Medical University of South Carolina
Adaptive control of auditory representations in listeners with central auditory processing disorder

Central Auditory Processing Disorder (CAPD) is typically defined as impairment in the ability to listen and use auditory information because of atypical function within the central auditory system. The current study uses neuroimaging to characterize CAPD in older adults whose impaired auditory processing abilities could be driven by cognitive and hearing-related declines, in addition to differences in central auditory nervous system function. Functional neuroimaging experiments will be used to test the hypothesis that older adults with CAPD fail to benefit from top-down enhancement of auditory cortex representations for speech. In particular, activation of the adaptive control system in cingulo-opercular cortex is predicted to enhance speech representations in auditory cortex for normal listeners, but not to the same extent for older adults with CAPD. This project aims to develop methods to assess the quality of speech representations based on brain activity and characterize top-down control systems that interact with auditory cortex. The results of this study will improve our understanding of a specific top-down control mechanism, and examine when and how adaptive control enhances speech recognition for people with CAPD.

University of Maryland
Noise trauma induced reorganization of the auditory cortex

Tinnitus (‘ringing in the ears’) is a debilitating condition that is experienced by millions of people worldwide. Tinnitus is frequently seen after noise trauma to the ear. One of the core hypotheses of the etiology of tinnitus is that the percept of ‘ringing in the ears’ is generated by changes in patterns of neural activity in brain circuits at many levels of the auditory pathway. One brain area thought to be at least partly responsible for the tinnitus percept is the primary auditory cortex (A1). However, the precise changes in neural activity within local neuron populations have not been investigated directly. The goal of the proposed project is to probe how noise trauma affects both large- and local-scale organization of A1 brain circuits with unprecedented spatial and cellular resolution in an animal model of tinnitus. Proposed experiments will use state-of-the-art optical imaging approaches to investigate how entire auditory cortical areas (large-scale) and auditory cortical microcircuits (local-scale) are disrupted by noise trauma. A multi-level understanding of circuit dynamics underlying tinnitus (from single neurons to complete representations) will enhance our understanding of precisely how cortical circuits remodel after noise trauma and, in turn, develop and identify strategies by which this debilitating condition can be repaired.