An Improved Model for the Rate-Level Functions of Auditory-Nerve Fibers

Acoustic information is conveyed to the brain by the spike patterns in auditory-nerve fibers (ANFs). In mammals, each ANF is excited via a single ribbon synapse in a single inner hair cell (IHC), and the spike patterns therefore also provide valuable information about those intriguing synapses. Here we reexamine and model a key property of ANFs, the dependence of their spike rates on the sound pressure level of acoustic stimuli (rate-level functions). We build upon the seminal model of Sachs and Abbas (1974), which provides good fits to experimental data but has limited utility for defining physiological mechanisms. We present an improved, physiologically plausible model according to which the spike rate follows a Hill equation and spontaneous activity and its experimentally observed tight correlation with ANF sensitivity are emergent properties. We apply it to 156 cat ANF rate-level functions using frequencies where the mechanics are linear and find that a single Hill coefficient of 3 can account for the population of functions. We also demonstrate a tight correspondence between ANF rate-level functions and the Ca2+ dependence of exocytosis from IHCs, and derive estimates of the effective intracellular Ca2+ concentrations at the individual active zones of IHCs. Weargue that the Hill coefficient might reflect the intrinsic, biochemical Ca2+ cooperativity of the Ca2+ sensor involved in exocytosis from the IHC. The model also links ANF properties with properties of psychophysical absolute thresholds.