实现了用于计算BEBIG Co-60高剂量率近距离放疗源周围剂量分布的Sievert积分

IF 0.7 Q4 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Polish Journal of Medical Physics and Engineering Pub Date : 2022-05-28 DOI:10.2478/pjmpe-2022-0011

C. Dumenya, F. Hasford, S. Tagoe, E. Sasu, M. Pokoo-Aikins, B. B. Asamanyuah, J. Amuasi

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引用次数: 2

摘要

摘要简介:在放射治疗中，计算机治疗计划系统(TPS)用于进行治疗计划以估计患者体内的剂量分布。为了简化剂量计算，采用了数学算法。TG43形式被广泛应用于近距离治疗。在临床实践中实施特定剂量计算算法之前，必须承认该算法的局限性和不确定性。关于这一点，将算法的输出与使用简单源放置几何形状的测量或剂量计算方法进行比较。手动剂量计算方法必须是可靠的、直接的，并且没有复杂性，以减少在剂量计算过程中犯错误的可能性。对于近距离放射治疗源，已经提出了许多人工剂量计算方法，但需要确定其可靠性。材料和方法:考虑到这一点，采用Sievert积分剂量计算方法，验证了用于近距离治疗计划的HDRplus治疗计划系统的输出，该系统使用TG43公式计算BEBIG Co-60源周围的剂量分布。使用从涂抹器库中选择的通用涂抹器LLA1200-20，使用TPS创建简单的源放置几何形状，并使用TPS和Sievert积分计算距离涂抹器各等距点的剂量。本文概述了提高西弗特积分法功效的各种步骤。结果:在0°< θ < 70°和0°< θ < 48°范围内，沿源垂直平分线角度的剂量偏差分别为0.03 ~ 10.51%(平均3.13%)和0.03 ~ 5.63%(平均2.55%)。结论:Sievert积分在θ≥60°角处失效，因此，忽略大角度，Sievert积分将是一种高效、有效和有效的工具，可用于Co-60源HDRplus TPS的质量控制。

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Implementation of the Sievert integral for the calculation of dose distribution around the BEBIG Co-60 high dose rate brachytherapy source

Abstract Introduction: In radiotherapy, a computerized treatment planning system (TPS) is used for performing treatment planning to estimate the dose distribution within a patient. To simplify the dose calculation, mathematical algorithms are employed. TG43 formalism is widely used for brachytherapy. Before the implementation of a particular dose calculation algorithm in clinical practice, it is imperative to acknowledge the limitations and uncertainties associated with the algorithm. Regarding this, outputs of the algorithm are compared to measurements or dose calculation approaches using simple source placement geometries. The manual dose calculation method has to be robust, straightforward, and devoid of complexities to reduce the likelihood of committing errors in the dose calculation process. A lot of manual dose calculation approaches have been proposed for Brachytherapy sources, but one needs to ascertain their reliability. Material and methods: Considering this, the output of an HDRplus treatment planning system dedicated to brachytherapy treatment planning and using the TG43 formalism to calculate the dose distribution around a BEBIG Co-60 source was validated with Sievert integral dose calculation approach. Simple source placement geometries were created with the TPS using the universal applicator, LLA1200-20, selected from the applicator library, and doses at various equidistant points from the applicator calculated with the TPS and the Sievert integral. Various steps to enhance the efficacy of the Sievert integral approach have been outlined. Results: The doses compared favourably well with deviations ranging from 0.03 – 10.51% (mean of 3.13%), and 0.03 – 5.63% (mean of 2.55%) for angles along the perpendicular bisector of the source, ranging from 0° < θ < 70° and 0° < θ < 48°, respectively. Conclusions: The Sievert integral breaks down at angles: θ ≥ 60°, and therefore, neglecting large angles, the Sievert integral would be an efficient, effective, and valid tool for quality control of the HDRplus TPS for the Co-60 source.

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来源期刊

Polish Journal of Medical Physics and Engineering RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： Polish Journal of Medical Physics and Engineering (PJMPE) (Online ISSN: 1898-0309; Print ISSN: 1425-4689) is an official publication of the Polish Society of Medical Physics. It is a peer-reviewed, open access scientific journal with no publication fees. The issues are published quarterly online. The Journal publishes original contribution in medical physics and biomedical engineering.