Department of Neurology, Johns Hopkins University, Baltimore, Maryland.
Neuroscience, Johns Hopkins University, Baltimore, Maryland.
J Neurophysiol. 2022 Oct 1;128(4):982-993. doi: 10.1152/jn.00474.2021. Epub 2022 Sep 21.
Although much research on motor learning has focused on how we adapt our movements to maintain performance in the face of imposed perturbations, in many cases, we must learn new skills from scratch or de novo. Compared with adaptation, relatively little is known about de novo learning. In part, this is because learning a new skill can involve many challenges, including learning to recognize new patterns of sensory input and generate new patterns of motor output. However, even with familiar sensory cues and well-practiced movements, the problem of quickly selecting the appropriate actions in response to the current state is challenging. Here, we devised a bimanual hand-to-cursor mapping that isolates this control problem. We find that participants initially struggled to control the cursor under this bimanual mapping, despite explicit knowledge of the mapping. Performance improved steadily over multiple days of practice, however. Participants exhibited no aftereffects when reverting to a veridical cursor, confirming that participants learned the new task de novo, rather than through adaptation. Corrective responses to mid-movement perturbations of the target were initially weak, but with practice, participants gradually became able to respond rapidly and robustly to perturbations. After 4 days of practice, participants' behavior under the bimanual mapping almost matched performance using a veridically mapped cursor. However, there remained a small but persistent difference in performance level. Our findings illustrate the dynamics and limitations of learning a novel controller and introduce a promising paradigm for tractably investigating this aspect of motor skill learning. We examine motor learning in a novel task in which participants must use both hands to control an on-screen cursor via a nonintuitive interface. Participants gradually improved their ability to control the cursor over multiple practice sessions, but their control was worse than baseline even after 4 days. These results reveal the timescale and limitations of de novo learning-an important but understudied form of learning.
虽然许多关于运动学习的研究都集中在我们如何适应运动以在受到强制干扰的情况下保持性能,但在许多情况下,我们必须从头开始或重新学习新技能。与适应相比,关于重新学习的知识相对较少。部分原因是学习一项新技能可能涉及许多挑战,包括学习识别新的感觉输入模式和产生新的运动输出模式。然而,即使有熟悉的感觉提示和经过充分练习的动作,快速选择适当的动作来响应当前状态的问题也是具有挑战性的。在这里,我们设计了一种双手到光标之间的映射,以隔离这个控制问题。我们发现,尽管参与者明确知道这种映射关系,但他们最初在这种双手映射下很难控制光标。然而,经过多天的练习,表现稳步提高。当参与者恢复到真实的光标时,他们没有表现出后效,这证实了参与者是从头开始学习新任务,而不是通过适应。对目标运动过程中的中间干扰的纠正反应最初很弱,但随着练习,参与者逐渐能够快速而稳健地对干扰做出反应。经过 4 天的练习,参与者在双手映射下的行为几乎与使用真实映射光标时的表现相匹配。然而,在表现水平上仍然存在一个很小但持续存在的差异。我们的发现说明了学习新控制器的动态和局限性,并引入了一种有前途的范例,用于可追踪地研究运动技能学习的这一方面。我们在一项新任务中研究运动学习,其中参与者必须通过一种非直观的界面使用双手来控制屏幕上的光标。在多个练习会话中,参与者逐渐提高了控制光标的能力,但即使在 4 天后,他们的控制能力仍不如基线。这些结果揭示了从头开始学习的时间尺度和局限性——这是一种重要但研究不足的学习形式。
