利用人类脑电皮层电图(ECoG)信号解码隐蔽的空间注意力。
Decoding covert spatial attention using electrocorticographic (ECoG) signals in humans.
机构信息
BCI R&D Progr, Wadsworth Ctr, NYS Dept of Health, Albany, NY 12201, USA.
出版信息
Neuroimage. 2012 May 1;60(4):2285-93. doi: 10.1016/j.neuroimage.2012.02.017. Epub 2012 Feb 16.
Abstract
This study shows that electrocorticographic (ECoG) signals recorded from the surface of the brain provide detailed information about shifting of visual attention and its directional orientation in humans. ECoG allows for the identification of the cortical areas and time periods that hold the most information about covert attentional shifts. Our results suggest a transient distributed fronto-parietal mechanism for orienting of attention that is represented by different physiological processes. This neural mechanism encodes not only whether or not a subject shifts their attention to a location, but also the locus of attention. This work contributes to our understanding of the electrophysiological representation of attention in humans. It may also eventually lead to brain-computer interfaces (BCIs) that optimize user interaction with their surroundings or that allow people to communicate choices simply by shifting attention to them.
摘要
这项研究表明,从大脑表面记录的脑电描记图(ECoG)信号为人类视觉注意力的转移及其方向提供了详细信息。ECoG 允许识别具有最多关于隐蔽注意力转移信息的皮质区域和时间段。我们的结果表明,注意的定向存在一个短暂的分布式额顶机制,该机制由不同的生理过程来表示。这种神经机制不仅编码了主体是否将注意力转移到某个位置,还编码了注意力的焦点。这项工作有助于我们理解人类注意力的电生理表现。它最终也可能导致脑机接口(BCIs),优化用户与周围环境的交互,或者允许人们通过将注意力转移到它们上来简单地进行选择沟通。
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