Animals models of hidden hearing loss: Does auditory-nerve-fiber loss cause real-world listening difficulties?

AbstractThe synapse between inner hair cells and auditory nerve fiber dendrites shows large EPSCs, which are either monophasic or multiphasic. Multiquantal or uniquantal flickering release have been proposed to underlie the unusual multiphasic waveforms. Here the nature of multiphasic waveforms is analyzed using EPSCs recorded in vitro in rat afferent dendrites. Spontaneous EPSCs were deconvolved into a sum of presumed release events with monophasic EPSC waveforms. Results include: first, the charge of EPSCs is about the same for multiphasic versus monophasic EPSCs. Second, EPSC amplitudes decline with the number of release events per EPSC. Third, there is no evidence of a mini-EPSC. Most results can be accounted for by versions of either uniquantal or multiquantal release. However, serial neurotransmitter release in multiphasic EPSCs shows properties that are not fully explained by either model, especially that the amplitudes of individual release events is established at the beginning of a multiphasic EPSC, constraining possible models of vesicle release.

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Contrasting mechanisms for hidden hearing loss: Synaptopathy vs myelin defects

PLoS Computational Biology ◽

10.1371/journal.pcbi.1008499 ◽

2021 ◽

Vol 17 (1) ◽

pp. e1008499

Author(s):

Maral Budak ◽

Karl Grosh ◽

Aritra Sasmal ◽

Gabriel Corfas ◽

Michal Zochowski ◽

...

Keyword(s):

Hearing Loss ◽

Animal Models ◽

Hair Cell ◽

Auditory Nerve ◽

Auditory Neuropathy ◽

Biophysical Model ◽

Spiral Ganglion Neuron ◽

High Threshold ◽

Type I ◽

Hidden Hearing Loss

Hidden hearing loss (HHL) is an auditory neuropathy characterized by normal hearing thresholds but reduced amplitudes of the sound-evoked auditory nerve compound action potential (CAP). In animal models, HHL can be caused by moderate noise exposure or aging, which induces loss of inner hair cell (IHC) synapses. In contrast, recent evidence has shown that transient loss of cochlear Schwann cells also causes permanent auditory deficits in mice with similarities to HHL. Histological analysis of the cochlea after auditory nerve remyelination showed a permanent disruption of the myelination patterns at the heminode of type I spiral ganglion neuron (SGN) peripheral terminals, suggesting that this defect could be contributing to HHL. To shed light on the mechanisms of different HHL scenarios observed in animals and to test their impact on type I SGN activity, we constructed a reduced biophysical model for a population of SGN peripheral axons whose activity is driven by a well-accepted model of cochlear sound processing. We found that the amplitudes of simulated sound-evoked SGN CAPs are lower and have greater latencies when heminodes are disorganized, i.e. they occur at different distances from the hair cell rather than at the same distance as in the normal cochlea. These results confirm that disruption of heminode positions causes desynchronization of SGN spikes leading to a loss of temporal resolution and reduction of the sound-evoked SGN CAP. Another mechanism resulting in HHL is loss of IHC synapses, i.e., synaptopathy. For comparison, we simulated synaptopathy by removing high threshold IHC-SGN synapses and found that the amplitude of simulated sound-evoked SGN CAPs decreases while latencies remain unchanged, as has been observed in noise exposed animals. Thus, model results illuminate diverse disruptions caused by synaptopathy and demyelination on neural activity in auditory processing that contribute to HHL as observed in animal models and that can contribute to perceptual deficits induced by nerve damage in humans.

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