Sensitivity to interaural onset time differences of high frequency stimuli in the inferior colliculus of Eptesicus fuscus

Abstract

Many neurons in the auditory midbrain are tuned to binaural cues. Two prominent binaural cues are the interaural intensity difference (IID) and the interaural time difference (ITD). The ITD cue can further be classified as either an ongoing ITD, which compares the phase difference in the waveform of low frequency stimuli present at either ear, or an onset ITD, which compares the onset time of arrival of two stimuli at either ear. Little research has been done on the sensitivity of single neurons to onset ITDs in the auditory system, particularly in bats. The current study examines the response properties of neurons in the inferior colliculus (IC) of the big brown bat, Eptesicus fuscus, to onset ITDs in response to high frequency pure tones. Measures of neurons’ dynamic response—the segment of the ITD function exhibiting the highest rate of change in activity—revealed an average change of 36% of its maximum response within the estimated behaviorally relevant range of ITDs. Time-intensity trading describes the ability of the brain to compensate the binaural time cue (ITD) cue for the binaural intensity cue (IID) and can be measured as the horizontal shift of an ITD function at various IIDs. Across all IC neurons, an average time-intensity trading ratio of 30 μs/dB was calculated to measure the sensitivity of IC neurons’ ITD response to changing IIDs. Minimum and maximum ITD responses were found to be clustered within a narrow range of ITDs. The average peak ITD response occurred at 268 μs and is consistent with findings in other mammals. All results in ITD tuning, time-intensity trading, and response maximum were invariant to stimulus frequency, confirming that IC neurons responded to onset ITDs and not ongoing ITDs. These results suggest the potential for high frequency onset cues to assist in the azimuthal localization of sound in echolocating bats.