基于内部动态胸腔幻影的调强质子治疗(IMPT)技术剂量规划评价

IF 0.6 Q4 NUCLEAR SCIENCE & TECHNOLOGY
V. Vernanda, A. Azzi, S. A. Pawiro
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引用次数: 0

摘要

调强放射治疗(IMRT)技术的缺点之一是健康组织的吸收剂量相对较高。质子束的特性可以弥补这些缺点。质子束的布拉格峰特性只允许对靶器官施加高剂量的辐射。非小细胞肺癌(NSCLC)病例位于许多重要器官附近,因此超过一定限度的辐射剂量会对这些器官产生重大影响。质子是一种重粒子,它与组织的非均质性表现出不同于光子的相互作用模式。本研究旨在确定强度调制质子治疗(IMPT)技术在NSCLC病例中的质子束计划剂量分布,并比较其与IMRT技术的有效性。采用TPS Eclipse对水模和内部胸腔动态模进行治疗计划。使用的水影规划参数为0°的一个场和45°、135°和225°的三个场。在本研究中,采用单场、综合场和多场技术对内部胸腔动态假体进行修复。通过计算每个治疗计划的符合性指数(CI)、均匀性指数(HI)和梯度指数(GI)参数进行评估。因此,在IMPT和IMRT计划之间显示出CI和HI值的一点差异。IMPT规划的GI值在4.15-4.53之间,IMRT的GI值为7.89。平面剂量分布的直方图结果显示,IMPT治疗计划提供的脱靶器官剂量比IMRT计划少。还对五个感兴趣领域和四个桨位靶器官的IMPT治疗计划进行了评估。然后将评估结果与IMRT测量数据进行比较。结果,靶器官的点剂量值没有显著差异。然而,IMPT技术在四个桨位的吸收剂量几乎为零,与IMRT技术相比有很大差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dose Planning Evaluation of Intensity-Modulated Proton Therapy (IMPT) Technique Based on In-House Dynamic Thorax Phantom
One of the drawbacks of the Intensity Modulated Radiation Therapy (IMRT) technique is that the absorbed dose in healthy tissue is relatively high. Proton beam has characteristics that can compensate for these drawbacks. The Bragg peak characteristic of a proton beam allows the administration of high radiation doses to the target organ only. Non-Small Cell Lung Cancer (NSCLC) cases are located in the vicinity of many vital organs, so radiation doses that exceed a certain limit will have a significant impact on these organs. Proton is a heavy particle that exhibits interaction patterns with tissue heterogeneity that differ from that of photon. This study aims to determine the distribution of proton beam planning doses in the NSCLC cases with the Intensity Modulated Proton Therapy (IMPT) technique and compare its effectiveness with the IMRT technique. Treatment planning was done by using TPS Eclipse on the water phantom and on the in-house thorax dynamic phantom. The water phantom planning parameters used are one field at 0° and three fields at 45°, 135°, and 225°. In this study, a single, sum, and multiple field techniques on the in-house thorax dynamic phantom were used. The evaluation was performed by calculating Conformity Index (CI), Homogeneity Index (HI), and Gradient Index (GI) parameters for each treatment planning. As a result, a bit of difference in the CI the HI values are shown between IMPT and IMRT planning. The GI values of IMPT planning are in the range between 4.15-4.53, while the GI value of IMRT is 7.89. The histogram results of the planar dose distribution show that the IMPT treatment planning provides fewer off-target organ doses than the IMRT planning. Evaluation was also carried out on the    IMPT treatment planning of target organs in five areas of interest and four OAR positions. The evaluation results were then compared with the IMRT measurement data. As a result, the value of the point doses at the target organ      did not differ significantly. However, the absorbed dose with the IMPT technique at four OAR positions is nearly zero, which had a large difference compared to the IMRT technique.
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来源期刊
Atom Indonesia
Atom Indonesia NUCLEAR SCIENCE & TECHNOLOGY-
CiteScore
1.00
自引率
0.00%
发文量
20
审稿时长
16 weeks
期刊介绍: The focus of Atom Indonesia is research and development in nuclear science and technology. The scope of this journal covers experimental and analytical research in nuclear science and technology. The topics include nuclear physics, reactor physics, radioactive waste, fuel element, radioisotopes, radiopharmacy, radiation, and neutron scattering, as well as their utilization in agriculture, industry, health, environment, energy, material science and technology, and related fields.
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