Sensory motor transformations in human cortex

人类皮层的感觉运动转换

基本信息

批准号：
10461165
负责人：
RICHARD A ANDERSEN
金额：
$ 94.05万
依托单位：
CALIFORNIA INSTITUTE OF TECHNOLOGY
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-08-15 至 2026-07-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10461165
关键词：
Accidents Accounting Address Affect Amyotrophic Lateral Sclerosis Anterior Area Attenuated Behavior Control Body part Cerebral cortex Clinical Clinical Research Code Conflict (Psychology)Cutaneous Data Dependence Development Devices Dorsal Environment Esthesia Eye Feedback Future Goals Hand Head Movements Human Imagery Implant Knowledge Learning Lesion Limb Prosthesis Limb structure Location Medical Device Microelectrodes Modeling Motor Motor Cortex Motor Pathways Movement Multiple Sclerosis Nervous system structure Neurons Output Paralysed Parietal Lobe Participant Pathway interactions Patients Performance Peripheral Nervous System Diseases Persons Population Positioning Attribute Property Proprioception Quadriplegia Research Design Retina Role Sensory Signal Transduction Somatosensory Cortex Spinal Cord Lesions Spinal cord injury Stroke Structure System Testing Visual Work arm base body position clinically relevant design experience flexibility grasp improved limb movement microstimulation mind control motor control multisensory neural prosthesis neurophysiology neuroprosthesis recruit relating to nervous system response sensorimotor system sensory cortex sensory feedback sensory input somatosensory visual feedback visual information

项目摘要

Abstract: The long-term objective of this application is to understand cortical processing of sensory to motor transformations within the human cerebral cortex. A vast number of computations must be performed to achieve sensory-guided motor control. Standing out among these computations, visual information of the goals of action must be transformed from the coordinates of the retina to the coordinates of effectors used for movement, for instance limb coordinates for reaching under visual guidance and to world coordinates for interactions in the environment. Once an object is grasped, somatosensory signals from the hand are required for dexterous manipulation of grasped objects. Internal models within the sensory motor pathway are essential for estimating the current state of the body and the external environment, accounting for lags in sensory feedback, and calibrating the body to the environment. We will use the rare opportunity of being able to record from populations of single neurons in a clinical study designed to develop neural prosthetics for tetraplegic participants paralyzed by spinal cord injuries. Cortical implants of microelectrode arrays will be made within three key locations in the sensorimotor system: primary motor cortex, primary somatosensory cortex, and posterior parietal cortex. These microelectrode arrays enable both recording and intracortical microstimulation. We will test the hypothesis that somatosensory and motor cortex represent imagined reaches in hand coordinates, but posterior parietal cortex is task dependent, and its population neural activity can flexibly change coordinate frames to enable encoding of the spatial relations within the body (arm and eyes), between the body and world (arm and reach targets; objects relative to self), and within the world (relative position of objects in the world) as required by task demands. Percepts evoked by intracortical microstimulation and imagined sensations will be used to understand the representation of cutaneous and proprioceptive information within primary somatosensory cortex and posterior parietal cortex. The hypothesis to be tested is that imagined sensation and electrically evoked sensations are highly overlapping—not just in primary somatosensory cortex but also in posterior parietal cortex. Lastly, we hypothesize that the posterior parietal cortex contains in humans an internal model of state estimation that shows plasticity for both natural and brain-control behaviors and transfers this learning to motor cortex. These studies will not only greatly advance our understanding of the human sensorimotor cortical circuit, but also will provide basic knowledge for the design of future neural prosthetics.

摘要：该应用的长期目标是了解感觉的皮层处理人类大脑皮层内的运动转换必须进行大量的计算。为了实现感官引导的运动控制，视觉在这些计算中脱颖而出。行动目标的信息必须从视网膜的坐标转换为用于运动的效应器的坐标，例如在视觉下到达的肢体坐标一旦抓住一个物体，就可以获取环境中交互的指导和世界坐标。灵巧地操纵内部物体需要来自手的体感信号。感觉运动通路内的模型对于估计身体和身体的当前状态至关重要外部环境，考虑感觉反馈的滞后，并根据环境校准身体环境。我们将利用能够在临床中记录单个神经元群体的难得机会旨在为因脊髓损伤而瘫痪的四肢瘫痪参与者开发神经假体的研究。微电极阵列的皮层植入物将在感觉运动的三个关键位置进行系统：初级运动皮层、初级体感皮层、后顶叶皮层。微电极阵列可以实现记录和皮质内微刺激。我们将测试体感和运动皮层代表想象中的手的假设坐标，但后顶叶皮层是任务依赖性的，其群体神经活动可以灵活地更改坐标系以对身体内的空间关系（手臂和眼睛）进行编码，身体与世界之间（手臂和到达目标；相对于自我的物体）以及世界内部（相对物体在世界上的位置）根据任务要求而引起的感知。微刺激和想象的感觉将被用来理解皮肤和初级体感皮层和后顶叶皮层内的本体感觉信息。要测试的假设是想象的感觉和电诱发的感觉高度重叠——不仅在初级体感皮层，而且在后顶叶皮层。发现人类的后顶叶皮层包含一个状态估计的内部模型显示出自然行为和大脑控制行为的可塑性，并将这种学习转移到运动皮层。这些研究不仅将极大地增进我们对人类感觉运动皮层回路的理解，同时也将为未来神经假肢的设计提供基础知识。