Neural Basis of Depth Perception

深度知觉的神经基础

• 批准号: 7628392
• 负责人: GREGORY C DEANGELIS
• 金额: $ 38.54万
• 依托单位: UNIVERSITY OF ROCHESTER
• 依托单位国家: 美国
• 财政年份: 2001
• 资助国家: 美国
• 起止时间: 2001-07-05 至 2011-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7628392
• 关键词: Address; Animals; Area; Behavior; Behavioral; Brain; Cereals; Code; Cues; Depth Perception; Discrimination; Dorsal; Environment; Eye; Eye Movements; Goals; Head; Head Movements; Human; Image; Judgment; Link; Location; Macaca; Mediating; Mental disorders; Monkeys; Motion; Movement; Muscimol; National Eye Institute; Nature; Neurons; Pattern; Perception; Performance; Play; Process; Psyche structure; Psychophysics; Psychophysiology; Relative (related person); Reporting; Research; Research Personnel; Retina; Retinal; Role; Shapes; Signal Transduction; Simulate; Specific qualifier value; Stimulus; Stream; Structure; System; Techniques; Testing; Training; Translating; Variant; Vision Disparity; Vision research; Visual; Visual Cortex; Visual Perception; Visual system structure; Work; area MT; base; cognitive function; extrastriate; extrastriate visual cortex; falls; improved; interest; neural circuit; neurophysiology; object shape; programs; relating to nervous system; research study; sample fixation; stereoscopic; three dimensional structure; two-dimensional; virtual reality; visual process; visual processing

DESCRIPTION (provided by applicant): We interact almost effortlessly with objects in our three-dimensional (3D) visual environment, yet the image formed on the retina of each eye is simply a two-dimensional projection of 3D space that contains no explicit information about depth. Thus, a fundamental task of the visual system is to reconstruct 3D scene structure from the images formed on the retina of each eye. Quantitative information about depth is mainly carried by two visual cues: binocular disparity and motion parallax. The overall goal of this research is to understand where and how these depth cues are processed by neurons in the visual cortex to mediate our perception of a 3D world. This proposal describes experiments that address two fundamental issues regarding the neural basis of depth perception. In Aim #1, we will use a reversible inactivation technique to explore the roles that the dorsal and ventral visual processing streams make to stereoscopic depth perception. By inactivating areas MT and V4, we will test the hypothesis that the dorsal stream mainly processes absolute disparities to compute the location of objects in 3D space, whereas the ventral stream mainly processes relative disparities to compute 3D shape and fine depth structure. In Aim #2, we will carry out the first neurophysiological studies of how the visual system computes depth from motion parallax. Motion parallax resulting from movement of the observer is fundamentally ambiguous regarding the sign of depth (near versus far relative to the point of fixation). As a result, motion parallax generally must be combined with extraretinal signals to compute depth sign. We will test whether neurons in area MT combine retinal image motion with extraretinal signals to compute depth from motion parallax, and we will explore the origins of the extraretinal signals involved in this process. This research addresses the fundamental issue of how neural activity gives rise to visual perception, and also explores how extraretinal signals interact with visual processing to carry out interesting computations in the brain. Thus, this work addresses one of the Program Goals of the National Eye Institute's National Plan for Eye and Vision Research. The ultimate health-related value of this work will follow from a deeper understanding of how cognitive functions can be explained in terms of neural activity. Understanding the links between brain activity and mental function in normal observers will provide a deeper appreciation of the causes of various mental disorders.

描述（由申请人提供）：我们几乎毫不费力地与三维（3D）视觉环境中的物体互动，然而在每只眼睛的视网膜上形成的图像只是3D空间的二维投影，不包含关于深度的明确信息。因此，视觉系统的一项基本任务是从每只眼睛视网膜上形成的图像重建3D场景结构。深度的定量信息主要由两种视觉线索传递：双眼视差和运动视差。这项研究的总体目标是了解这些深度线索在哪里以及如何被视觉皮层中的神经元处理，以调节我们对3D世界的感知。这个提议描述了两个关于深度感知的神经基础的基本问题的实验。在目标#1中，我们将使用可逆失活技术来探索背侧和腹侧视觉处理流对立体深度感知的作用。通过关闭MT和V4区域，我们将验证背侧流主要处理绝对差异来计算物体在三维空间中的位置，而腹侧流主要处理相对差异来计算三维形状和精细深度结构的假设。在Aim #2中，我们将进行视觉系统如何从运动视差计算深度的第一个神经生理学研究。由于观察者的运动而产生的运动视差基本上是模糊的深度符号（相对于注视点的远近）。因此，运动视差通常必须与眼外信号相结合来计算深度符号。我们将测试MT区域的神经元是否将视网膜图像运动与视网膜外信号结合起来，从运动视差中计算深度，并探索参与这一过程的视网膜外信号的来源。这项研究解决了神经活动如何产生视觉感知的基本问题，并探索了视网膜外信号如何与视觉处理相互作用，从而在大脑中进行有趣的计算。因此，这项工作解决了国家眼科研究所国家眼与视觉研究计划的项目目标之一。这项工作的最终健康相关价值将来自于对认知功能如何用神经活动来解释的更深入的理解。了解正常观察者的大脑活动和心理功能之间的联系，将有助于我们更深入地了解各种精神障碍的原因。