Temporary Unilateral Hearing Loss Impairs Spatial Auditory Information Processing in Neurons in the Central Auditory System

Temporary Unilateral Hearing Loss Impairs Spatial Auditory Information Processing in Neurons in the Central Auditory System

Temporary conductive hearing loss (CHL) can lead to hearing impairments that persist beyond resolution of the CHL. In particular, unilateral CHL leads to deficits in auditory skills that rely on binaural input (e.g., spatial hearing). Here, we asked whether single neurons in the auditory midbrain, w...

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Published in:Frontiers in neuroscience Vol. 15; p. 721922
Main Authors: Thornton, Jennifer L., Anbuhl, Kelsey L., Tollin, Daniel J.
Format: Journal Article
Language:English
Published: Lausanne Frontiers Research Foundation 01-11-2021
Frontiers Media S.A
Subjects:
Auditory system
Cochlea
conductive hearing loss
Ears & hearing
Hearing loss
Inferior colliculus
Information processing
interaural level difference
Mesencephalon
mutual information
Neurons
Neuroscience
Random variables
sound localization
Young adults
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Summary:Temporary conductive hearing loss (CHL) can lead to hearing impairments that persist beyond resolution of the CHL. In particular, unilateral CHL leads to deficits in auditory skills that rely on binaural input (e.g., spatial hearing). Here, we asked whether single neurons in the auditory midbrain, which integrate acoustic inputs from the two ears, are altered by a temporary CHL. We introduced 6 weeks of unilateral CHL to young adult chinchillas via foam earplug. Following CHL removal and restoration of peripheral input, single-unit recordings from inferior colliculus (ICC) neurons revealed the CHL decreased the efficacy of inhibitory input to the ICC contralateral to the earplug and increased inhibitory input ipsilateral to the earplug, effectively creating a higher proportion of monaural responsive neurons than binaural. Moreover, this resulted in a ∼10 dB shift in the coding of a binaural sound location cue (interaural-level difference, ILD) in ICC neurons relative to controls. The direction of the shift was consistent with a compensation of the altered ILDs due to the CHL. ICC neuron responses carried ∼37% less information about ILDs after CHL than control neurons. Cochlear peripheral-evoked responses confirmed that the CHL did not induce damage to the auditory periphery. We find that a temporary CHL altered auditory midbrain neurons by shifting binaural responses to ILD acoustic cues, suggesting a compensatory form of plasticity occurring by at least the level of the auditory midbrain, the ICC.
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Edited by: Victoria M. Bajo Lorenzana, University of Oxford, United Kingdom
Reviewed by: Fernando R. Nodal, University of Oxford, United Kingdom; Joel I. Berger, The University of Iowa, United States
This article was submitted to Auditory Cognitive Neuroscience, a section of the journal Frontiers in Neuroscience
ISSN:1662-453X
1662-4548
1662-453X
DOI:10.3389/fnins.2021.721922