[Simulation model of tumor-treating fields].

Q4 Medicine
Liping Qin, Xu Xie, Minmin Wang, Mingwei Ma, Yun Pan, Guangdi Chen, Shaomin Zhang
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引用次数: 0

Abstract

Tumor-treating fields (TTFields) is a novel treatment modality for malignant solid tumors, often employing electric field simulations to analyze the distribution of electric fields on the tumor under different parameters of TTFields. Due to the present difficulties and high costs associated with reproducing or implementing the simulation model construction techniques, this study used readily available open-source software tools to construct a highly accurate, easily implementable finite element simulation model for TTFields. The accuracy of the model is at a level of 1 mm 3. Using this simulation model, the study carried out analyses of different factors, such as tissue electrical parameters and electrode configurations. The results show that factors influncing the distribution of the internal electric field of the tumor include changes in scalp and skull conductivity (with a maximum variation of 21.0% in the treatment field of the tumor), changes in tumor conductivity (with a maximum variation of 157.8% in the treatment field of the tumor), and different electrode positions and combinations (with a maximum variation of 74.2% in the treatment field of the tumor). In summary, the results of this study validate the feasibility and effectiveness of the proposed modeling method, which can provide an important reference for future simulation analyses of TTFields and clinical applications.

[肿瘤治疗场模拟模型]。
肿瘤治疗场(TTFields)是一种新型的恶性实体肿瘤治疗模式,通常采用电场模拟来分析不同参数的TTFields下肿瘤上的电场分布。由于目前复制或实施仿真模型构建技术的难度大、成本高,本研究利用现成的开源软件工具构建了一个高精度、易实施的 TTFields 有限元仿真模型。利用该仿真模型,研究人员对组织电参数和电极配置等不同因素进行了分析。结果表明,影响肿瘤内部电场分布的因素包括头皮和头骨电导率的变化(在肿瘤治疗场中最大变化为 21.0%)、肿瘤电导率的变化(在肿瘤治疗场中最大变化为 157.8%)以及不同电极位置和组合(在肿瘤治疗场中最大变化为 74.2%)。总之,本研究的结果验证了所提出的建模方法的可行性和有效性,可为今后 TTFields 的模拟分析和临床应用提供重要参考。
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
生物医学工程学杂志
生物医学工程学杂志 Medicine-Medicine (all)
CiteScore
0.80
自引率
0.00%
发文量
4868
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