Photoneutron production mechanisms, their characteristics, and shielding strategies in high-energy linac environment: A review

IF 1.7 4区综合性期刊 Q2 MULTIDISCIPLINARY SCIENCES Journal of Radiation Research and Applied Sciences Pub Date : 2024-07-18 DOI:10.1016/j.jrras.2024.101031

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Abstract

Radiotherapy, a mainstay cancer treatment for patients worldwide, utilizes medical linear accelerators (linacs) with photon energies ranging from 4 MV to 25 MV. However, concerns arise at higher energies (>6 MV, particularly >10 MV). These high-energy photons interact with high-atomic number materials in the linac head and collimation system, generating unwanted neutrons through (γ,n) reactions. This neutron contamination, present in both photon and electron beams, is a significant issue. Neutrons, with their high Linear Energy Transfer (LET), are more effective at causing clustered DNA damage (single and double-strand breaks). These neutrons not only impact shielding requirements in treatment rooms but also increase out-of-field radiation doses for patients receiving high-energy photon therapy. Therefore, for radiotherapy treatments exceeding 6 MV, additional precautions become crucial, including enhanced door shielding and optimized treatment planning. This review discusses in detail the multifaceted aspects of neutron production and shielding requirements during radiotherapy.

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高能直列加速器环境中的光中子产生机制、特征和屏蔽策略：综述

放疗是全球癌症患者的主要治疗手段，它使用光子能量从 4 MV 到 25 MV 不等的医用直线加速器（linacs）。然而，在更高能量（6 MV，尤其是 10 MV）时，问题就出现了。这些高能光子与直列加速器头部和准直系统中的高原子序数材料相互作用，通过（γ,n）反应产生不需要的中子。这种中子污染在光子束和电子束中都存在，是一个重要问题。中子的线性能量转移（LET）很高，能更有效地造成成簇的 DNA 损伤（单链和双链断裂）。这些中子不仅会影响治疗室的屏蔽要求，还会增加接受高能光子治疗的患者的场外辐射剂量。因此，对于超过 6 MV 的放射治疗，额外的预防措施变得至关重要，包括加强门屏蔽和优化治疗计划。本综述将详细讨论放疗期间中子产生和屏蔽要求的多方面问题。

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来源期刊

Journal of Radiation Research and Applied Sciences MULTIDISCIPLINARY SCIENCES-

自引率

5.90%

发文量

130

审稿时长

16 weeks

期刊介绍： Journal of Radiation Research and Applied Sciences provides a high quality medium for the publication of substantial, original and scientific and technological papers on the development and applications of nuclear, radiation and isotopes in biology, medicine, drugs, biochemistry, microbiology, agriculture, entomology, food technology, chemistry, physics, solid states, engineering, environmental and applied sciences.