Neural Correlates of Post-error Slowing During a Stop Signal Task: a Functional Magnetic Resonance Imaging Study

Overview

Journal J Cogn Neurosci

Specialty Neurology

Date 2008 Jan 24

PMID 18211230

Citations 97

Authors

Chiang-Shan Ray Li

Cong Huang

Peisi Yan

Prashni Paliwal

Robert Todd Constable

Rajita Sinha

Affiliations

Soon will be listed here.

Abstract

The ability to detect errors and adjust behavior accordingly is essential for maneuvering in an uncertain environment. Errors are particularly prone to occur when multiple, conflicting responses are registered in a situation that requires flexible behavioral outputs; for instance, when a go signal requires a response and a stop signal requires inhibition of the response during a stop signal task (SST). Previous studies employing the SST have provided ample evidence indicating the importance of the medial cortical brain regions in conflict/error processing. Other studies have also related these regional activations to postconflict/error behavioral adjustment. However, very few studies have directly explored the neural correlates of postconflict/error behavioral adjustment. Here we employed an SST to elicit errors in approximately half of the stop trials despite constant behavioral adjustment of the observers. Using functional magnetic resonance imaging, we showed that prefrontal loci including the ventrolateral prefrontal cortex are involved in post-error slowing in reaction time. These results delineate the neural circuitry specifically involved in error-associated behavioral modifications.

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