高能电子治疗规划：显示该模式潜力的研究

IF 3.4 Q2 ONCOLOGY

Physics and Imaging in Radiation Oncology Pub Date : 2024-10-01 DOI:10.1016/j.phro.2024.100670

James L. Bedford, Uwe Oelfke

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引用次数: 0

摘要

背景和目的与光子相比，使用甚高能电子（VHEE）进行放疗有可能减少危险器官的剂量。因此，本文对 VHEE 的治疗计划进行了回顾，以明确该模式的潜在益处。材料与方法对有关 VHEE 的文章进行了识别，并人工筛选出那些关注治疗计划的文章，尤其是那些包含患者数据集结果的文章。结果发现增加射束能量可减少电子散射，使半影更窄，但导致深度剂量曲线相当恒定，不像质子那样有助于保护正常组织。超高频电子显微镜的尖锐半影有利于治疗计划的制定，从而产生适形剂量整形的治疗计划，多个治疗部位的关键结构的剂量都得到了改善。与规定剂量相比，关键结构的平均剂量比光子低 0-10%，比质子高 0-10%。结论目前，相对于光子或质子，VHEE 的潜在临床效益还很小。还需要进一步研究，以更精确地量化宽光束与铅笔束扫描的相对性能，并调查可能从使用 VHEE 光束中获益最大的治疗部位。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Treatment planning for very high energy electrons: Studies that indicate the potential of the modality

Background and purpose

Radiotherapy using Very High Energy Electrons (VHEE) has the potential to reduce dose to organs at risk compared to photons. This article therefore reviews treatment planning for VHEE, to clarify the potential benefit of the modality.

Materials and methods

Articles on VHEE were identified and those which focused on treatment planning were manually selected, particularly those which contained results on patient datasets. Benefits in absorbed dose to organs at risk were converted to percentages of prescription dose so as to provide uniform, clinically relevant reporting.

Results

Increased beam energy was found to reduce electron scatter and give rise to a narrower penumbra but lead to a rather constant depth dose curve, which was not as useful for sparing normal tissues as that of protons. The sharp penumbra of VHEE was of benefit in treatment planning for producing treatment plans with conformal dose shaping, with improved dose to critical structures being demonstrated for several treatment sites. Mean dose to critical structures, relative to the prescribed dose, was in the order of 0–10% lower than photons and 0–10% higher than protons. The delivery technology and dose distributions were also promising for radiotherapy with ultra-high dose rate (FLASH).

Conclusion

At present, the potential clinical benefit of VHEE relative to photons or protons is small. Further studies are needed to more precisely quantify the relative performance of broad beams versus pencil beam scanning and to investigate treatment sites that might benefit maximally from the use of VHEE beams.

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来源期刊

Physics and Imaging in Radiation Oncology Physics and Astronomy-Radiation

CiteScore

5.30

自引率

18.90%

发文量

审稿时长

6 weeks