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无错误通道试验期间的在线视觉反馈导致运动动力学的主动遗忘:适应轨迹预测误差的证据。

Online Visual Feedback during Error-Free Channel Trials Leads to Active Unlearning of Movement Dynamics: Evidence for Adaptation to Trajectory Prediction Errors.

作者信息

Lago-Rodriguez Angel, Miall R Chris

机构信息

School of Psychology, University of Birmingham Birmingham, UK.

出版信息

Front Hum Neurosci. 2016 Sep 23;10:472. doi: 10.3389/fnhum.2016.00472. eCollection 2016.

DOI:10.3389/fnhum.2016.00472
PMID:27721748
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5033978/
Abstract

Prolonged exposure to movement perturbations leads to creation of motor memories which decay towards previous states when the perturbations are removed. However, it remains unclear whether this decay is due only to a spontaneous and passive recovery of the previous state. It has recently been reported that activation of reinforcement-based learning mechanisms delays the onset of the decay. This raises the question whether other motor learning mechanisms may also contribute to the retention and/or decay of the motor memory. Therefore, we aimed to test whether mechanisms of error-based motor adaptation are active during the decay of the motor memory. Forty-five right-handed participants performed point-to-point reaching movements under an external dynamic perturbation. We measured the expression of the motor memory through error-clamped (EC) trials, in which lateral forces constrained movements to a straight line towards the target. We found greater and faster decay of the motor memory for participants who had access to full online visual feedback during these EC trials (Cursor group), when compared with participants who had no EC feedback regarding movement trajectory (Arc group). Importantly, we did not find between-group differences in adaptation to the external perturbation. In addition, we found greater decay of the motor memory when we artificially increased feedback errors through the manipulation of visual feedback (Augmented-Error group). Our results then support the notion of an active decay of the motor memory, suggesting that adaptive mechanisms are involved in correcting for the mismatch between predicted movement trajectories and actual sensory feedback, which leads to greater and faster decay of the motor memory.

摘要

长时间暴露于运动扰动会导致运动记忆的形成,当扰动消除时,这些记忆会向先前状态衰减。然而,目前尚不清楚这种衰减是否仅归因于先前状态的自发和被动恢复。最近有报道称,基于强化的学习机制的激活会延迟衰减的开始。这就提出了一个问题,即其他运动学习机制是否也可能有助于运动记忆的保留和/或衰减。因此,我们旨在测试基于误差的运动适应机制在运动记忆衰减过程中是否活跃。45名右利手参与者在外部动态扰动下进行点对点的伸手动作。我们通过误差钳制(EC)试验测量运动记忆的表现,在这些试验中,侧向力将运动限制在朝向目标的直线上。我们发现,与那些没有关于运动轨迹的EC反馈的参与者(弧线组)相比,在这些EC试验中能够获得完整在线视觉反馈的参与者(光标组)的运动记忆衰减更大且更快。重要的是,我们没有发现两组在适应外部扰动方面的差异。此外,当我们通过操纵视觉反馈人为增加反馈误差时(增强误差组),我们发现运动记忆的衰减更大。我们的结果支持了运动记忆主动衰减的观点,表明适应性机制参与纠正预测运动轨迹与实际感觉反馈之间的不匹配,这导致运动记忆更大且更快的衰减。

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