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脑电图频率标记以区分皮层对伤害性和非伤害性刺激的反应。

EEG frequency tagging to dissociate the cortical responses to nociceptive and nonnociceptive stimuli.

作者信息

Colon Elisabeth, Legrain Valéry, Mouraux André

机构信息

Université catholique de Louvain.

出版信息

J Cogn Neurosci. 2014 Oct;26(10):2262-74. doi: 10.1162/jocn_a_00648. Epub 2014 Apr 16.

DOI:10.1162/jocn_a_00648
PMID:24738772
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5321242/
Abstract

Whether the cortical processing of nociceptive input relies on the activity of nociceptive-specific neurons or whether it relies on the activity of neurons also involved in processing nonnociceptive sensory input remains a matter of debate. Here, we combined EEG "frequency tagging" of steady-state evoked potentials (SS-EPs) with an intermodal selective attention paradigm to test whether the cortical processing of nociceptive input relies on nociceptive-specific neuronal populations that can be selectively modulated by top-down attention. Trains of nociceptive and vibrotactile stimuli (Experiment 1) and trains of nociceptive and visual stimuli (Experiment 2) were applied concomitantly to the same hand, thus eliciting nociceptive, vibrotactile, and visual SS-EPs. In each experiment, a target detection task was used to focus attention toward one of the two concurrent streams of sensory input. We found that selectively attending to nociceptive or vibrotactile somatosensory input indistinctly enhances the magnitude of nociceptive and vibrotactile SS-EPs, whereas selectively attending to nociceptive or visual input independently enhances the magnitude of the SS-EP elicited by the attended sensory input. This differential effect indicates that the processing of nociceptive input involves neuronal populations also involved in the processing of touch, but distinct from the neuronal populations involved in vision.

摘要

伤害性输入的皮层处理是依赖于伤害性特异性神经元的活动,还是依赖于也参与处理非伤害性感觉输入的神经元的活动,仍然是一个有争议的问题。在这里,我们将稳态诱发电位(SS-EP)的脑电图“频率标记”与多模态选择性注意范式相结合,以测试伤害性输入的皮层处理是否依赖于可通过自上而下的注意进行选择性调节的伤害性特异性神经元群体。将伤害性刺激和振动触觉刺激序列(实验1)以及伤害性刺激和视觉刺激序列(实验2)同时施加到同一只手上,从而诱发伤害性、振动触觉和视觉SS-EP。在每个实验中,使用目标检测任务将注意力集中在两个同时存在的感觉输入流之一上。我们发现,选择性地关注伤害性或振动触觉体感输入会无差别地增强伤害性和振动触觉SS-EP的幅度,而选择性地关注伤害性或视觉输入则会独立增强由被关注的感觉输入诱发的SS-EP的幅度。这种差异效应表明,伤害性输入的处理涉及也参与触觉处理的神经元群体,但与参与视觉处理的神经元群体不同。

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