Collimation principles of a hollow X-ray microbeam for high-contrast cytoplasm irradiation.

IF 1.9 4区 医学 Q2 BIOLOGY
Qinqin Cheng, Ruifeng Zhao, Xiaowa Wang, Xufei Wang
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Abstract

A Monte Carlo simulation was used to assess the performance of a collimated hollow X-ray microbeam for subcellular cytoplasm irradiation. A high-Z coaxial collimation structure with an inner core for nucleus shielding was investigated. Two key performances, the extraction efficiency (cytoplasm dose per unit incident fluence) and the dose contrast (cytoplasm-to-nucleus dose ratio), were evaluated regarding the influences of the material, geometry and physical arrangements of the collimator, target dish and incident beam source. Simulation results demonstrate that a gold coaxial structure with a practical collimation geometry of a 1-mm length, 10-μm inner diameter and 200-μm outer diameter, with the top exit closely attached (with a minimized air gap) to the bottom of a cell dish with a 3-μm thick Mylar film is recommended for cytoplasm irradiation of adherent mammalian cells. For a synchrotron source in the energy range < 10 keV, a dose contrast of approximately 100 can be achieved. For a bremsstrahlung source <30-kV tube voltage, a dose contrast of approximately 50-100 can still be achieved. General principles are summarized with further explanations of the performance of the hollow X-ray microbeam.

用于高对比度细胞质照射的空心 X 射线微束的准直原理。
利用蒙特卡罗模拟评估了用于亚细胞质照射的准直空心 X 射线微束的性能。研究了一种高 Z 同轴准直结构,其内核用于屏蔽细胞核。针对准直器、靶盘和入射束源的材料、几何形状和物理排列的影响,对提取效率(单位入射流量的细胞质剂量)和剂量对比度(细胞质与细胞核的剂量比)这两个关键性能进行了评估。模拟结果表明,在对粘附的哺乳动物细胞进行细胞质辐照时,推荐使用长度为 1 毫米、内径为 10 微米、外径为 200 微米的实用准直几何形状的金同轴结构,其顶部出口与铺有 3 微米厚 Mylar 薄膜的细胞皿底部紧密相连(气隙最小)。对于能量范围为
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来源期刊
CiteScore
3.60
自引率
5.00%
发文量
86
审稿时长
4-8 weeks
期刊介绍: The Journal of Radiation Research (JRR) is an official journal of The Japanese Radiation Research Society (JRRS), and the Japanese Society for Radiation Oncology (JASTRO). Since its launch in 1960 as the official journal of the JRRS, the journal has published scientific articles in radiation science in biology, chemistry, physics, epidemiology, and environmental sciences. JRR broadened its scope to include oncology in 2009, when JASTRO partnered with the JRRS to publish the journal. Articles considered fall into two broad categories: Oncology & Medicine - including all aspects of research with patients that impacts on the treatment of cancer using radiation. Papers which cover related radiation therapies, radiation dosimetry, and those describing the basis for treatment methods including techniques, are also welcomed. Clinical case reports are not acceptable. Radiation Research - basic science studies of radiation effects on livings in the area of physics, chemistry, biology, epidemiology and environmental sciences. Please be advised that JRR does not accept any papers of pure physics or chemistry. The journal is bimonthly, and is edited and published by the JRR Editorial Committee.
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