Nonlinear input-output functions derived from the responses of guinea-pig cochlear nerve fibres: Variations with characteristic frequency
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Cited by (86)
A simplified physiological model of rate-level functions of auditory-nerve fibers
2021, Hearing ResearchCitation Excerpt :Fig. 8 shows data from one example ANF (A5-U24) having a CF of 19.8 kHz and a spontaneous rate of 1.2 spikes/s. Fig. 8A shows rate-level functions and model fits for different stimulus frequencies (see legend in Fig. 8B). The spontaneous rate is independent of frequency (apart from random variation) whereas the maximum rate can vary with frequency, in line with previous observations (e.g., Sachs and Abbas, 1974; Yates et al., 1990, 2000; Cooper and Yates, 1994; Temchin and Ruggero, 2010; Sumner and Palmer, 2012). Fig. 8B shows the SPL needed to obtain a given model rate with a tone at CF plotted against the SPLs needed to obtain the same model rate with tones at the other frequencies.
Timing of cochlear responses inferred from frequency-threshold tuning curves of auditory-nerve fibers
2011, Hearing ResearchCitation Excerpt :Transitions in active mechanical processes at the 1- and 3–4 kHz CF boundaries seem consistent with the results of attempts to derive BM input–output functions at CF from ANF rate-level functions on the assumption that BM responses grow compressively at CF but linearly at frequencies << CF: such putative “BM” input–output functions were less compressive for CFs < 4 kHz than for higher CFs and could not be computed for CFs <1.5 kHz (Cooper and Yates, 1994).
The effect of BAPTA and 4AP in scala media on transduction and cochlear gain
2006, Hearing ResearchCompression in the Auditory System
2023, Neuroscience and Behavioral Physiology