Electric Field Regression and Error Variance Estimation for Transcranial Magnetic Stimulation using Deep Neural Networks

IF 0.8 Q4 ENGINEERING, BIOMEDICAL Advanced Biomedical Engineering Pub Date : 2023-01-01 DOI:10.14326/abe.12.225
Toyohiro Maki, Tatsuya Yokota, Akimasa Hirata, Hidekata Hontani
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Abstract

Transcranial magnetic stimulation (TMS) is a widely used non-invasive neurostimulation technique in neuroscience and in the treatment of psychiatric disorders. By placing a TMS coil over a patient's head, neurons in the brain can be electromagnetically stimulated through the induction of an electric field (E-field). Accurate estimation of the E-field induced in a patient's head is crucial for determining the stimulated area of the brain. The electromagnetic simulation for E-field estimation involves two processes: the development of a volume conductor model (VCM) to determine the electrical conductivity at each position of the brain from a head magnetic resonance (MR) image, and the computation of the E-field on the VCM. Currently, neither of these processes can be performed in real-time. Achieving real-time estimation would greatly assist in determining the appropriate coil position and direction to stimulate the target regions in the patient's brain. In recent years, several methods utilizing deep neural networks (DNNs) have been proposed to estimate E-fields from MR images in real-time. These methods construct a regressor of the E-field using a set of simulated E-fields as training data to estimate the E-field. However, the reliability of these regressors in clinical applications could be improved by incorporating uncertainty estimation of the regressed variables, although this has not been reported. In this study, we enhanced the accuracy of E-field strength estimation by first regressing the E-field and then computing the norm of the E-field vectors, instead of directly regressing the E-field strength. In addition, we investigated the statistical uncertainty of the regressed E-fields using DNN. It should be noted that the E-fields estimated by the regressors are random variables. To evaluate the uncertainty of this application, we employed MCDropout, a well-known Bayesian estimation method. The uncertainty of the regressed E-field was evaluated for each anatomical tissue of the brain, to examine the relationship between uncertainty and depth from the coil. The experimental results of this evaluation are presented quantitatively.
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基于深度神经网络的经颅磁刺激电场回归及误差方差估计
经颅磁刺激(TMS)是一种广泛应用于神经科学和精神疾病治疗的无创神经刺激技术。通过将TMS线圈置于患者头上,大脑中的神经元可以通过感应电场(E-field)受到电磁刺激。准确估计患者头部产生的电场对于确定大脑的受刺激区域至关重要。电磁场估计的电磁模拟包括两个过程:建立体积导体模型(VCM),根据头部磁共振(MR)图像确定大脑各位置的电导率,以及在VCM上计算电磁场。目前,这两个进程都不能实时执行。实现实时估计将极大地有助于确定适当的线圈位置和方向,以刺激患者大脑的目标区域。近年来,人们提出了几种利用深度神经网络(dnn)从磁共振图像中实时估计电磁场的方法。这些方法使用一组模拟的电场作为训练数据来构建电场的回归量来估计电场。然而,这些回归量在临床应用中的可靠性可以通过纳入回归变量的不确定性估计来提高,尽管这还没有报道。本文采用先对电场进行回归,再计算电场矢量范数的方法来提高电场强度估计的精度,而不是直接对电场强度进行回归。此外,我们还利用深度神经网络研究了回归电磁场的统计不确定性。需要注意的是,由回归量估计的e场是随机变量。为了评估该应用程序的不确定性,我们采用了MCDropout,一种著名的贝叶斯估计方法。对每个脑解剖组织的回归电磁场的不确定度进行评估,以检查不确定度与线圈深度之间的关系。定量地给出了该评价的实验结果。
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来源期刊
Advanced Biomedical Engineering
Advanced Biomedical Engineering ENGINEERING, BIOMEDICAL-
CiteScore
1.40
自引率
10.00%
发文量
15
审稿时长
15 weeks
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