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Pre-motor Neural Circuits for Exploratory Movement

用于探索性运动的前运动神经回路

基本信息

批准号：
8617309
负责人：
Fan Wang
金额：
$ 33.08万
依托单位：
DUKE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-02-15 至 2018-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8617309
关键词：
3-Dimensional Age Amputation Amputees Animals Attention Back Behavior Brain Complex Development Devices Disease Electrophysiology (science)Esthesia Exploratory Behavior Face Facial nerve nucleus Feedback Fingers Foundations Future Generations Glutamates Hand Human In Situ Hybridization Intention Lateral Lead Maps Mediating Memory Methods Molecular Motor Motor Neurons Movement Mus Neonatal Neurons Neurotransmitters Organ Paralysed Patients Pattern Phenotype Physical environment Play Property Rabies virus Rodent Role Scheme Sensory Shapes Side Structure Study models Surface Synapses Tactile Testing Texture Touch sensation Vibrissae abstracting active control barrel cortex base design information processing insight motor control mouse model nervous system disorder neural circuit neuromechanism neuroregulation optogenetics physical property postnatal presynaptic public health relevance receptor reconstruction relating to nervous system research study sensorimotor system sensory feedback somatosensory tool

项目摘要

DESCRIPTION (provided by applicant): Pre-motor Neural Circuits for Exploratory Movement Abstract Movements performed by animals in order to explore external objects are called "exploratory movements". Humans use delicate and complex movements of fingers/fingertips to discern the texture, shape and other physical properties of objects, and to manipulate tools. Rodents explore their physical environment through rhythmic sweeping of their vibrissae ("whisking"), and thus serve as a major model for studying neural circuits controlling exploratory touch movements. The final common control of the tactile vibrissae is provided by motor neurons located in the lateral facial nucleus (vFMNs). The objective of this proposal is to discover and characterize the "premotor circuitry" that directly regulates the activities of vFMNs. We will identify the "connectivity maps" of premotor neurons that provide monosynaptic input for the different vFMNs controlling vibrissa protraction and retraction. We wil also determine the "neurotransmitter phenotypes" of identified premotor neurons, and characterize the functional inputs of different premotor neurons onto vFMNs using electrophysiological and optogenetic approaches. Furthermore, we will determine how developmental changes in the vFMN premotor circuitry enable the postnatal emergence of bilaterally coordinated and often synchronized exploratory whisking behavior. Identifying the structural and functional wiring diagram of these premotor neural circuits is a critical step for investigating the generation and voluntary control f exploratory movements. Results from this study will also provide new foundations for understanding motor control of hand and finger movements in humans, and thus can help lead to the design of superior neuroprosthetics devices to restore exploratory movements following paralysis or amputation.

描述（由申请人提供）：探索性运动的前运动神经回路动物为了探索外部物体而进行的抽象运动被称为“探索性运动”。人类使用手指/指尖的微妙和复杂的运动来辨别物体的纹理，形状和其他物理属性，并操纵工具。啮齿类动物通过有节奏地扫动触须（“拂动”）来探索它们的物理环境，因此可以作为研究控制探索性触摸运动的神经回路的主要模型。触觉触须的最终共同控制由位于面外侧核（vFMNs）的运动神经元提供。这项建议的目的是发现和表征的“运动前电路”，直接调节活动的vFMNs。我们将确定的“连接地图”的前运动神经元，提供单突触输入的不同vFMNs控制触须延长和收缩。我们还将确定已鉴定的前运动神经元的“神经递质表型”，并使用电生理学和光遗传学方法表征不同前运动神经元对vFMNs的功能输入。此外，我们将确定如何在vFMN前运动电路的发展变化，使出生后出现的双边协调和经常同步探索搅拌行为。识别这些前运动神经回路的结构和功能布线图是研究探索性运动的产生和自主控制的关键步骤。这项研究的结果也将为理解人类手部和手指运动的运动控制提供新的基础，从而有助于设计出上级神经修复装置，以恢复瘫痪或截肢后的探索性运动。