A Touching Advantage: Cross-modal Stop-signals Improve Reactive Response Inhibition

Overview

Journal Exp Brain Res

Specialty Neurology

Date 2024 Jan 16

PMID 38227008

Authors

Maximilian A Friehs

Philipp Schmalbrock

Simon Merz

Martin Dechant

Gesa Hartwigsen

Christian Frings

Affiliations

Soon will be listed here.

Abstract

The ability to inhibit an already initiated response is crucial for navigating the environment. However, it is unclear which characteristics make stop-signals more likely to be processed efficiently. In three consecutive studies, we demonstrate that stop-signal modality and location are key factors that influence reactive response inhibition. Study 1 shows that tactile stop-signals lead to better performance compared to visual stop-signals in an otherwise visual choice-reaction task. Results of Study 2 reveal that the location of the stop-signal matters. Specifically, if a visual stop-signal is presented at a different location compared to the visual go-signal, then stopping performance is enhanced. Extending these results, study 3 suggests that tactile stop-signals and location-distinct visual stop-signals retain their performance enhancing effect when visual distractors are presented at the location of the go-signal. In sum, these results confirm that stop-signal modality and location influence reactive response inhibition, even in the face of concurrent distractors. Future research may extend and generalize these findings to other cross-modal setups.

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