学会预料意外之事:灵长类动物小脑在自主运动过程中的快速更新。
Learning to expect the unexpected: rapid updating in primate cerebellum during voluntary self-motion.
作者信息
Brooks Jessica X, Carriot Jerome, Cullen Kathleen E
机构信息
Aerospace Medical Research Unit, Department of Physiology, McGill University, Montreal, Canada.
出版信息
Nat Neurosci. 2015 Sep;18(9):1310-7. doi: 10.1038/nn.4077. Epub 2015 Aug 3.
Abstract
There is considerable evidence that the cerebellum has a vital role in motor learning by constructing an estimate of the sensory consequences of movement. Theory suggests that this estimate is compared with the actual feedback to compute the sensory prediction error. However, direct proof for the existence of this comparison is lacking. We carried out a trial-by-trial analysis of cerebellar neurons during the execution and adaptation of voluntary head movements and found that neuronal sensitivities dynamically tracked the comparison of predictive and feedback signals. When the relationship between the motor command and resultant movement was altered, neurons robustly responded to sensory input as if the movement was externally generated. Neuronal sensitivities then declined with the same time course as the concurrent behavioral learning. These findings demonstrate the output of an elegant computation in which rapid updating of an internal model enables the motor system to learn to expect unexpected sensory inputs.
摘要
有大量证据表明,小脑通过构建对运动感觉后果的估计,在运动学习中起着至关重要的作用。理论表明,将这种估计与实际反馈进行比较,以计算感觉预测误差。然而,缺乏这种比较存在的直接证据。我们在自愿头部运动的执行和适应过程中对小脑神经元进行了逐次试验分析,发现神经元敏感性动态跟踪预测信号和反馈信号的比较。当运动指令与最终运动之间的关系改变时,神经元对感觉输入有强烈反应,就好像运动是由外部产生的一样。然后,神经元敏感性随着同时发生的行为学习以相同的时间进程下降。这些发现证明了一种精妙计算的输出,其中内部模型的快速更新使运动系统能够学会预期意外的感觉输入。
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