Experimental Measurement of Secondary Particle Count for Real-Time Proton Range Verification

IF 4.6 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Chuan Huang;Zhengguo Hu;Wei Lv;Yucong Chen;Xiuling Zhang;Zhiguo Xu;Faming Luo;Xinle Lang;Zulong Zhao;Ruishi Mao;Yongzhi Yin;Zhongming Wang;Di Wang;Guoqing Xiao
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Abstract

The real-time positioning of the particle beam range during treatment is a critical technology for improving the quality of the patient treatment. This article presents a scheme for the real-time proton range verification, and an experimental prototype is built at the Xi’an proton application facility (XiPAF) terminal. The experiment utilized a 150 MeV passive proton beam delivery mode to bombard the polymethyl methacrylate (PMMA) target for the real-time proton range verification. This scheme utilizes the secondary particle counts generated per monitor unit (MU) of primary particles and does not require identification of the secondary particle species, only its deposition energy in the cerium bromide (CeBr3) scintillator module exceeding 73.24 keV. The accuracy of range verification was evaluated at various acquisition periods by establishing the relationship between the secondary particle counts generated per MU of primary particles and the proton range. The range verification accuracy after one spill ( $\sim ~1.67\times 10$ 9 protons) delivery was measured at $0.01~\pm ~0$ .29 mm. The accuracy of range verification within milliseconds is mainly affected by the statistical fluctuations in the secondary particle counts caused by the accumulation of activation products. Under constrained conditions, the range verification accuracy was measured at $0.16~\pm ~0$ .69 mm within 110 ms acquisition time and $0.16~\pm ~0$ .94 mm within 55 ms acquisition time. The experimental results confirm the feasibility of the scheme for the real-time range verification practice. The study hopes to provide a new reference scheme for reducing the impact of range uncertainty on the patient treatment quality.
用于实时质子范围验证的二次粒子计数实验测量
治疗过程中粒子束射程的实时定位是提高患者治疗质量的关键技术。本文提出了一种质子射程实时验证方案,并在西安质子应用设施(XiPAF)终端搭建了实验样机。实验采用 150 MeV 被动质子束输送模式轰击聚甲基丙烯酸甲酯(PMMA)靶,进行实时质子射程验证。该方案利用每监测单位(MU)一次粒子产生的二次粒子计数,无需识别二次粒子种类,只需识别其在超过 73.24 keV 的溴化铈(CeBr3)闪烁器模块中的沉积能量。通过确定每 MU 一次粒子产生的二次粒子计数与质子量程之间的关系,评估了不同采集周期下量程验证的准确性。一次质子溢出(1.67乘以10的9次方倍)后的量程验证精度为0.01~/pm~0.29毫米。毫秒内的量程验证精度主要受活化产物积累引起的二次粒子数统计波动的影响。在受限条件下,在 110 毫秒采集时间内测得的量程验证精度为 0.16~pm ~0$ .69 毫米,在 55 毫秒采集时间内测得的量程验证精度为 0.16~pm ~0$ .94 毫米。实验结果证实了该方案在实时测距验证实践中的可行性。该研究希望为降低测距不确定性对患者治疗质量的影响提供一种新的参考方案。
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来源期刊
IEEE Transactions on Radiation and Plasma Medical Sciences
IEEE Transactions on Radiation and Plasma Medical Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
8.00
自引率
18.20%
发文量
109
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