Diversity of characteristic frequency rate-intensity functions in guinea pig auditory nerve fibres
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2022, Cell ReportsCitation Excerpt :Furthermore, diverse tuning across sensory input populations has been reported in numerous systems (see Bale et al., 2013; Goldberg, 2000; Raman et al., 2010), suggesting that the mechanism described here may be of general relevance for understanding how latency codes are utilized by the brain. In the mammalian auditory system, for example, there is wide variation in the sensitivity of auditory nerve fibers that co-varies with spontaneous firing rate, axonal morphology, and transcriptional patterns, and has been functionally linked to the wide dynamic range of human hearing (Liberman, 1982; Liberman and Oliver, 1984; Petitpre et al., 2018; Viemeister, 1983; Winter et al., 1990). Although the origin of the diverse tuning observed across A-type electroreceptors is not known, a prior electrophysiological study noted that A-type electroreceptors exhibit widely varying spike thresholds, and an electron microscopy study observed notable variation in the area of the outer membrane of A cells (Bell, 1990b; Bell et al., 1989).
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Present address: M.R.C. Institute of Hearing Research, University Park, University of Nottingham, Nottingham BG7 2RD U.K.