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预测、视觉反应抑制及视觉感知调节:来自视觉诱发电位和表象动量的见解

Prediction, Suppression of Visual Response, and Modulation of Visual Perception: Insights From Visual Evoked Potentials and Representational Momentum.

作者信息

Kimura Motohiro

机构信息

Department of Information Technology and Human Factors, National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan.

出版信息

Front Hum Neurosci. 2021 Aug 25;15:730962. doi: 10.3389/fnhum.2021.730962. eCollection 2021.

DOI:10.3389/fnhum.2021.730962
PMID:34512299
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8425455/
Abstract

When a visual object changes its position along with certain sequential regularities, the visual system rapidly and automatically forms a prediction regarding the future position of the object based on the regularities. Such prediction can drastically alter visual perception. A phenomenon called representational momentum (RM: a predictive displacement of the perceived final position of a visual object along its recent regular pattern) has provided extensive evidence for the predictive modulation of visual perception. The purpose of the present study was to identify neural effects that could explain individual differences in the strength of the predictive modulation of visual perception as measured by RM. For this purpose, in two experiments with a conventional RM paradigm where a bar was discretely presented in a regular rotation manner (with a step of 18° in Experiment 1 and a step of 20° in Experiment 2), visual evoked potentials (VEPs) in response to the regularly rotated bar were measured, and correlations between the magnitudes of RM and VEPs were examined. The results showed that the magnitudes of RM and central P2 were negatively correlated, consistently in both experiments; participants who showed a smaller central P2 tended to exhibit greater RM. Together with a previous proposal that central P2 would represent delayed reactivation of lower visual areas around the striate and prestriate cortices via reentrant feedback projections from higher areas, the present results suggest that greater suppression of delayed reactivation of lower visual areas (as indicated by smaller central P2) may underlie stronger predictive modulation of visual perception (as indicated by greater RM).

摘要

当一个视觉对象按照一定的顺序规律改变其位置时,视觉系统会基于这些规律迅速且自动地对该对象的未来位置形成预测。这种预测会极大地改变视觉感知。一种被称为表征动量(RM:视觉对象的感知最终位置沿其最近规律模式的预测性位移)的现象为视觉感知的预测性调制提供了大量证据。本研究的目的是确定能够解释以RM测量的视觉感知预测性调制强度个体差异的神经效应。为此,在两个采用传统RM范式的实验中,以规则旋转的方式离散呈现一个条形(实验1中步长为18°,实验2中步长为20°),测量对规则旋转条形的视觉诱发电位(VEP),并检查RM大小与VEP之间的相关性。结果表明,在两个实验中,RM大小与中央P2均呈负相关;中央P2较小的参与者往往表现出更大的RM。结合之前的观点,即中央P2可能代表通过来自更高区域的折返反馈投射对纹状和前纹状皮质周围较低视觉区域的延迟再激活,目前的结果表明,较低视觉区域延迟再激活的更大抑制(以较小的中央P2表示)可能是视觉感知更强预测性调制的基础(以更大的RM表示)。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7669/8425455/782f8884114d/fnhum-15-730962-g008.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7669/8425455/782f8884114d/fnhum-15-730962-g008.jpg
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