Volume conduction effects in EEG and MEG

Electroencephalography and clinical neurophysiology Pub Date : 1998-06-01 DOI:10.1016/S0013-4694(97)00147-8

S.P van den Broek, F Reinders, M Donderwinkel, M.J Peters

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引用次数: 292

Abstract

Volume conductor models that are commonly used to describe the EEG and MEG neglect holes in the skull, lesions, the ventricles, and anisotropic conductivity of the skull. To determine the influence of these features, simulations were carried out using the finite element method. The simulations showed that a hole in the skull will have a large effect on the EEG, and as one of the consequences localisation errors up to 15 mm may occur. The effect on the MEG is negligible. The presence of a lesion may cause the shape and magnitude of the EEG and MEG to change. Hence, a lesion has to be taken into account, if the active neurones are close to it. Moreover, a localisation procedure may fail if the lesion is not included in the volume conductor model. Inclusion of the ventricles in the volume conductor model is necessary only if sources are in their vicinity or if their sizes are unusually large. Anisotropic conductivity of the skull has a smearing effect on the EEG but does not influence the MEG.

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脑电和脑磁图的体积传导效应

通常用于描述EEG和MEG的体积导体模型忽略了颅骨中的孔、病变、脑室和颅骨的各向异性电导率。为了确定这些特征的影响，采用有限元方法进行了仿真。模拟结果表明，颅骨上的一个洞会对脑电图产生很大的影响，其中一个后果是可能出现高达15毫米的定位误差。对脑磁图的影响可以忽略不计。病变的存在可能导致脑电图和脑磁图的形状和大小发生变化。因此，如果活跃的神经元靠近病变，就必须考虑病变。此外，如果病变不包括在体积导体模型中，定位程序可能会失败。只有当声源在其附近或其大小异常大时，才有必要将心室包括在体积导体模型中。颅骨的各向异性电导率对脑电图有涂抹效应，但对脑磁图没有影响。

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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Electroencephalography and clinical neurophysiology

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