Cochlear partition displacement patterns to frequency varying signals

Abstract

Cochlear microphonic recordings from 10 guinea pig cochleas were used to infer cochlear partition displacement patterns to frequency varying signals. Rate‐dependent differences between rising and falling sweeps were predicted on the basis of delay‐line characteristics of the cochlear partition. The frequency responses of three basal turn locations were assessed using puretones of different frequencies. Tone sweeps with different frequency change rates (i.e., frequency endpoints were kept constant and duration was varied) were generated near the “best‐frequencies” of these regions. Responses to sweeps obtained from each electrode location were summed and the time of occurrence of cochlear microphonic maxima and minima from each location was measured relative to the other locations. The results indicate that inferred cochlear partition displacements to falling frequency sweeps occur sequentially at different points along the partition. Corresponding rising‐frequency sweeps cause displacements more closely spaced in time. Displacement pattern differences occurred only at high rates of change. At low rates, cochlear partition displacements for the rising sweep disperse in time, showing the sequential pattern obtained with falling sweeps. [Work supported by NIH.]