Differential effects of perturbation direction and magnitude on the neural processing of voice pitch feedback

ObjectiveThe present study examined the differential effects of voice auditory feedback perturbation direction and magnitude on voice fundamental frequency (F0) responses and event-related potentials (ERPs) from EEG electrodes on the scalp.MethodsThe voice F0 responses and N1 and P2 components of ERPs were examined from 12 right-handed speakers when they sustained a vowel phonation and their mid-utterance voice pitch feedback was shifted ±100, ±200, and ±500 cents with 200 ms duration.ResultsDownward voice pitch feedback perturbations led to larger voice F0 responses than upward perturbations. The amplitudes of N1 and P2 components were larger for downward compared with upward pitch-shifts for 200 and 500 cents stimulus magnitudes. Shorter N1 and P2 latencies were also associated with larger magnitudes of pitch feedback perturbations.ConclusionsCorresponding changes in vocal and neural responses to upward and downward voice pitch feedback perturbations suggest that the N1 and P2 components of ERPs reflect neural concomitants of the vocal responses.SignificanceThe findings of interactive effects between the magnitude and direction of voice feedback pitch perturbation on N1 and P2 ERP components indicate that the neural mechanisms underlying error detection and correction in voice pitch auditory feedback are differentially sensitive to both the magnitude and direction of pitch perturbations.

► Cortical ERP magnitudes are sensitive to the direction of voice pitch-shifted auditory feedback. ► Cortical ERP latencies are shorter for larger magnitudes of voice pitch-shifted auditory feedback. ► Neural mechanisms of error detection and correction are sensitive to direction and magnitude of perturbations in voice feedback.