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阈下知觉的大脑状态和皮质层特异性机制。

Brain state and cortical layer-specific mechanisms underlying perception at threshold.

机构信息

Department of Neuroscience, Yale University, New Haven, United States.

Interdepartmental Neuroscience Program, Yale University, New Haven, United States.

出版信息

Elife. 2024 Nov 18;12:RP91722. doi: 10.7554/eLife.91722.

DOI:10.7554/eLife.91722
PMID:39556415
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11573349/
Abstract

Identical stimuli can be perceived or go unnoticed across successive presentations, producing divergent behavioral outcomes despite similarities in sensory input. We sought to understand how fluctuations in behavioral state and cortical layer and cell class-specific neural activity underlie this perceptual variability. We analyzed physiological measurements of state and laminar electrophysiological activity in visual area V4 while monkeys were rewarded for correctly reporting a stimulus change at perceptual threshold. Hit trials were characterized by a behavioral state with heightened arousal, greater eye position stability, and enhanced decoding performance of stimulus identity from neural activity. Target stimuli evoked stronger responses in V4 in hit trials, and excitatory neurons in the superficial layers, the primary feed-forward output of the cortical column, exhibited lower variability. Feed-forward interlaminar population correlations were stronger on hits. Hit trials were further characterized by greater synchrony between the output layers of the cortex during spontaneous activity, while the stimulus-evoked period showed elevated synchrony in the feed-forward pathway. Taken together, these results suggest that a state of elevated arousal and stable retinal images allow enhanced processing of sensory stimuli, which contributes to hits at perceptual threshold.

摘要

相同的刺激在连续呈现时可能被感知或被忽略,尽管感觉输入相似,但产生了不同的行为结果。我们试图了解行为状态和皮质层以及细胞类特异性神经活动的波动如何导致这种感知变异性。当猴子在感知阈值下正确报告刺激变化时,我们分析了视觉区域 V4 的生理状态和分层电生理活动的生理测量结果。在击中试验中,行为状态表现为觉醒度提高、眼位稳定性增强,以及从神经活动中解码刺激身份的性能增强。目标刺激在击中试验中引起了 V4 更强的反应,并且在浅层中兴奋性神经元表现出更低的变异性,而浅层是皮质柱的主要前馈输出。前馈层间群体相关性在击中时更强。击中试验还表现出在自发活动期间皮层输出层之间更大的同步性,而在刺激诱发期间前馈通路中表现出更高的同步性。总的来说,这些结果表明,提高的觉醒状态和稳定的视网膜图像允许增强对感觉刺激的处理,这有助于在感知阈值时达到命中。

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