Grimm, S., Schröger, E., Bendixen, A., Bäß, P., Roye, A., & Deouell, L. Y. (2008). Optimizing the auditory distraction paradigm: Behavioral and event-related potential effects in a lateralized multi-deviant approach. Clinical Neurophysiology, 119, 934-947.

Optimizing the auditory distraction paradigm: Behavioral and event-related potential effects in a lateralized multi-deviant approach.

Grimm, S., Schröger, E., Bendixen, A., Bäß, P., Roye, A., & Deouell, L. Y.

Objective: The present study aimed at adapting a multi-deviant auditory distraction paradigm for a comprehensive screening of functions of voluntary and involuntary auditory attention. Methods: Subjects performed phonetic discrimination on lateralized consonant-vowel syllables in a distraction paradigm in which task-irrelevant deviances occurred on different syllable features. Behavioral performance and event-related potentials (ERPs) were measured within a multi-deviant (frequency, location, and duration deviants, p=0.11 each) and a classic single deviant design (frequency deviants only, p=0.11). Additionally, ERP effects obtained in an active and a passive multi-deviant condition were compared. Results: Behavioral and electrophysiological deviance-related effects were rather similar in the multi-deviant and the single-deviant paradigm. Furthermore, the comparison to the passive listening condition revealed a marked effect of voluntary attention on sensory processing of the syllables. Conclusions: The multi-deviant distraction paradigm provides a gain in time compared to the classic single-deviant distraction paradigm which is not accompanied by a loss in the strength of the effects. Inclusion of a passive listening condition enables the additional evaluation of effects of voluntary attention. Significance: The present multi-deviant distraction paradigm creates an important step towards a tool suited to investigate involuntary and voluntary attention in selected groups of patients during the processing of task-relevant and task-irrelevant auditory information across different acoustic dimensions.