前额叶损伤破坏视觉工作记忆表象的后顶叶 α-γ 协调。

Prefrontal Lesions Disrupt Posterior Alpha-Gamma Coordination of Visual Working Memory Representations.

机构信息

University of Montréal, Quebec, Canada.

CHU Sainte-Justine Research Center, Montréal, Quebec, Canada.

出版信息

J Cogn Neurosci. 2021 Aug 1;33(9):1798-1810. doi: 10.1162/jocn_a_01715.

DOI:10.1162/jocn_a_01715

PMID:34375418

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8428813/

Abstract

How does the human brain prioritize different visual representations in working memory (WM)? Here, we define the oscillatory mechanisms supporting selection of "where" and "when" features from visual WM storage and investigate the role of pFC in feature selection. Fourteen individuals with lateral pFC damage and 20 healthy controls performed a visuospatial WM task while EEG was recorded. On each trial, two shapes were presented sequentially in a top/bottom spatial orientation. A retro-cue presented mid-delay prompted which of the two shapes had been in either the top/bottom spatial position or first/second temporal position. We found that cross-frequency coupling between parieto-occipital alpha (α; 8-12 Hz) oscillations and topographically distributed gamma (γ; 30-50 Hz) activity tracked selection of the distinct cued feature in controls. This signature of feature selection was disrupted in patients with pFC lesions, despite intact α-γ coupling independent of feature selection. These findings reveal a pFC-dependent parieto-occipital α-γ mechanism for the rapid selection of visual WM representations.

摘要

人类大脑如何在工作记忆 (WM) 中优先处理不同的视觉表现形式？在这里，我们定义了支持从视觉 WM 存储中选择“何处”和“何时”特征的振荡机制，并研究了 pFC 在特征选择中的作用。14 名外侧 pFC 损伤患者和 20 名健康对照者在记录 EEG 的同时进行了视觉空间 WM 任务。在每次试验中，两个形状按上下空间方向顺序呈现。中间延迟时出现的回溯提示提示两个形状中的哪一个处于上下空间位置或第一/第二时间位置。我们发现，顶枕部α（α；8-12 Hz）振荡与地形分布γ（γ；30-50 Hz）活动之间的跨频耦合在对照组中跟踪了不同提示特征的选择。尽管与特征选择无关，但 pFC 损伤患者的这种特征选择特征受到破坏。这些发现揭示了 pFC 依赖的顶枕部α-γ 机制，用于快速选择视觉 WM 表示。

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