Investigating Slit-Collimator-Produced Carbon Ion Minibeams with High-Resolution CMOS Sensors

Q3 Physics and Astronomy
L. Volz, C. Reidel, M. Durante, Y. Prezado, C. Schuy, U. Weber, C. Graeff
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引用次数: 1

Abstract

Particle minibeam therapy has demonstrated the potential for better healthy tissue sparing due to spatial fractionation of the delivered dose. Especially for heavy ions, the spatial fractionation could enhance the already favorable differential biological effectiveness at the target and the entrance region. Moreover, spatial fractionation could even be a viable option for bringing ions heavier than carbon back into patient application. To understand the effect of minibeam therapy, however, requires careful conduction of pre-clinical experiments, for which precise knowledge of the minibeam characteristics is crucial. This work introduces the use of high-spatial-resolution CMOS sensors to characterize collimator-produced carbon ion minibeams in terms of lateral fluence distribution, secondary fragments, track-averaged linear energy transfer distribution, and collimator alignment. Additional simulations were performed to further analyze the parameter space of the carbon ion minibeams in terms of beam characteristics, collimator positioning, and collimator manufacturing accuracy. Finally, a new concept for reducing the neutron dose to the patient by means of an additional neutron shield added to the collimator setup is proposed and validated in simulation. The carbon ion minibeam collimator characterized in this work is used in ongoing pre-clinical experiments on heavy ion minibeam therapy at the GSI.
用高分辨率CMOS传感器研究狭缝准直器产生的碳离子微束
粒子微束治疗已经证明,由于所给剂量的空间分割,有可能更好地保留健康组织。特别是对于重离子,空间分选可以增强靶区和入口区本已良好的差异生物效应。此外,空间分馏甚至可能是将比碳重的离子带回患者应用的可行选择。然而,要了解微束治疗的效果,需要仔细进行临床前实验,因此精确了解微束特性至关重要。这项工作介绍了使用高空间分辨率CMOS传感器来表征准直器产生的碳离子微束的横向通量分布、二次碎片、轨迹平均线性能量传递分布和准直器对准。通过仿真进一步分析了碳离子微光束在光束特性、准直器定位和准直器制造精度等方面的参数空间。最后,提出了一种通过在准直器装置中增加一个额外的中子屏蔽来减少病人中子剂量的新概念,并在仿真中进行了验证。在这项工作中表征的碳离子微束准直器用于GSI正在进行的重离子微束治疗的临床前实验。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Instruments
Instruments Physics and Astronomy-Instrumentation
CiteScore
2.60
自引率
0.00%
发文量
70
审稿时长
11 weeks
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