人类灵活运动的自动学习机制。

Cristina Rossi, Kristan A Leech, Ryan T Roemmich, Amy J Bastian
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引用次数: 0

摘要

动作灵活性和自动化是成功驾驭不同环境所必需的。当遇到泥泞的小路等困难地形时,我们几乎可以立即改变走路方式,以便继续行走。这种灵活性是有代价的,因为我们一开始必须仔细关注我们的行动方式。渐渐地,在小径上走了几分钟后,脚步就自动了,这样我们就不需要思考自己的动作了。经典理论表明,不同的自适应运动学习机制赋予运动这些基本特性:显式控制赋予灵活性,而正向模型重新校准赋予自动性。在这里,我们揭示了跑步机行走适应的一个独特机制——一种自动刺激反应映射——它赋予了运动的两种特性。该机制是灵活的,因为它可以学习可以快速改变的步进模式,以适应一系列跑步机配置。它也是自动的,因为它可以在没有参与者故意控制或明确意识的情况下运行。我们的研究结果揭示了行走的前向模型重新校准和自动刺激反应映射机制的串联结构,调和了运动适应和感知重新调整的不同发现。
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Automatic learning mechanisms for flexible human locomotion.

Movement flexibility and automaticity are necessary to successfully navigate different environments. When encountering difficult terrains such as a muddy trail, we can change how we step almost immediately so that we can continue walking. This flexibility comes at a cost since we initially must pay deliberate attention to how we are moving. Gradually, after a few minutes on the trail, stepping becomes automatic so that we do not need to think about our movements. Canonical theory indicates that different adaptive motor learning mechanisms confer these essential properties to movement: explicit control confers rapid flexibility, while forward model recalibration confers automaticity. Here we uncover a distinct mechanism of treadmill walking adaptation - an automatic stimulus-response mapping - that confers both properties to movement. The mechanism is flexible as it learns stepping patterns that can be rapidly changed to suit a range of treadmill configurations. It is also automatic as it can operate without deliberate control or explicit awareness by the participants. Our findings reveal a tandem architecture of forward model recalibration and automatic stimulus-response mapping mechanisms for walking, reconciling different findings of motor adaptation and perceptual realignment.

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