Chair of Human Movement Science, Department of Sport and Health Sciences, Technical University of Munich , Munich , Germany.
Sport and Health Sciences, College of Life and Environmental Sciences, University of Exeter , Exeter , United Kingdom.
J Neurophysiol. 2019 Apr 1;121(4):1289-1299. doi: 10.1152/jn.00710.2018. Epub 2019 Feb 13.
Predicting instead of only reacting to the properties of objects we grasp is crucial to dexterous object manipulation. Although we normally plan our grasps according to well-learned associations, we rely on implicit sensorimotor memories when we learn to interact with novel or ambiguous objects. However, little is known about the influence of sensorimotor predictions on subsequent perception and action. Here, young and elderly subjects repeatedly lifted an object in which the center of mass (CoM) was randomly varied between trials straight upward with the aim of preventing object tilts. After each lift, subjects indicated the location of the perceived CoM and reported how heavy the object felt. Surprisingly, we found that sensorimotor torque memories eventually causing initial lifting errors had substantial effects on the perception of torques, weight, and the torque planning for the next lift. Whereas subjects tended to partly retain their previous erroneous sensorimotor memories (instead of solely relying on the previously encountered torque for the upcoming motor plan), they perceived encountered torques to be stronger when they erroneously predicted them. Additionally, we found that torque prediction errors, as well as the actual torques, made the object feel heavier. By contrast, perception did not influence upcoming motor control. There were no major differences observed between the age groups. The sensorimotor impact on torque perception can be explained by internal feedforward prediction highlighting task-relevant errors, while the partial retention and adaptation of sensorimotor torque memories is reconciled with the trial-to-trial learning rule for motor adaptation. NEW & NOTEWORTHY The current study is the first to demonstrate in an object manipulation task in uncertainty that errors in the sensorimotor prediction of torques influence the perception of both torques and weight, whereas sensorimotor torque memories are partly retained and partly adapted to planning errors. Our results provide novel insights into the predictive mechanisms underpinning the common everyday task of object manipulation and further support theories about the predictive modulation of perception established in other neuroscientific disciplines.
预测物体的属性而不仅仅是对其做出反应,这对于熟练的物体操纵至关重要。尽管我们通常根据习得的关联来规划抓握,但在学习与新的或模糊的物体交互时,我们依赖于内隐的感觉运动记忆。然而,对于感觉运动预测如何影响后续的感知和动作,人们知之甚少。在这里,年轻和老年的参与者反复向上举起一个物体,物体的质心(CoM)在试验之间随机变化,目的是防止物体倾斜。每次提起后,参与者指示感知到的 CoM 的位置,并报告物体感觉有多重。令人惊讶的是,我们发现最终导致初始提升错误的感觉运动扭矩记忆对扭矩、重量的感知以及下一次提升的扭矩规划有显著影响。尽管参与者倾向于部分保留之前的错误感觉运动记忆(而不是仅依赖于之前遇到的扭矩来规划即将到来的运动),但当他们错误地预测扭矩时,他们会感觉到更强的扭矩。此外,我们发现扭矩预测错误以及实际扭矩会使物体感觉更重。相比之下,感知不会影响即将到来的运动控制。在两个年龄组之间没有观察到重大差异。对扭矩感知的感觉运动影响可以通过内部前馈预测来解释,该预测突出了任务相关的错误,而对感觉运动扭矩记忆的部分保留和适应则与运动适应的试验到试验学习规则相一致。
新的和值得注意的是,本研究首次在不确定的物体操纵任务中证明,扭矩的感觉运动预测中的错误会影响扭矩和重量的感知,而感觉运动扭矩记忆则部分保留并部分适应于规划错误。我们的结果为支持物体操纵这一日常任务的预测机制提供了新的见解,并进一步支持了其他神经科学领域中建立的关于感知预测调制的理论。
