Reorganization of Neural Activity in Cerebral Cortex during Adaptation to External Force Perturbations of Reaching Movement

Conference Proceedings. 2nd International IEEE EMBS Conference on Neural Engineering, 2005. Pub Date : 2005-03-16 DOI:10.1109/CNE.2005.1419640

X. Cai, Y. Shimansky, Jiping He

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引用次数: 1

Abstract

Knowledge of the properties of motor cortical neurons is crucial for solving the problem of developing a flexible and robust brain-computer interface (BCI). The results of chronic multielectrode recording from the primary motor cortical area of monkey brain during the animal's performance of a center-out 3D reaching task and adaptation to external force perturbation of the movement are described. Recruitment of new cells was observed in the dorsal premotor and primary motor cortex. This consisted of the gradual, day-to-day development of a directional tuning pattern (DTP) of spike activity. In many neurons an "exploratory" variation of DTP was observed. The intensity of variation gradually decreased by the end of adaptation, usually converging to a new pattern. The resulting DTP was retained for at least several days after perturbations were discontinued. The results suggest that the brain cortex can be viewed as a pool of functionally flexible processing elements that can be dynamically recruited into a system controlling the performance of a given motor task and individually adjusted as required for motor learning

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适应外力扰动时大脑皮层神经活动的重组

了解运动皮质神经元的特性对于解决开发灵活和鲁棒的脑机接口(BCI)的问题至关重要。本文描述了猴脑初级运动皮质区慢性多电极记录动物在中心向外的三维到达任务和适应外力扰动运动过程中的结果。在背侧运动前皮层和初级运动皮层观察到新细胞的募集。这包括一个逐渐的，每天发展的定向调谐模式(DTP)的尖峰活动。在许多神经元中观察到DTP的“探索性”变化。在适应结束时，变异的强度逐渐减小，通常会收敛到一个新的模式。所产生的DTP在干扰停止后至少保留了几天。结果表明，大脑皮层可以被视为一个功能灵活的处理元素池，可以动态地纳入控制给定运动任务表现的系统，并根据运动学习的需要进行单独调整

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Conference Proceedings. 2nd International IEEE EMBS Conference on Neural Engineering, 2005.

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