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Literature DB >> 28867348

Cellular Computations Underlying Detection of Gaps in Sounds and Lateralizing Sound Sources.

Donata Oertel¹, Xiao-Jie Cao², James R Ison³, Paul D Allen⁴.

Abstract

In mammals, acoustic information arises in the cochlea and is transmitted to the ventral cochlear nuclei (VCN). Three groups of VCN neurons extract different features from the firing of auditory nerve fibers and convey that information along separate pathways through the brainstem. Two of these pathways process temporal information: octopus cells detect coincident firing among auditory nerve fibers and transmit signals along monaural pathways, and bushy cells sharpen the encoding of fine structure and feed binaural pathways. The ability of these cells to signal with temporal precision depends on a low-voltage-activated K+ conductance (gKL) and a hyperpolarization-activated conductance (gh). This 'tale of two conductances' traces gap detection and sound lateralization to their cellular and biophysical origins.

Entities: Chemical Disease Gene Species

Keywords: HCN; Kv1; gap detection; hearing; ion channels; potassium channel; sound localization

Mesh：

Year: 2017 PMID： 28867348 PMCID： PMC5624792 DOI： 10.1016/j.tins.2017.08.001

Source DB: PubMed Journal: Trends Neurosci ISSN： 0166-2236 Impact factor: 13.837

102 in total

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3. Slow NMDA-Mediated Excitation Accelerates Offset-Response Latencies Generated via a Post-Inhibitory Rebound Mechanism.

Authors: Ezhilarasan Rajaram; Carina Kaltenbach; Matthew J Fischl; Leander Mrowka; Olga Alexandrova; Benedikt Grothe; Matthias H Hennig; Conny Kopp-Scheinpflug
Journal: eNeuro Date: 2019-06-18

3 in total