Compensation for traveling wave delay through selection of dendritic delays using spike-timing-dependent plasticity in a model of the auditory brainstem

MJ Spencer; H Meffin; AN Burkitt; DB Grayden

Journal article

Compensation for traveling wave delay through selection of dendritic delays using spike-timing-dependent plasticity in a model of the auditory brainstem

MJ Spencer, H Meffin, AN Burkitt, DB Grayden

Frontiers in Computational Neuroscience | FRONTIERS MEDIA SA | Published : 2018

DOI: 10.3389/fncom.2018.00036

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Abstract

Asynchrony among synaptic inputs may prevent a neuron from responding to behaviorally relevant sensory stimuli. For example, “octopus cells” are monaural neurons in the auditory brainstem of mammals that receive input from auditory nerve fibers (ANFs) representing a broad band of sound frequencies. Octopus cells are known to respond with finely timed action potentials at the onset of sounds despite the fact that due to the traveling wave delay in the cochlea, synaptic input from the auditory nerve is temporally diffuse. This paper provides a proof of principle that the octopus cells’ dendritic delay may provide compensation for this input asynchrony, and that synaptic weights may be adjusted..

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University of Melbourne Researchers

Martin Spencer Author

Hamish Meffin Author

Anthony Burkitt Author

David Grayden Author

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Grants

Awarded by Centre of Excellence for Integrative Brain Function, Australian Research Council

Funding Acknowledgements

AB acknowledges support under the Australian Research Councils Discovery Projects funding scheme (Project DP140102947). DG acknowledges support under the Australian Research Council Discovery Projects funding schemes (Project DP1094830). HM acknowledges support from Australian Research Council Centre of Excellence for Integrative Brain Function (CE140100007).