基于蒙特卡罗的离子束传输到TPS的PET验证的实现

Q1 Health Professions

Radiation Medicine and Protection Pub Date : 2022-09-01 DOI:10.1016/j.radmp.2022.08.001

Pablo Yepes , Zhuangming Shen , Michael F. Moyers , Qianxia Wang , Hongliang Chen , Jie Li , Yongqiang Li , James Lin

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引用次数: 1

摘要

目的研制并实现一种基于诱导放射性模拟并与患者正电子发射断层扫描(PET)对比的离子束远程治疗验证系统。方法将蒙特卡罗算法集成到内部构建的处理、信息、管理和规划系统(TIMPS®)中，计算离子束诱导正电子发射体的分布。这些分布被处理以模拟PET图像，考虑到正电子扩散、放射性衰变、生物冲洗和探测器模糊。研究人员还开发了其他工具来将模拟PET图像与计划CT图像进行配准，并对测量和模拟PET图像进行比较。结果得到了不同同位素和材料的生产截面。对几个不同身体部位的治疗方案进行了验证，以验证质子和碳离子束的新工具的功能和效用。已经开发了几种工具来模拟离子束照射患者的PET扫描，并将模拟图像与测量结果进行比较。在调试和实施到诊所后，考虑不确定性的边际的适当大小可能会被调查。

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Implementation of Monte Carlo based PET verification of ion beam delivery into a TPS

Objective

To develop and implement an ion beam teletherapy verification system based upon simulations of induced radioactivity and comparison with patient positron emission tomography (PET) scans.

Methods

A Monte Carlo algorithm was integrated into an in-house built treatment, information, management, and planning system (TIMPS®) to calculate distributions of positron emitters induced by ion beams. These distributions are processed to simulate PET images taking into account positron diffusion, radioactive decay, biological washout, and detector blurring. Additional tools were developed to register simulated PET images with planning CT images and perform comparisons of measured and simulated PET images.

Results

Production cross-sections were generated for various isotopes and materials. Treatment plans for several different body sites were used to verify the functioning and utility of the new tools for both proton and carbon ion beams.

Conclusions

Several tools have been developed to simulate PET scans of patients irradiated with ion beams and compare the simulated images to measurements. After commissioning and implementation into the clinic, the appropriate sizes for margins that account for uncertainties may be investigated.

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来源期刊

Radiation Medicine and Protection Health Professions-Emergency Medical Services

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

103 days