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《中国医学物理学杂志》[ISSN:1005-202X/CN:44-1351/R]

卷:

41卷

期数:

2024年第6期

页码:

661-666

栏目:

医学放射物理

出版日期:

2024-06-25

文章信息/Info

Title:

Beam trajectory correction and dose distribution in the presence of fringe fields in magnetic resonance imaging-guided proton therapy

文章编号:

1005-202X（2024）06-0661-06

作者:

李国栋1; 王明1; 薛景硕2; 董浪1; 孙甜甜1; 代伟1; 张磊1

1.成都理工大学核技术与自动化工程学院， 四川 成都 610059； 2.浙江省肿瘤医院放射物理科/中国科学院杭州医学研究所， 浙江 杭州 310022

Author(s):

LI Guodong1;  WANG Ming1;  XUE Jingshuo2;  DONG Lang1;  SUN Tiantian1;  DAI Wei1;  ZHANG Lei1

1. College of Nuclear Technology and Automation Engineering, Chengdu University of Technology, Chengdu 610059, China 2. Department of Radiation Physics, Zhejiang Cancer Hospital/Hangzhou Institute of Medicine, Chinese Academy of Sciences, Hangzhou 310022, China

关键词:

质子治疗; 磁共振图像引导; 边缘场; 束流轨迹校正

Keywords:

Keywords: proton therapy magnetic resonance imaging-guided fringe field beam trajectory correction

分类号:

R318；R811.1

DOI:

DOI:10.3969/j.issn.1005-202X.2024.06.001

文献标志码:

A

摘要:

目的：研究磁共振图像引导质子治疗中边缘场存在时束流轨迹的校正和校正前后机体中剂量变化。方法：使用开源的治疗计划软件matRad对脑肿瘤、肝脏肿瘤、前列腺癌病例进行计划设计，并在蒙特卡罗模拟工具包TOPAS中进行模拟研究，计算质子剂量分布。建立一种适用于三维磁场的质子束轨迹校正模型，并基于此开发一个束流轨迹校正算法。分析边缘场存在时，质子布拉格峰的偏转情况。对边缘场存在时的3种肿瘤治疗计划模拟并进行剂量校正，使用γ分析法评估校正效果，定量分析校正后靶区和危及器官中的剂量变化情况。结果：磁场的扰动会使质子束轨迹发生横向偏转，而边缘场的存在会显著地增加这一影响，且随束流能量的增加而增加。边缘场存在时，对脑肿瘤、肝脏肿瘤和前列腺癌治疗计划进行校正，在3%/3 mm标准下靶区γ通过率分别为94.844%、92.054%、97.863%，校正后体内的总剂量分别增加2.8%、2.5%和1.5%，增加的剂量主要由入射质子贡献。结论：在磁共振图像引导质子治疗中，应该考虑边缘场带来的影响。校正后入射质子束能量的增加会导致体内总剂量的增加，由于束流轨迹仍然存在曲率，在不同危及器官中剂量的变化不同。

Abstract:

Abstract: Objective To explore the correction of beam trajectories in the presence of fringe fields in magnetic resonance imaging-guided proton therapy and dose changes in the body before and after correction. Methods The open-source treatment planning software matRad was used to design plans for brain tumor, liver tumor, and prostate cancer cases, and simulation studies were conducted in the Monte Carlo simulation toolkit TOPAS to calculate proton dose distribution. A proton beam trajectory correction model suitable for three-dimensional magnetic fields was established, and a beam trajectory correction algorithm was developed. The deflection of the proton Bragg peak in the presence of fringe fields was analyzed. Furthermore, 3 treatment plans were simulated and dose correction was carried out when the fringe field existed. Gamma analysis method is used to evaluate the correction effect and the dose changes in the target area and organs-at-risk after correction were quantitatively analyzed. Results The perturbation of the magnetic field would cause lateral deflection of the proton beam trajectory, and the presence of fringe fields would significantly increase this effect, which increased with the increasing of beam energy. When the fringe field existed, the treatment plans for brain tumor, liver tumor, and prostate cancer were corrected. Under the 3%/3 mm criterion, the gamma passing rates for target area were 94.844%, 92.054%, and 97.863%, respectively, and after correction, the total dose in the body was increased by 2.8%, 2.5%, and 1.5%, respectively. The increased dose was mainly contributed by incident protons. Conclusion In magnetic resonance imaging-guided proton therapy, the effects of fringe fields should be considered. The increase in incident proton beam energy after correction will lead to an increase in the total dose in the body. Since the beam trajectory still has curvature, the dose changes differently in different organs-at-risk.

备注/Memo

备注/Memo:

【收稿日期】2024-01-19 【基金项目】国家自然科学基金（12105030）；四川省教育厅科研基金（2022NSFSC1185） 【作者简介】李国栋，硕士研究生，研究方向：医学物理，E-mail: liguodongi@163.com 【通信作者】王明，副教授，硕士生导师，研究方向：医学物理，E-mail: wangming1@cdut.edu.cn

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更新日期/Last Update: 2024-06-25