How conductivity boundaries influence the electric field induced by transcranial magnetic stimulation in in vitro experiments

IF 7.6 1区 医学 Q1 CLINICAL NEUROLOGY Brain Stimulation Pub Date : 2024-09-01 DOI:10.1016/j.brs.2024.08.003
Padmavathi Sundaram , Chunling Dong , Sergey Makaroff , Yoshio Okada
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Abstract

Background

Although transcranial magnetic stimulation (TMS) has become a valuable method for non-invasive brain stimulation, the cellular basis of TMS activation of neurons is still not fully understood. In vitro preparations have been used to understand the biophysical mechanisms of TMS, but in many cases these studies have encountered substantial difficulties in activating neurons.

Objective/hypothesis

The hypothesis of this work is that conductivity boundaries can have large effects on the electric field in commonly used in vitro preparations. Our goal was to analyze the resulting difficulties in in vitro TMS using a simulation study, using a charge-based boundary element model.

Methods

We decomposed the total electric field into the sum of the primary electric field, which only depends on coil geometry and current, and the secondary electric field arising from conductivity boundaries, which strongly depends on tissue and chamber geometry. We investigated the effect of the conductivity boundaries on the electric field strength for a variety of in vitro experimental settings to determine the sources of difficulty.

Results

We showed that conductivity boundaries can have large effects on the electric field in in vitro preparations. Depending on the geometry of the air-saline and the saline-tissue interfaces, the secondary electric field can significantly enhance, or attenuate the primary electric field, resulting in a much stronger or weaker total electric field inside the tissue; we showed this using a realistic preparation. Submerged chambers are generally much more efficient than interface chambers since the secondary field due to the thin film of saline covering the tissue in the interface chamber opposes the primary field and significantly reduces the total field in the tissue placed in the interface chamber. The relative dimensions of the chamber and the TMS coil critically determine the total field; the popular setup with a large coil and a small chamber is particularly sub-optimal because the secondary field due to the air-chamber boundary opposes the primary field, thereby attenuating the total field. The form factor (length vs width) of the tissue in the direction of the induced field can be important since a relatively narrow tissue enhances the total field at the saline-tissue boundary.

Conclusions

Overall, we found that the total electric field in the tissue is higher in submerged chambers, higher if the chamber size is larger than the coil and if the shorter tissue dimension is in the direction of the electric field. Decomposing the total field into the primary and secondary fields is useful for designing in vitro experiments and interpreting the results.

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电导边界如何影响体外实验中经颅磁刺激所产生的电场
背景虽然经颅磁刺激(TMS)已成为一种有价值的非侵入性脑部刺激方法,但人们对 TMS 激活神经元的细胞基础仍不完全了解。体外制备已被用于了解 TMS 的生物物理机制,但在许多情况下,这些研究在激活神经元方面遇到了很大困难。我们将总电场分解为初级电场和次级电场之和,前者只取决于线圈的几何形状和电流,后者则主要取决于组织和腔室的几何形状。我们研究了各种体外实验环境下导电边界对电场强度的影响,以确定困难的来源。结果我们发现,导电边界会对体外制备中的电场产生很大影响。根据空气-盐水和盐水-组织界面的几何形状,次级电场可显著增强或减弱初级电场,从而导致组织内的总电场大大增强或减弱。浸没室通常比界面室有效得多,因为界面室中的组织上覆盖着一层生理盐水薄膜,这层薄膜所产生的次级电场会与初级电场对立,并显著降低放置在界面室中的组织内的总电场。腔室和 TMS 线圈的相对尺寸对总磁场起着至关重要的作用;大线圈小腔室的流行设置尤其不理想,因为空气-腔室边界产生的次级磁场会与主磁场对立,从而衰减总磁场。组织在诱导场方向上的形状系数(长度与宽度)可能很重要,因为相对较窄的组织会增强盐水-组织边界处的总场。结论总的来说,我们发现在浸没室中,组织中的总电场较高,如果浸没室的尺寸大于线圈,并且较短的组织尺寸位于电场方向上,则总电场较高。将总电场分解为初级电场和次级电场有助于设计体外实验和解释实验结果。
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来源期刊
Brain Stimulation
Brain Stimulation 医学-临床神经学
CiteScore
13.10
自引率
9.10%
发文量
256
审稿时长
72 days
期刊介绍: Brain Stimulation publishes on the entire field of brain stimulation, including noninvasive and invasive techniques and technologies that alter brain function through the use of electrical, magnetic, radiowave, or focally targeted pharmacologic stimulation. Brain Stimulation aims to be the premier journal for publication of original research in the field of neuromodulation. The journal includes: a) Original articles; b) Short Communications; c) Invited and original reviews; d) Technology and methodological perspectives (reviews of new devices, description of new methods, etc.); and e) Letters to the Editor. Special issues of the journal will be considered based on scientific merit.
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