Back to Search Start Over

Noise masking in cochlear synaptopathy: auditory brainstem response vs. auditory nerve response in mouse

Authors :
Kirupa Suthakar
M. Charles Liberman
Source :
J Neurophysiol
Publication Year :
2022
Publisher :
American Physiological Society, 2022.

Abstract

After acoustic overexposure, many auditory-nerve fiber (ANF) synapses permanently retract from surviving cochlear hair cells. This synaptopathy is hard to diagnose, since it does not elevate audiometric thresholds until almost no synapses remain, nevertheless it may degrade discrimination of complex stimuli especially in noisy environments. Here, we study an assay based on masking the auditory brainstem responses (ABRs) to a moderate-level probe tone with continuous noise of varied sound levels, and we investigate the underlying ANF responses at the single-fiber level. Synaptopathy was induced by overexposure to octave-band noise, resulting in a permanent synaptic loss of ∼50%, without permanent threshold elevation except at the highest frequencies. The normal progressive delay of ABR peaks with increasing masker level is diminished in synaptopathic ears; however, the single-fiber analysis suggests that this normal latency shift does not arise because contributing ANFs shift from low-threshold fibers (with high spontaneous rates) to high-threshold fibers (with low spontaneous rates). Rather, it may arise because of a shift in the cochlear region dominating the response. Surprisingly, the dynamic range of masking, i.e., the difference between the lowest masker level that attenuates the ABR to a fixed-level probe and the lowest masker level that eliminates the ABR, is enhanced in the synaptopathic ears. This ABR behavior mirrors the single-fiber data showing a paradoxical enhancement of onset-response synchrony and resistance to masking in responses of ANFs in the synaptopathic regions. An assay based on the dynamic range of masking could be useful in diagnosing synaptic damage in human populations. NEW & NOTEWORTHY Using a masking paradigm, we demonstrate that noise-damaged animals exhibit “improved” performance, i.e., the dynamic range of masker levels over which an ABR remains detectable is increased in regions of damaged cochlear ribbon synapses. Furthermore, the normal masker-induced changes in ABR response latency, used as a biomarker of a healthy cochlear neural population, may reflect a shift in cochlear frequency regions dominating the response, rather than from high- to low spontaneous-rate groups as previously thought.

Details

ISSN :
15221598 and 00223077
Volume :
127
Database :
OpenAIRE
Journal :
Journal of Neurophysiology
Accession number :
edsair.doi.dedup.....77f9a3b08b71f0db0afb001769cb36d9