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Brainstem control of visual orienting movements

视觉定向运动的脑干控制

基本信息

批准号：
6370509
负责人：
EDWARD G FREEDMAN
金额：
$ 31.07万
依托单位：
UNIVERSITY OF ROCHESTER
依托单位国家：
美国
项目类别：
财政年份：
2001
资助国家：
美国
起止时间：
2001-09-03 至 2005-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/6370509
关键词：
Primates behavioral /social science research tag brain regulatory center caudate nucleus electromyography electrophysiology electrostimulus eye movements head movements motor neurons neural information processing orientation saccades single cell analysis space perception superior colliculus synapses visual perception

项目摘要

DESCRIPTION(adapted from applicant's abstract): The ability to coordinate movements during the performance of complex behaviors in our ever-changing environment is an essential goal of the nervous system. To accomplish this, sensory information must be integrated continuously in order to construct a representation of objects in the world. This critical function requires the ability to distinguish between self-generated and object motion, to integrate diverse sensory information, and to plan and execute simultaneous motor behaviors. The neural control of eye movements is an experimental system that has provided significant insights into the neural mechanisms mediating visual orienting behaviors. Directing the line of sight (gaze) towards interesting objects enhances our perception of the object and provides a way to construct and maintain an internal model of the world. These shifts in gaze direction are generally accomplished by coordinating movements of the eyes and head, and they provide an excellent model system for studying the neural control of orienting behavior, the coordination of multiple body segments, spatial orientation and transformation of sensory information into motor commands. By recording the activity of specific groups of neurons during performance of orienting movements it is possible to correlate neural responses with particular features of coordinated gaze shifts. The goals of the proposed research are to use these techniques to elucidate the neural computations and processes involved in eye-head coordination. Our recent experiments, recording neural activity in the brainstem of head-free monkeys, indicate that the relationships which have previously defined the rules of the oculomotor system, break down when the head and eyes move together to re-direct the line of sight (gaze). The implications of these experiments are that hypotheses of oculomotor control based on data from head restrained subjects, are a special case of a more general system. The proposed experiments are designed to identify and characterize the mechanisms of this more general control system, and will contribute directly to our understanding of the neural control of orienting movements. They also contribute to a more general understanding of the neural mechanisms involved in motor control and coordination during complex behaviors. In addition, this research will facilitate identification and treatment of spatial disorientation, saccadic and/or gaze dysmetrias, and brain stem damage resulting from trauma or disease.

描述（改编自申请人摘要）：协调能力在我们不断变化的复杂行为的表现过程中，环境是神经系统的基本目标。为了实现这一点，感官信息必须持续整合，以构建一个世界上的物体。这一关键功能需要区分自生运动和物体运动的能力，不同的感觉信息，并计划和执行同步运动行为。眼球运动的神经控制是一个实验系统，提供了重要的见解神经机制介导的视觉定向行为将视线（凝视）引向有趣的物体增强了我们对物体的感知，并提供了一种构建并维持一个内在的世界模型。这些注视方向的变化是通常通过协调眼睛和头部的运动来完成，为研究定向神经控制提供了一个很好的模型系统行为，多个身体部分的协调，空间方向和将感觉信息转化为运动指令。通过记录特定神经元组在执行过程中的活动，定向运动，有可能将神经反应与协调的注视转移的特殊特征。拟议的目标研究将使用这些技术来阐明神经计算，涉及眼头协调的过程。我们最近的实验、记录无头猴脑干的神经活动表明，先前已经定义了眼科系统的规则的关系，当头部和眼睛一起移动以重新引导视线时，（凝视）。这些实验的意义在于，基于头部受限受试者的数据的控制，是更一般的系统。拟议的实验旨在识别和描述这种更一般的控制系统的机制，并将直接有助于我们理解定向的神经控制动作它们也有助于更全面地了解神经系统在复杂行为中涉及运动控制和协调的机制。此外，这项研究将有助于识别和治疗空间定向障碍、扫视和/或凝视辨距障碍和脑干损伤由创伤或疾病引起的。