脑电电极位置及其潜在脑区的变异性：从同时进行的脑电-功能磁共振成像（EEG-fMRI）数据集中可视化凝胶伪影。

Variability of EEG electrode positions and their underlying brain regions: visualizing gel artifacts from a simultaneous EEG-fMRI dataset.

机构信息

MRC Cognition and Brain Sciences Unit, University of Cambridge, Cambridge, UK.

School of Philosophy, Psychology and Language Sciences, University of Edinburgh, Edinburgh, UK.

出版信息

Brain Behav. 2022 Feb;12(2):e2476. doi: 10.1002/brb3.2476. Epub 2022 Jan 18.

DOI:10.1002/brb3.2476

PMID:35040596

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8865144/

Abstract

INTRODUCTION

We investigated the between-subject variability of EEG (electroencephalography) electrode placement from a simultaneously recorded EEG-fMRI (functional magnetic resonance imaging) dataset.

METHODS

Neuro-navigation software was used to localize electrode positions, made possible by the gel artifacts present in the structural magnetic resonance images. To assess variation in the brain regions directly underneath electrodes we used MNI coordinates, their associated Brodmann areas, and labels from the Harvard-Oxford Cortical Atlas. We outline this relatively simple pipeline with accompanying analysis code.

RESULTS

In a sample of 20 participants, the mean standard deviation of electrode placement was 3.94 mm in x, 5.55 mm in y, and 7.17 mm in z, with the largest variation in parietal and occipital electrodes. In addition, the brain regions covered by electrode pairs were not always consistent; for example, the mean location of electrode PO7 was mapped to BA18 (secondary visual cortex), whereas PO8 was closer to BA19 (visual association cortex). Further, electrode C1 was mapped to BA4 (primary motor cortex), whereas C2 was closer to BA6 (premotor cortex).

CONCLUSIONS

Overall, the results emphasize the variation in electrode positioning that can be found even in a fixed cap. This may be particularly important to consider when using EEG positioning systems to inform non-invasive neurostimulation.

摘要

简介

我们研究了从同时记录的 EEG-fMRI（功能磁共振成像）数据集中的 EEG（脑电图）电极放置的个体间可变性。

方法

神经导航软件用于定位电极位置，这得益于结构磁共振图像中存在的凝胶伪影。为了评估电极下方的大脑区域的变化，我们使用了 MNI 坐标、它们的相关布罗德曼区域以及哈佛-牛津皮质图谱的标签。我们概述了这个相对简单的管道以及相关的分析代码。

结果

在 20 名参与者的样本中，电极放置的平均标准偏差为 x 方向 3.94 毫米，y 方向 5.55 毫米，z 方向 7.17 毫米，顶叶和枕叶电极的变化最大。此外，电极对覆盖的脑区并不总是一致的；例如，电极 PO7 的平均位置映射到 BA18（次级视觉皮层），而 PO8 更接近 BA19（视觉联合皮层）。此外，电极 C1 映射到 BA4（初级运动皮层），而 C2 更接近 BA6（运动前皮层）。

结论

总体而言，结果强调了即使在固定帽中也能找到的电极定位变化。当使用 EEG 定位系统来告知非侵入性神经刺激时，这可能尤其重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2beb/8865144/d2d18ca47f68/BRB3-12-e2476-g002.jpg

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脑电电极位置及其潜在脑区的变异性：从同时进行的脑电-功能磁共振成像（EEG-fMRI）数据集中可视化凝胶伪影。

Variability of EEG electrode positions and their underlying brain regions: visualizing gel artifacts from a simultaneous EEG-fMRI dataset.

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSIONS

简介

方法

结果

结论

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