通过神经一致性实现跨模态绑定：对多感官处理的影响。

Crossmodal binding through neural coherence: implications for multisensory processing.

作者信息

Senkowski Daniel, Schneider Till R, Foxe John J, Engel Andreas K

机构信息

Department of Neurophysiology and Pathophysiology, University Medical Center Hamburg-Eppendorf, Hamburg, Germany.

出版信息

Trends Neurosci. 2008 Aug;31(8):401-9. doi: 10.1016/j.tins.2008.05.002. Epub 2008 Jul 2.

DOI:10.1016/j.tins.2008.05.002

PMID:18602171

Abstract

Picture yourself on a crowded sideway with people milling about. The acoustic and visual signals generated by the crowd provide you with complementary information about their locations and motion which needs to be integrated. It is not well understood how such inputs from different sensory channels are combined into unified perceptual states. Coherence of oscillatory neural signals might be an essential mechanism supporting multisensory perception. Evidence is now emerging which indicates that coupled oscillatory activity might serve to link neural signals across uni- and multisensory regions and to express the degree of crossmodal matching of stimulus-related information. These results argue for a new view on multisensory processing which considers the dynamic interplay of neural populations as a key to crossmodal integration.

摘要

想象一下自己身处拥挤的人行道上，人们来回走动。人群产生的听觉和视觉信号为你提供了关于他们位置和动作的互补信息，这些信息需要整合起来。目前还不清楚来自不同感官通道的这些输入是如何组合成统一的感知状态的。振荡神经信号的一致性可能是支持多感官感知的一种基本机制。现在有证据表明，耦合振荡活动可能有助于连接单感官和多感官区域的神经信号，并表达与刺激相关信息的跨模态匹配程度。这些结果支持了一种关于多感官处理的新观点，该观点认为神经群体的动态相互作用是跨模态整合的关键。

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通过神经一致性实现跨模态绑定：对多感官处理的影响。

Crossmodal binding through neural coherence: implications for multisensory processing.

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