Cortical correlates of auditory sensory gating: a simultaneous near-infrared spectroscopy event-related potential study.

Sensory gating refers to the ability of cerebral networks to inhibit responding to irrelevant environmental stimuli, a mechanism that protects the brain from information overflow. The reduction of the P50 amplitude (an early component of the event-related potential/ERP in electrophysiological recordings) after repeated occurrence of a particular acoustic stimulus is one means to quantitatively assess gating mechanisms. Even though P50 suppression has been extensively investigated, neuroimaging studies on the cortical correlates of auditory sensory gating are so far very sparse. Near-infrared spectroscopy (NIRS) is an optical imaging technique perfectly suitable for the investigation of auditory paradigms, since it involves virtually no noise. We conducted a simultaneous NIRS-ERP measurement to assess cortical correlates of auditory sensory gating in humans. The multi-channel NIRS recording indicated a specific activation of prefrontal and temporo-parietal cortices during conditions of increased sensory gating (dual-click trials). Combining the hemodynamic data with an electrophysiological index of the "gating quality" (gating quotient Q) revealed a positive correlation between the amount of sensory gating and the strength of the hemodynamic response during dual-clicks in the left prefrontal and temporal cortices. The results are in line with previous findings and confirm a possible inhibitory influence of the prefrontal cortex on primary auditory cortices.

Far field potentials from the brain stem after transcutaneous vagus nerve stimulation.

Recently, the vagus nerve has gained particular interest in neuropsychiatry, as neurodegenerative diseases like Alzheimer's and Parkinson's disease are supposed to affect the brainstem nuclei of the vagus nerve early in their course. In addition, electric stimulation of the vagus nerve has therapeutic effects in otherwise therapy-refractory epilepsies and depressions. So far, no method is available to assess vagus nerve function in this context. On this background and based on the established techniques of early acoustic evoked potentials we investigated if a transcutaneous electric stimulation of the sensory auricular branch of the vagus nerve innervating parts of the outer ear is feasible in healthy subjects using this hypothesis-generated approach. We were able to record a clear, reproducible Vagus Sensory Evoked Potential (VSEP) measured as far field potential probably originating in vagus nuclei in the brainstem. Further studies are needed to test the interindividual stability and test-retest reliability of this new method before potential diagnostic and therapeutic applications might be evaluated.