Anthropomorphic Brain Models Based on Magnetic Resonance Imaging

Digital Transformation Pub Date : 2022-09-02 DOI:10.35596/2522-9613-2022-28-2-61-69

V. Kabachek, N. S. Davydova, M. Mezhennaya, M. Davydov

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Abstract

The article is devoted to the creation of a method for generating anthropomorphic brain models based on magnetic resonance imaging. The selection of the magnetic field amplitude for transcranial magnetic stimulation (TMS) is carried out through modeling using the finite element method (FEM). These FEM models graphically demonstrate information on the distribution of the magnetic field and, therefore, on the occurring neurophysiological and behavioral changes based on the dose of the TMS, the specific resistance of the head tissue and its anatomy. Thus, these models are an integral tool used to design, configure, and program TMS devices, as well as to study parameters such as magnetic field strength and tension. A distinctive aspect of this work is the quality of the resulting head models. When creating the calculated FEM models, an MRI image of the head was used to perform segmentation in the FreeSurfer environment. Next, the image was converted in the Matlab environment. After the assembly of the head model in COMSOL Multiphysics, the TMS was simulated. The results of the transformations is a head model made in the form of a three-dimensional grid, which is suitable for modeling. The obtained data can be used to personalize the TMS method in medicine.

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基于磁共振成像的拟人化脑模型

本文致力于创造一种基于磁共振成像生成拟人化脑模型的方法。采用有限元方法对经颅磁刺激(TMS)的磁场幅值进行了建模，确定了磁场幅值的选择。这些有限元模型以图形方式展示了磁场分布的信息，因此，也展示了基于经颅磁刺激剂量、头部组织的特定电阻及其解剖结构所发生的神经生理和行为变化。因此，这些模型是用于设计、配置和编程TMS设备以及研究磁场强度和张力等参数的不可或缺的工具。这项工作的一个独特方面是产生的头部模型的质量。在创建计算的FEM模型时，使用头部的MRI图像在FreeSurfer环境中进行分割。接下来，在Matlab环境下对图像进行转换。将头部模型在COMSOL Multiphysics中组装完成后，对TMS进行仿真。转换的结果是一个三维网格形式的头部模型，适合建模。所获得的数据可用于医学中TMS方法的个性化。

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

Digital Transformation

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