猕猴辅助眼区中与预期时间和消逝时间相关的神经元活动。

Neuronal activity related to anticipated and elapsed time in macaque supplementary eye field.

作者信息

Ohmae Shogo, Lu Xiaofeng, Takahashi Toshimitsu, Uchida Yusuke, Kitazawa Shigeru

机构信息

Department of Neurophysiology, Juntendo University, School of Medicine, 2-1-1 Hongo, Tokyo 113-8421, Japan.

出版信息

Exp Brain Res. 2008 Feb;184(4):593-8. doi: 10.1007/s00221-007-1234-3. Epub 2007 Dec 7.

DOI:10.1007/s00221-007-1234-3

PMID:18064442

Abstract

It is essential to sense anticipated and elapsed time in our daily life. Several areas of the brain including parietal cortex, prefrontal cortex, basal ganglia and olivo-cerebellar system are known to be related to this temporal processing. We now describe a number of cells in the supplementary eye field (SEF) with phasic, delay activity and postdelay activity modulation that varied with the length of the delay period. This variation occurred in two manners. First, cells became active with the shorter delay periods (GO signal presented earlier). We call these cells "short-delay cells". Second, cells became active with the longer delay periods (GO signal presented later). We call these cells "long-delay cells". However, such changed neuronal activity did not correlate with reaction time. These results suggest that the delay-dependent activity may reflect anticipated and elapsed time during performance of a delayed saccadic eye movement.

摘要

在我们的日常生活中，感知预期时间和流逝时间至关重要。已知大脑的几个区域，包括顶叶皮层、前额叶皮层、基底神经节和橄榄小脑系统，都与这种时间处理有关。我们现在描述了辅助眼区（SEF）中的一些细胞，它们具有相位性、延迟活动和延迟后活动调制，这些调制随延迟期的长度而变化。这种变化以两种方式发生。首先，细胞在较短的延迟期（更早呈现GO信号）时变得活跃。我们将这些细胞称为“短延迟细胞”。其次，细胞在较长的延迟期（更晚呈现GO信号）时变得活跃。我们将这些细胞称为“长延迟细胞”。然而，这种变化的神经元活动与反应时间无关。这些结果表明，延迟依赖性活动可能反映了延迟扫视眼动执行过程中的预期时间和流逝时间。

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猕猴辅助眼区中与预期时间和消逝时间相关的神经元活动。

Neuronal activity related to anticipated and elapsed time in macaque supplementary eye field.

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