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空间选择性α 振荡揭示了工作记忆和注意力之间的瞬息权衡。

Spatially Selective Alpha Oscillations Reveal Moment-by-Moment Trade-offs between Working Memory and Attention.

机构信息

Vrije Universiteit Amsterdam.

The University of Chicago.

出版信息

J Cogn Neurosci. 2018 Feb;30(2):256-266. doi: 10.1162/jocn_a_01198. Epub 2017 Oct 17.

DOI:10.1162/jocn_a_01198
PMID:29040014
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6022736/
Abstract

Current theories assume a functional role for covert attention in the maintenance of spatial information in working memory. Consistent with this view, both the locus of attention and positions stored in working memory can be decoded based on the topography of oscillatory alpha-band (8-12 Hz) activity on the scalp. Thus far, however, alpha modulation has been studied in isolation for covert attention and working memory tasks. Here, we applied an inverted spatial encoding model in combination with EEG to study the temporal dynamics of spatially specific alpha activity during a task that required observers to visually select a target location while maintaining another independently varying location in working memory. During the memory delay period, alpha-based spatial tuning functions shifted from the position stored in working memory to the covertly attended position and back again after the attention task was completed. The findings provide further evidence for a common oscillatory mechanism in both the selection and the maintenance of relevant spatial visual information and demonstrate the dynamic trade-off in prioritization between two spatial tasks.

摘要

目前的理论假设,在工作记忆中维持空间信息方面,内隐注意具有功能作用。与这一观点一致,基于头皮上的振荡 alpha 波段(8-12 Hz)活动的拓扑结构,可以对注意的焦点和工作记忆中存储的位置进行解码。然而,到目前为止,alpha 调制已经在单独的内隐注意和工作记忆任务中进行了研究。在这里,我们应用了一种反转的空间编码模型,并结合 EEG 研究了在需要观察者在视觉上选择目标位置的任务期间,空间特定 alpha 活动的时间动态,同时在工作记忆中保持另一个独立变化的位置。在记忆延迟期间,基于 alpha 的空间调谐函数从工作记忆中存储的位置转移到内隐注意的位置,并且在注意任务完成后又返回。这些发现为选择和维护相关空间视觉信息的共同振荡机制提供了进一步的证据,并证明了两个空间任务之间的优先级动态权衡。

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本文引用的文献

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