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初级视觉皮层中的振荡神经元同步作为刺激选择的一个关联因素。

Oscillatory neuronal synchronization in primary visual cortex as a correlate of stimulus selection.

作者信息

Fries Pascal, Schröder Jan-Hinrich, Roelfsema Pieter R, Singer Wolf, Engel Andreas K

机构信息

F. C. Donders Centre for Cognitive Neuroimaging, 6525 EK Nijmegen, The Netherlands.

出版信息

J Neurosci. 2002 May 1;22(9):3739-54. doi: 10.1523/JNEUROSCI.22-09-03739.2002.

DOI:10.1523/JNEUROSCI.22-09-03739.2002
PMID:11978850
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6758402/
Abstract

Spike and local field potential activity were recorded simultaneously from multiple sites in primary visual cortex of strabismic cats, while monocular stimulation alternated with dichoptic stimulation, inducing interocular rivalry. During interocular rivalry, there is competition between the two nonfusible stimuli presented to the two eyes, and only one stimulus is selected at any time. We biased this competition in three different ways: (1) we exploited the condition that in strabismic cats there is often one dominant eye that is selected for most of the time. (2) We presented the two stimuli with a temporal offset, which biases competition in favor of the newly appearing stimulus. (3) We presented the two stimuli with highly different contrasts, which biases competition in favor of the stimulus with higher contrast. Whenever competition was biased in favor of the stimulus activating the recorded neurons, gamma-frequency synchronization of the respective responses was enhanced, and vice versa. Firing rates showed some differences between stimulation conditions. However, when present, these changes were inversely related to a competitive advantage of the respective stimulus. We hypothesize that enhanced gamma-frequency synchronization in primary visual cortex is a correlate of stimulus selection. Synchronization is likely to be translated into firing rate changes at later processing stages.

摘要

在斜视猫的初级视觉皮层多个部位同时记录尖峰电位和局部场电位活动,同时单眼刺激与双眼刺激交替进行,引发双眼竞争。在双眼竞争期间,呈现给两只眼睛的两个不可融合刺激之间存在竞争,且在任何时刻只有一个刺激被选中。我们通过三种不同方式使这种竞争产生偏差:(1)我们利用了斜视猫中通常存在一只占主导地位的眼睛,该眼睛在大多数时间被选中这一情况。(2)我们以时间偏移的方式呈现两个刺激,这会使竞争偏向于新出现的刺激。(3)我们以对比度差异很大的方式呈现两个刺激,这会使竞争偏向于对比度更高的刺激。每当竞争偏向于激活所记录神经元的刺激时,相应反应的伽马频率同步就会增强,反之亦然。刺激条件之间的放电率存在一些差异。然而,当这些差异出现时,它们与相应刺激的竞争优势呈负相关。我们假设初级视觉皮层中增强的伽马频率同步是刺激选择的一个相关因素。同步很可能在后续处理阶段转化为放电率变化。

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