Physiological sensitivity to across-channel temporal patterns in response to Schroeder harmonic complexes, based on sequence rather than coincidence detection

Abstract

The flat-envelope harmonic complexes devised by Schroeder (1970) contain a linear frequency sweep whose direction and speed depend on phase curvature C. Physiological studies have focused on responses at a given characteristic frequency (CF), which show only a subtle dependence on the sign and magnitude of C. The question arises whether CNS neurons are sensitive to the temporal pattern across nerve fibers differing in CF. Octopus cells in the cochlear nucleus receive convergent excitatory input from nerve fibers spanning a wide range of CFs and are thought to be monaural coincidence detectors. We studied their spike output and membrane responses to Schroeder complexes in anesthetized gerbils. Octopus cells were indeed tuned to a wide frequency range but showed discrete frequency “hotspots” of differing strength. Most cells showed marked sensitivity to C, with some neurons preferring upward and others downward frequency sweeps, which was broadly stable across SPL and fundamental frequency. The sensitivity to C arises not from coincidence detection, but from a sensitivity to the temporal sequence of activation of inputs tuned to different frequencies. We conclude that marked sensitivity to Schroeder phase exists at the first CNS processing stage and is based on temporal sequence detection across frequency channels.