Oscillatory cortico-cortical connectivity during tactile discrimination between dynamic and static stimulation.

IF 2.9 2区 医学 Q2 NEUROSCIENCES
Wenjie Wang, Yuan Liu, Guoyao Wang, Qian Cheng, Dong Ming
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Abstract

Fine sensory modalities play an essential role in perceiving the world. However, little is known about how the cortico-cortical distinguishes between dynamic and static tactile signals. This study investigated oscillatory connectivity during a tactile discrimination task of dynamic and static stimulation via electroencephalogram (EEG) recordings and the fast oscillatory networks across widespread cortical regions. While undergoing EEG recordings, the subject felt an electro-tactile presented by a 3-dot array. Each block consisted of 3 forms of stimulation: Spatio-temporal (dynamic), Spatial (static), and Control condition (lack of electrical stimulation). The average event-related potential for the Spatial and Spatio-temporal conditions exhibited statistically significant differences between 25 and 75, 81 and 121, 174 and 204 and 459 and 489 ms after stimulus onset. Based on those times, the sLORETA approach was used to reconstruct the inverse solutions of EEG. Source localization appeared superior parietal at around 25 to 75 ms, in the primary motor cortex at 81 to 121 ms, in the central prefrontal cortex at 174 to 204 and 459 to 489 ms. To better assess spectral brain functional connectivity, we selected frequency ranges with correspondingly significant differences: for static tactile stimulation, these are concentrated in the Theta, Alpha, and Gamma bands, whereas for dynamic stimulation, the relative energy change bands are focused on the Theta and Alpha bands. These nodes' functional connectivity analysis (phase lag index) showed 3 distinct distributed networks. A tactile information discrimination network linked the Occipital lobe, Prefrontal lobe, and Postcentral gyrus. A tactile feedback network linked the Prefrontal lobe, Postcentral gyrus, and Temporal lobe. A dominant motor feedforward loop network linked the Parietal cortex, Prefrontal lobe, Frontal lobe, and Parietal cortex. Processing dynamic and static tactile signals involves discriminating tactile information, motion planning, and cognitive decision processing.

动态和静态刺激下触觉分辨过程中皮质与皮质之间的振荡联系
精细的感觉模式在感知世界的过程中起着至关重要的作用。然而,人们对皮质如何区分动态和静态触觉信号知之甚少。本研究通过脑电图(EEG)记录和广泛皮层区域的快速振荡网络,研究了在动态和静态刺激的触觉分辨任务中的振荡连接。在进行脑电图记录时,受试者会感觉到由 3 点阵列呈现的电触觉。每个区块包括 3 种形式的刺激:时空(动态)、空间(静态)和控制条件(无电刺激)。空间和时空条件下的平均事件相关电位在刺激开始后的 25 和 75、81 和 121、174 和 204 以及 459 和 489 毫秒之间有显著的统计学差异。根据这些时间,使用 sLORETA 方法重建了脑电图的逆解。信号源定位在 25 至 75 毫秒左右出现在顶叶上部,在 81 至 121 毫秒出现在初级运动皮层,在 174 至 204 毫秒和 459 至 489 毫秒出现在中央前额叶皮层。为了更好地评估频谱大脑功能连通性,我们选择了具有相应显著差异的频率范围:对于静态触觉刺激,这些差异集中在 Theta、Alpha 和 Gamma 波段,而对于动态刺激,相对能量变化波段集中在 Theta 和 Alpha 波段。这些节点的功能连接分析(相位滞后指数)显示出 3 个不同的分布式网络。触觉信息辨别网络连接枕叶、前额叶和中央后回。触觉反馈网络连接了前额叶、中央后回和颞叶。优势运动前馈环路网络连接顶叶皮层、前额叶、额叶和顶叶皮层。处理动态和静态触觉信号涉及触觉信息分辨、运动规划和认知决策处理。
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来源期刊
Cerebral cortex
Cerebral cortex 医学-神经科学
CiteScore
6.30
自引率
8.10%
发文量
510
审稿时长
2 months
期刊介绍: Cerebral Cortex publishes papers on the development, organization, plasticity, and function of the cerebral cortex, including the hippocampus. Studies with clear relevance to the cerebral cortex, such as the thalamocortical relationship or cortico-subcortical interactions, are also included. The journal is multidisciplinary and covers the large variety of modern neurobiological and neuropsychological techniques, including anatomy, biochemistry, molecular neurobiology, electrophysiology, behavior, artificial intelligence, and theoretical modeling. In addition to research articles, special features such as brief reviews, book reviews, and commentaries are included.
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