Study on Quality Diagnosis and Dose Measurement Accuracy Evaluation of 100 MeV Proton Beam

Qiaojuan WANG; Li SUI; Yihao GONG; Fuquan KONG; Jiancheng LIU; Yanwen ZHANG; Jinhua HAN

doi:10.11804/NuclPhysRev.37.2020029

Volume 37 Issue 4

Dec. 2020

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Article Navigation > Nuclear Physics Review > 2020 > 37(4): 893-900

Qiaojuan WANG, Li SUI, Yihao GONG, Fuquan KONG, Jiancheng LIU, Yanwen ZHANG, Jinhua HAN. Study on Quality Diagnosis and Dose Measurement Accuracy Evaluation of 100 MeV Proton Beam[J]. Nuclear Physics Review, 2020, 37(4): 893-900. doi: 10.11804/NuclPhysRev.37.2020029

Citation:

Qiaojuan WANG, Li SUI, Yihao GONG, Fuquan KONG, Jiancheng LIU, Yanwen ZHANG, Jinhua HAN. Study on Quality Diagnosis and Dose Measurement Accuracy Evaluation of 100 MeV Proton Beam[J]. Nuclear Physics Review, 2020, 37(4): 893-900. doi: 10.11804/NuclPhysRev.37.2020029

Study on Quality Diagnosis and Dose Measurement Accuracy Evaluation of 100 MeV Proton Beam

doi: 10.11804/NuclPhysRev.37.2020029

Qiaojuan WANG^{1, 2
,},
Li SUI^{1, 2
,
,},
Yihao GONG^{1, 2},
Fuquan KONG^{1, 2},
Jiancheng LIU^{1, 2},
Yanwen ZHANG^{1, 2},
Jinhua HAN^{1, 2}

1.
China Institute of Atomic Energy, Beijing 102413, China
2.
National Innovation Center of Radiation Application, Beijing 102413, China

Funds: National Natural Science Foundation of China(11575293); Continuous Basic Scientific Research Project(WDJC-2019-11); China Institute of Atomic Energy Dean Foundation(11YZ201911)

More Information

Corresponding author: E-mail: lisui@ciae.ac.cn.
Received Date: 2020-05-11
Rev Recd Date: 2020-07-22

Available Online: 2021-11-22

Publish Date: 2020-12-20

Abstract

The biological effect of proton radiation is an important foundation of space radiobiology and proton radiotherapy, which can provide scientific basis for the estimation of risk to crews in space radiation and optimization design of proton therapy. It is necessary to establish irradiation technology for biological samples by accelerator. The protons with middle-energy generated by 100 MeV cyclotron established recently by the China Institute of Atomic Energy have the highest energy in China, particularly suitable for the research of space radiobiology and proton therapy. In present study, the methods of proton beam diagnosis and dose measurement were established. The beam quality, such as the size and uniformity of irradiation field, and the accuracy of dose measurement system, was analyzed and evaluated by means of in-beam and off-line methods. The results show that LiF(Mg, Ti) thermo-luminescence detector with good response to photon dose also has good dose response to 90 MeV protons, which can be used to evaluate the accuracy of dose of protons with middle-energy. The uniformity of 100 MeV proton beam is better than 90% in 5.0 cm×5.0 cm irradiation field. The accuracy of in-beam dose measurement system is better than 93%. The beam quality and dose measurement conditions of proton basically meet the requirements of radiobiology, which can provide reliable guarantee for the research of radiobiological effects.
- middle-energy proton,
- beam quality diagnosis,
- accuracy of dose measurement,
- dose film,
- thermo-luminescence detector,
- proton therapy,
- space radiobiolog

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1. 引言

随着人类对太空的不断探索，空间站任务、载人登月、深空探测的不断发展，人类驻留空间的时间逐渐延长，空间复杂的辐射环境已成为制约载人深空探测发展的重要因素之一^[1]。质子是空间辐射的主要成分：98%的银河宇宙射线是由质子和重离子组成，其中质子占87%^[2-3]；太阳粒子事件中，质子占90%~95%^[2-3]。当前，我国即将进入空间站时代，开展质子辐射生物学效应研究对保障宇航员的生命安全和航天任务的顺利完成具有重要意义。此外，近年来，全球癌症的发病率呈现持续升高的总体趋势，癌症已成为全球性的公共卫生问题。据美国癌症学会发表的《2018年全球癌症统计数据》报告^[4]显示：2018年全球将有大约1 810万癌症新发病例和960 万癌症死亡病例；其中我国新发病率占23.7%，死亡率占30%，居全球第一^[5]。普通放疗是治疗肿瘤的重要手段之一^[6]，已取得了明显成效，但由于X或γ射线是以指数形式衰减，射程无法控制，所以对浅层组织和肿瘤后的正常组织损伤较大，而且由于其生物学效应低，很容易使肿瘤出现放射抗拒而使治疗失败。而质子束由于深度剂量分布在接近射程末端时具有Bragg峰的特点，在此处的传能线密度(Linear Energy Transfer, LET)高，能量沉积密集，局部剂量大，可有效增加对肿瘤的杀伤效果及减少对周围正常组织的损伤，已成为国际上治疗肿瘤的重要物理疗法之一^[7-8]。因此，开展质子辐射生物学基础研究对于其临床应用的优化意义重大。

而不论是空间辐射环境危害的预估和防护对策研究，还是质子治癌的基础性和先导性研究，都需要依托加速器辐照装置建立适宜于生物学效应研究的辐照技术，其中束流品质诊断和剂量测量技术是重要研究内容之一。例如，法国Institut de Physique Nucléaire de Lyon(IPNL)利用离子注入型钝化硅半导体(Passivated Implanted Planar Silicon，PIPS)探测器、闪烁纤维探测器和剂量胶片对质子辐照装置Radiograaff的生物研究终端引出的质子束流品质进行诊断^[9]；美国空间辐射实验室(NASA Space Radiation Laboratory，NSRL)利用透射电离室、标准电离室和塑料闪烁体^[10-11]，美国Lawrence Berkeley国家实验室^[12]利用法拉第筒(Faraday Cylinder, FC)、透射电离室和塑料闪烁体探测器，加拿大TRIUMF大学^[13]利用法拉第筒、二次电子发射监督器(Secondary Electron Emission Monitor, SEEM)和塑料闪烁体探测器对引出的束流进行了诊断。在临床放疗中，对于治疗束的体内射程、平均剂量率、照射野尺寸和均匀度等物理学特性有着严格的规定，利用最新的GAFCHROMIC^TMEBT系列胶片分析照射野剂量分布的报道很多，如：Sorriaux 等^[14]利用EBT3对放疗中的光子、电子及质子束的均匀性等特性进行了研究； Krzempek等^[15]利用EBT对质子治疗的剂量分布进行了研究；王志斌等^[16]利用EBT3胶片对医科达Leksell Gamma Knife Perfexion^TM 头部伽马刀辐射场的半影、焦点剂量、照射野大小等进行了研究。在空间辐射剂量测量中，需要利用多种探测方法、多种探测仪器，相互补充、相互验证才能给出更可靠的空间辐射剂量学数据，热释光探测器(Thermo-Luminescent Detector，TLD)是主要使用的被动探测器之一，例如Matroshka实验装置是目前关于应用TLD进行空间探测的最大拟人化人体躯干研究设施，2004年，在国际空间站上利用装有数千个TLD的Matroshka直立人体模型对宇航员舱内活动和出舱活动(Extra-Vehicular Activity, EVA)进行了模拟，获得了不同深度不同器官的辐射剂量分布。TLD测量法已被证明是空间辐射剂量学研究的优选方法之一，是测量累积剂量首选的探测器之一^[17-18]。

目前，国内在质子束流品质诊断和剂量测量技术方面，主要是中国原子能科学研究院和北京大学依托串列加速器开展的低能质子相关研究并已应用于辐射生物学研究^[19-20]中，对于中能质子，由于之前一直缺乏能量合适的加速器设备和实验终端，尚未开展相关应用研究。2016年底，基于中国原子能科学研究院100 MeV强流质子回旋加速器的单粒子效应实验终端建设完成，为中能质子辐照技术和辐射生物学效应提供了研究平台。其引出的质子能量为30~100 MeV，能谱范围宽，十分适合用于模拟空间站辐射环境，同时也特别适用于浅层肿瘤(如皮肤癌、口腔癌、眼癌和鼻咽癌等)治疗相关研究，以及与治癌相关的辐射生物学基础研究。本研究以此为出发点，利用荧光屏、SEEM-FC在线测量方法，剂量胶片、热释光探测器离线分析方法和理论模拟计算，对单粒子效应实验终端引出的质子束流的物理特性，如照射野大小、束流均匀性，以及建立的SEEM-FC在线剂量测量系统的准确性进行分析和评估，探讨单粒子效应实验终端用于辐射生物学效应研究的适用性。

4. 结论

对光子剂量响应好的LiF(Mg,Ti)热释光探测器，对90 MeV质子同样具有良好的剂量响应关系，可作为中能质子剂量准确性评估的手段之一。基于100 MeV强流质子加速器单粒子实验终端建立的ZnS荧光屏和SEEM-FC在束测量技术，剂量胶片和TLD离线分析以及理论计算方法，可多方位诊断和评估所建终端的物理参数特性。加速器引出的100 MeV质子，经过双环双散射靶均匀化后，在5.0 cm×5.0 cm照射野范围内，均匀性好于90%，建立的SEEM-FC在线剂量测量系统准确性好于93%。单粒子实验终端引出的质子束流的照射野范围、均匀性及剂量监测准确性基本能满足生物样本的要求，可为质子辐射生物学效应研究提供良好的实验条件和数据可靠保障。

致谢　感谢中国原子能科学研究院回旋加速器设计中心100 MeV强流质子回旋加速器运行人员在照射实验中给予的帮助和支持；感谢国防科工委放射性计量一级站在标准⁶⁰Co γ射线照射实验中给予的帮助和支持，以及提供用于TLD测量的RGD-3B热释光读出仪。

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位置	FC计数/N	注量率/(particles/cm²/s)	平均注量率
束流中心	293.6	9.7×10⁶	9.7×10⁶
左上角	282.4	9.4×10⁶	标准差
右上角	290.9	9.6×10⁶	2.5×10⁵
左下角	301.7	10.0×10⁶	均匀性
右下角	299.2	9.9×10⁶	97.4%

区域	面积/cm²	均值±SD	均匀性
C2, I8(7×7)	5.2×5.2	102.5±9.3	90.9%
D3, H7(5×5)	3.7×3.7	107.9±4.4	95.9%
E4, G6(3×3)	2.2×2.2	110.8±2.5	97.6%

剂量/Gy	γ射线均值±SD	质子均值±SD	校正剂量/Gy	偏差/%
0.5	49.1±3.1	50.9±3.5	5.2×10^–1	4.0
1	96.5±6.1	106.2±6.7	1.1	10.0
2	194.3±8.5	216.6±9.8	2.2	10.0
4	389.5±6.8	419.6±4.5	4.3	7.5

剂量/Gy	γ射线/Gy	中子/Gy	共计剂量/Gy	γ偏差/%	共计偏差/%
0.5	2.6×10^–4	90.2×10^–4	92.9×10^–4	0.5×10^–1	1.9
1	5.3×10^–4	180.5×10^–4	185.8×10^–4	0.5×10^–1	1.9
2	10.5×10^–4	361.0×10^–4	371.5×10^–4	0.5×10^–1	1.9
4	21.1×10^–4	722.0×10^–4	743.1×10^–4	0.5×10^–1	1.9
8	42.1×10^–4	1444.0×10^–4	1486.1×10^–4	0.5×10^–1	1.9

Study on Quality Diagnosis and Dose Measurement Accuracy Evaluation of 100 MeV Proton Beam

doi: 10.11804/NuclPhysRev.37.2020029

Abstract

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通讯作者: 陈斌, bchen63@163.com

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