impact on the resultant dose distribution.

Methods

Monte Carlo simulations using Geant4 were used to model the production of low-energy proton scatter produced in the collimating components of a novel PBS collimator. Custom spectral tallies were created to quantify the energy, track- and dose-averaged LET resulting from individual beamlet and composite fields simulated from a model of the IBA dedicated nozzle system. The composite dose distributions were optimized to achieve a uniform physical dose coverage of a cubical and pyramidal target, and the resulting dose-average LET distributions were calculated for uncollimated and collimated PBS deliveries and used to generate RBE-weighted dose distributions.

Results

For collimated beamlets, the scattered proton energy fluence is strongly dependent on collimator position relative to the central axis of the beamlet. When delivering a uniform profile, the distribution of dose-average LET was nearly identical within the target and increased between 1 and $2 keV / μ m$ within 10 mm surrounding the target. Dynamic collimation resulted in larger dose-average LET changes: increasing the dose-average LET between 1 and $3 keV / μ m$ within 10 mm of a pyramidal target while reducing the dose-average LET outside this margin by as much as $10 keV / μ m$ . Biological dose distributions are improved with energy-specific collimation in reducing the lateral penumbra.

Conclusion

The presence of energy-specific collimation in PBS can lead to dose-average LET changes relative to an uncollimated delivery. In some clinical situations, the placement and application of energy-specific collimation may require additional planning considerations based on its reduction to the lateral penumbra and increase in high-dose conformity. Future applications may embody these unique dosimetric characteristics to redirect high-LET portions of a collimated proton beamlet from healthy tissues while enhancing the dose-average LET distribution within target.

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来源期刊

Journal of Applied Clinical Medical Physics 医学-核医学

CiteScore

3.60

自引率

19.00%

发文量

331

审稿时长

3 months

期刊介绍： Journal of Applied Clinical Medical Physics is an international Open Access publication dedicated to clinical medical physics. JACMP welcomes original contributions dealing with all aspects of medical physics from scientists working in the clinical medical physics around the world. JACMP accepts only online submission. JACMP will publish: -Original Contributions: Peer-reviewed, investigations that represent new and significant contributions to the field. Recommended word count: up to 7500. -Review Articles: Reviews of major areas or sub-areas in the field of clinical medical physics. These articles may be of any length and are peer reviewed. -Technical Notes: These should be no longer than 3000 words, including key references. -Letters to the Editor: Comments on papers published in JACMP or on any other matters of interest to clinical medical physics. These should not be more than 1250 (including the literature) and their publication is only based on the decision of the editor, who occasionally asks experts on the merit of the contents. -Book Reviews: The editorial office solicits Book Reviews. -Announcements of Forthcoming Meetings: The Editor may provide notice of forthcoming meetings, course offerings, and other events relevant to clinical medical physics. -Parallel Opposed Editorial: We welcome topics relevant to clinical practice and medical physics profession. The contents can be controversial debate or opposed aspects of an issue. One author argues for the position and the other against. Each side of the debate contains an opening statement up to 800 words, followed by a rebuttal up to 500 words. Readers interested in participating in this series should contact the moderator with a proposed title and a short description of the topic