Neuroscience Center, UNC Chapel Hill, Chapel Hill, North Carolina, United States.
Neuroscience Program, Rhodes College, Memphis, Tennessee, United States.
J Neurophysiol. 2023 Aug 1;130(2):427-435. doi: 10.1152/jn.00110.2023. Epub 2023 Jul 12.
Sensorimotor adaptation is supported by at least two parallel learning systems: an intentionally controlled explicit strategy and an involuntary implicit learning system. Past work focused on constrained reaches or finger movements in laboratory environments has shown subconscious learning systems to be driven in part by sensory prediction error (SPE), i.e., the mismatch between the realized and expected outcome of an action. We designed a ball rolling task to explore whether SPEs can drive implicit motor adaptation during complex whole body movements that impart physical motion on external objects. After applying a visual shift, participants rapidly adapted their rolling angles to reduce the error between the ball and the target. We removed all visual feedback and told participants to aim their throw directly toward the primary target, revealing an unintentional 5.06° implicit adjustment to reach angles that decayed over time. To determine whether this implicit adaptation was driven by SPE, we gave participants a second aiming target that would "solve" the visual shift, as in the study by Mazzoni and Krakauer (Mazzoni P, Krakauer JW. 26: 3642-3645, 2006). Remarkably, after rapidly reducing ball-rolling error to zero (due to enhancements in strategic aiming), the additional aiming target caused rolling angles to deviate beyond the primary target by 3.15°. This involuntary overcompensation, which worsened task performance, is a hallmark of SPE-driven implicit learning. These results show that SPE-driven implicit processes, previously observed within simplified finger or planar reaching movements, actively contribute to motor adaptation in more complex naturalistic skill-based tasks. Implicit and explicit learning systems have been detected using simple, constrained movements inside the laboratory. How these systems impact movements during complex whole body, skill-based tasks has not been established. Here, we demonstrate that sensory prediction errors significantly impact how a person updates their movements, replicating findings from the laboratory in an unconstrained ball-rolling task. This real-world validation is an important step toward explaining how subconscious learning helps humans execute common motor skills in dynamic environments.
一种是有意控制的外显策略,另一种是无意识的内隐学习系统。过去的研究集中在实验室环境中的受限伸展或手指运动,表明潜意识学习系统部分受感觉预测误差(SPE)驱动,即动作的实际结果与预期结果之间的不匹配。我们设计了一个球滚动任务来探索在复杂的全身运动中,是否可以通过 SPE 驱动内隐运动适应,这些运动会给外部物体带来物理运动。在施加视觉转移后,参与者迅速调整滚动角度,以减少球和目标之间的误差。我们去除了所有的视觉反馈,并告诉参与者直接将球投向主要目标,结果显示出无意识的 5.06°内隐调整,以适应角度,这种调整随着时间的推移而衰减。为了确定这种内隐适应是否由 SPE 驱动,我们给参与者第二个瞄准目标,该目标会“解决”视觉转移,就像 Mazzoni 和 Krakauer 的研究一样(Mazzoni P, Krakauer JW. 26: 3642-3645, 2006)。值得注意的是,在快速将球滚动误差降低到零(由于策略性瞄准的增强)后,额外的瞄准目标会使滚动角度偏离主要目标 3.15°。这种无意识的过度补偿会恶化任务表现,是 SPE 驱动内隐学习的标志。这些结果表明,以前在简化的手指或平面伸展运动中观察到的 SPE 驱动的内隐过程,积极地促进了更复杂的自然技能任务中的运动适应。内隐和外显学习系统已在实验室中使用简单、受限的运动进行检测。这些系统如何影响复杂的全身、基于技能的任务中的运动尚不清楚。在这里,我们通过一个不受限制的球滚动任务,证明了感觉预测误差显著影响了一个人如何更新他们的运动,复制了实验室的发现。这一真实世界的验证是解释潜意识学习如何帮助人类在动态环境中执行常见运动技能的重要一步。
