一种新提出的表面近距离放射治疗模具的剂量学评估与蒙特卡罗模拟
Dosimetric evaluation and Monte Carlo simulation of a new proposed surface brachytherapy mould.
作者信息
Salamat Fatemeh, Siavashpour Zahra, Sadeghi Mahdi, Jaberi Ramin, Gholami Somayeh
机构信息
Department of Medical Physics, School of Medicine, Iran University of Medicine Sciences, Tehran, Iran.
Department of Radiation Oncology, Shohada Tajrish Educational Hospital, Medical School, Shahid Beheshti University of Medical Sciences, Tehran, Iran.
出版信息
J Contemp Brachytherapy. 2024 Aug;16(4):279-288. doi: 10.5114/jcb.2024.143609. Epub 2024 Sep 16.
PURPOSE
The aim of this study was to develop a new in-house low-cost surface mould, and to evaluate its performance and dosimetric properties for high-dose-rate (HDR) cobalt-60 (Co) brachytherapy.
MATERIAL AND METHODS
A water-equivalent surface mould was developed using medical silicone. Mould performance and dosimetry characteristics were evaluated with Monte Carlo N-particle (MCNP2.6) simulation, Gafchromic™ EBT3 film measurements, and treatment planning system (TPS) output. Three sample moulds with different thicknesses (i.e., 0.5 cm, 1 cm, and 1.5 cm) were constructed, and a phantom study was performed. Treatment plans prescribing 3 Gy to 0.5 cm under pseudo-skin were designed, and film dosimetry was completed. TPS dose distributions were compared using Monte Carlo (MC) simulation and film dosimetry.
RESULTS
Good consistency was observed between TPS results and film dosimetry at the prescribed depth of 0.5 cm, with mean differences of 0.70%, 0.40%, and 0.19% for mould thicknesses of 0.5 cm, 1 cm, and 1.5 cm, respectively. However, higher discrepancies were found at the phantom surface with 1.00%, 0.80%, and 0.56% dose differences for the considered mould thicknesses, respectively. These increased differences could be due to a higher dose gradient at the phantom surface, and a greater impact of uncertainties on the obtained results in this part. Moreover, mean differences between the results obtained from MC simulations and output of TPS at the prescribed depth of 0.5 cm were 0.73%, 0.60%, and 0.08% for mold thicknesses of 0.5 cm, 1 cm, and 1.5 cm, respectively. Higher variations were observed between TPS and MC at the phantom surface with 1.30%, 0.70%, and 0.13% dose differences for the considered mould thicknesses, respectively.
CONCLUSIONS
The developed surface mould demonstrated water equivalence at Co energies, and was consistent with TPS calculations at routine treatment depths. Its effectiveness in non-melanoma skin cancer (NMSC) lesion treatment is highlighted. However, due to mould attenuation, TG-43-based TPS overestimated the dose delivered using this mould, especially at pseudo-skin surface, emphasizing the necessity for a model-based TPS algorithm.
目的
本研究的目的是开发一种新型的低成本内部表面模具,并评估其在高剂量率(HDR)钴 - 60(Co)近距离放射治疗中的性能和剂量学特性。
材料与方法
使用医用硅胶开发了一种水等效表面模具。通过蒙特卡罗N粒子(MCNP2.6)模拟、Gafchromic™ EBT3胶片测量和治疗计划系统(TPS)输出评估模具性能和剂量学特征。构建了三个不同厚度(即0.5厘米、1厘米和1.5厘米)的样品模具,并进行了体模研究。设计了在假皮肤下0.5厘米处给予3 Gy的治疗计划,并完成了胶片剂量学测量。使用蒙特卡罗(MC)模拟和胶片剂量学比较TPS剂量分布。
结果
在规定深度0.5厘米处,TPS结果与胶片剂量学之间观察到良好的一致性,对于0.5厘米、1厘米和1.5厘米厚度的模具,平均差异分别为0.70%、0.40%和0.19%。然而,在体模表面发现了更高的差异,对于所考虑的模具厚度,剂量差异分别为1.00%、0.80%和0.56%。这些增加的差异可能是由于体模表面更高的剂量梯度以及该部分不确定性对所得结果的更大影响。此外,在规定深度0.5厘米处,MC模拟结果与TPS输出之间的平均差异对于0.5厘米、1厘米和1.5厘米厚度的模具分别为0.73%、0.60%和0.08%。在体模表面,TPS和MC之间观察到更高的变化,对于所考虑的模具厚度,剂量差异分别为1.30%、0.70%和0.13%。
结论
所开发的表面模具在钴能量下表现出水等效性,并且在常规治疗深度与TPS计算结果一致。突出了其在非黑色素瘤皮肤癌(NMSC)病变治疗中的有效性。然而,由于模具衰减,基于TG - 43的TPS高估了使用该模具递送的剂量,特别是在假皮肤表面,强调了基于模型的TPS算法的必要性。
Zotero 插件