Corticofugal oscillatory modulation of the cochlear receptor during auditory and visual attention in tinnitus

Abstract

AbstractThe mechanisms underlying tinnitus perception are still under research. One of the proposed hypotheses involves an alteration in top-down processing of auditory activity. Low-frequency oscillations in the delta and theta bands have been recently described in brain and cochlear infrasonic signals during selective attention paradigms in normal hearing controls. Here, we propose that the top-down oscillatory activity observed in brain and cochlear signals during auditory and visual selective attention in normal subjects, is altered in tinnitus patients, reflecting an abnormal functioning of the corticofugal pathways that connect brain circuits with the cochlear receptor.Methods:To test this hypothesis, we used a behavioral task that alternates between auditory and visual top-down attention while we simultaneously measured electroencephalogram (EEG) and distortion-product otoacoustic emissions (DPOAE) signals in 14 tinnitus and 14 control subjects.Results:We found oscillatory activity in the delta and theta bands in cortical and cochlear channels in control and tinnitus patients. There were significant decreases in the DPOAE oscillatory amplitude during the visual attention period as compared to the auditory attention period in tinnitus and control groups, while frontal EEG oscillatory activity (Fz) was increased during the visual attention task only in the tinnitus group. The difference between auditory and visual DPOAE oscillatory power in the delta band was stronger in tinnitus individuals as compared to controls.Conclusions:These results confirm the presence of top-down infrasonic low-frequency cochlear oscillatory activity in the delta and theta bands in tinnitus patients. Our results show an increase in the EEG theta oscillatory power in frontal regions of tinnitus sufferers concomitant with a stronger corticofugal suppression of cochlear oscillations in the delta band during visual attention in tinnitus. These findings suggest an increased compensatory corticofugal inhibitory mechanism to the cochlear receptor in tinnitus.