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知觉多稳态中感知和动作的可分离瞳孔特征。

Separable pupillary signatures of perception and action during perceptual multistability.

机构信息

Michigan State University, Department of Psychology, East Lansing, United States.

Michigan State University, Neuroscience Program, East Lansing, United States.

出版信息

Elife. 2021 Aug 11;10:e66161. doi: 10.7554/eLife.66161.

DOI:10.7554/eLife.66161
PMID:34378532
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8378849/
Abstract

The pupil provides a rich, non-invasive measure of the neural bases of perception and cognition and has been of particular value in uncovering the role of arousal-linked neuromodulation, which alters both cortical processing and pupil size. But pupil size is subject to a multitude of influences, which complicates unique interpretation. We measured pupils of observers experiencing perceptual multistability-an ever-changing subjective percept in the face of unchanging but inconclusive sensory input. In separate conditions, the endogenously generated perceptual changes were either task-relevant or not, allowing a separation between perception-related and task-related pupil signals. Perceptual changes were marked by a complex pupil response that could be decomposed into two components: a dilation tied to task execution and plausibly indicative of an arousal-linked noradrenaline surge, and an overlapping constriction tied to the perceptual transient and plausibly a marker of altered visual cortical representation. Constriction, but not dilation, amplitude systematically depended on the time interval between perceptual changes, possibly providing an overt index of neural adaptation. These results show that the pupil provides a simultaneous reading on interacting but dissociable neural processes during perceptual multistability, and suggest that arousal-linked neuromodulator release shapes action but not perception in these circumstances.

摘要

瞳孔为感知和认知的神经基础提供了一种丰富、非侵入性的衡量方式,尤其在揭示与觉醒相关的神经调质的作用方面具有重要价值,这种神经调质会改变皮质处理和瞳孔大小。但是,瞳孔大小受到多种因素的影响,这使得对其进行独特的解释变得复杂。我们测量了经历知觉多态性的观察者的瞳孔,知觉多态性是指在面对不变但不确定的感觉输入时,不断变化的主观知觉。在单独的条件下,内源性产生的知觉变化要么与任务相关,要么不相关,这允许将与知觉相关的和与任务相关的瞳孔信号分开。知觉变化的标志是一种复杂的瞳孔反应,可以分解为两个组成部分:与任务执行相关的扩张,可能表明与觉醒相关的去甲肾上腺素激增,以及与知觉瞬变相关的重叠收缩,可能是改变视觉皮质代表的标志物。收缩,但不是扩张,幅度与知觉变化之间的时间间隔系统相关,这可能为神经适应提供了一个明显的指标。这些结果表明,瞳孔在知觉多态性期间提供了对相互作用但可分离的神经过程的同时读取,并表明在这些情况下,与觉醒相关的神经调质释放会影响行动,但不会影响知觉。

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