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Multisensory Processes in the Mechanics of Hearing

听觉机制中的多感官过程

基本信息

批准号：
9899220
负责人：
JENNIFER M GROH
金额：
$ 34.21万
依托单位：
DUKE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2019
资助国家：
美国
起止时间：
2019-04-01 至 2024-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9899220
关键词：
Affect Age-associated memory impairment Auditory Auditory Perceptual Disorders Auditory system Binaural Brain Cochlea Cognition Disorders Comprehension Coupled Cues Disease Dyslexia Ear Electric Stimulation Eye Eye Movements Head Head Movements Hearing Hearing problem Human Labyrinth Lasers Learning Light Lipreading Location Measurement Measures Mechanics Meniere&apos s Disease Mental disorders Monkeys Motion Motor Movement Outer Hair Cells Pathway interactions Peripheral Phase Play Pontine structure Positioning Attribute Process Property Reporting Reticular Formation Retina Role Route Saccades Schizophrenia Sensory Sensory Disorders Services Signal Transduction Smooth Pursuit Sound Localization Source Speech Speed Stimulus Structure System Testing Time Tinnitus Travel Tympanic membrane Update Vision Visual Visual system structure Visuospatial auditory pathway auditory processing autism spectrum disorder ear muscle experimental study eye center frontal eye fields human subject microphone middle ear mind control multisensory oculomotor sensory system sound superior colliculus Corpora quadrigemina vector virtual

项目摘要

PROJECT SUMMARY Vision helps us hear. For example, lip reading aids speech comprehension, and visual cues are thought to be critical for learning how to localize sounds. Visual-auditory interactions are usually considered to be a cortical phenomenon, but mounting evidence suggests that cross-talk between sensory systems begins well before the cortical stage. In this project, we investigate visual influences over the auditory processing at the earliest point that they occur: in the ear. The auditory pathway has a robust system for modulating the processing of incoming auditory signals via the motoric actions of outer hair cells and middle ear musculature. These structures are under descending control from the brain, providing potential routes for visual-related signals to influence auditory processing. This system is affected by movements of the eyes: we have recently reported a previously unknown oscillation of the eardrum that is time locked to the occurrence of saccades and occurs in the absence of a delivered sound. We hypothesize that the processes that underlie this eye movement-related effect on peripheral auditory processing play a role in reconciling the disparities in visual and auditory spatial signals that accompany eye movements. We will test this hypothesis by determining what eye movement properties determine the properties of the eardrum oscillation, where in the oculomotor system commands that contribute to this effect originate; and how eye-movement related peripheral processing changes in conjunction with changes in the mapping between visual and auditory space. Together, these experiments will shed light on how the brain tunes its auditory input to coordinate with the visual system. The discovery of multisensory signals at the very gateway of the auditory pathway represents a fundamental shift in our understanding of the scope and mechanisms employed not only in service of multisensory integration, but also on what was previously supposed to be unimodal processing. The findings will be relevant to disorders involving hearing as well as other conditions that involve visual and auditory deficits, such as dyslexia, auditory processing disorder, Meniere's disease, autism, schizophrenia, and age-related cognitive impairments.

项目总结视觉帮助我们听力。例如，唇读有助于言语理解，而视觉线索则是思维方式对学习如何本地化声音至关重要。视觉-听觉相互作用通常被认为是一种皮质现象，但越来越多的证据表明，感觉系统之间的串扰开始早在大脑皮层阶段之前。在这个项目中，我们研究视觉对听觉处理的影响在它们出现的最早时刻：在耳朵里。听觉通路具有用于调制传入听觉信号的处理的健壮系统外毛细胞和中耳肌肉的运动动作。这些结构处于下降状态来自大脑的控制，为视觉相关信号影响听觉处理提供了潜在的途径。这个系统受眼睛运动的影响：我们最近报告了一种以前未知的与眼跳发生时间相关的鼓膜振荡，在没有眼跳的情况下发生传来的声音。我们假设，这种与眼动相关的外周听觉效应背后的过程处理在协调伴随的视觉和听觉空间信号的差异方面发挥了作用眼球运动。我们将通过确定眼球运动特性决定什么来检验这一假设鼓膜振荡的特性，在眼球运动系统中，有助于这种效应是如何产生的；以及眼球运动相关的外周处理是如何结合视觉和听觉空间之间的映射的变化。总之，这些实验将阐明大脑是如何调整其听觉输入以与视觉系统。在听觉通路的入口处发现多感官信号表示我们对范围和机制的理解发生了根本转变，不仅在多感官整合的服务，但也是在什么以前被认为是单模式的处理。这些发现将与听力障碍和其他涉及视觉的疾病相关以及听力障碍，如阅读困难、听觉处理障碍、梅尼埃病、自闭症、精神分裂症，以及与年龄相关的认知障碍。