用于质子治疗射程验证的康普顿相机中的次级粒子相互作用

Secondary Particle Interactions in a Compton Camera Designed for Range Verification of Proton Therapy.

作者信息

Panthi Rajesh, Maggi Paul, Peterson Stephen, Mackin Dennis, Polf Jerimy, Beddar Sam

机构信息

The University of Texas M. D. Anderson Cancer Center, Houston, Texas 77030, USA.

University of Maryland School of Medicine, Baltimore, Maryland 21201, USA.

出版信息

IEEE Trans Radiat Plasma Med Sci. 2021 May;5(3):383-391. doi: 10.1109/trpms.2020.3030166. Epub 2020 Oct 12.

DOI:10.1109/trpms.2020.3030166

PMID:34056151

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8153369/

Abstract

The purpose of this study was to determine the types, proportions, and energies of secondary particle interactions in a Compton camera (CC) during the delivery of clinical proton beams. The delivery of clinical proton pencil beams ranging from 70 to 200 MeV incident on a water phantom was simulated using Geant4 software (version 10.4). The simulation included a CC similar to the configuration of a Polaris J3 CC designed to image prompt gammas (PGs) emitted during proton beam irradiation for the purpose of range verification. The interaction positions and energies of secondary particles in each CC detector module were scored. For a 150-MeV proton beam, a total of 156,688(575) secondary particles per 10 protons, primarily composed of gamma rays (46.31%), neutrons (41.37%), and electrons (8.88%), were found to reach the camera modules, and 79.37% of these particles interacted with the modules. Strategies for using CCs for proton range verification should include methods of reducing the large neutron backgrounds and low-energy non-PG radiation. The proportions of interaction types by module from this study may provide information useful for background suppression.

摘要

本研究的目的是确定在临床质子束传输过程中康普顿相机（CC）内次级粒子相互作用的类型、比例和能量。使用Geant4软件（版本10.4）模拟了能量范围为70至200 MeV的临床质子笔形束入射到水模体上的情况。该模拟包括一个与北极星J3 CC配置相似的CC，其设计目的是对质子束辐照期间发射的瞬发伽马射线（PG）进行成像，以进行射程验证。对每个CC探测器模块中次级粒子的相互作用位置和能量进行了记录。对于150 MeV的质子束，每10个质子中共有156,688（575）个次级粒子到达相机模块，这些粒子主要由伽马射线（46.31%）、中子（41.37%）和电子（8.88%）组成，其中79.37%的粒子与模块发生相互作用。将CC用于质子射程验证的策略应包括减少大量中子本底和低能非PG辐射的方法。本研究中各模块相互作用类型的比例可能为背景抑制提供有用信息。

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