Functional Connectivity Delineates Distinct Roles of the Inferior Frontal Cortex and Presupplementary Motor Area in Stop Signal Inhibition

Functional Connectivity Delineates Distinct Roles of the Inferior Frontal Cortex and Presupplementary Motor Area in Stop Signal Inhibition

The neural basis of motor response inhibition has drawn considerable attention in recent imaging literature. Many studies have used the go/no-go or stop signal task to examine the neural processes underlying motor response inhibition. In particular, showing greater activity during no-go (stop) compa...

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Veröffentlicht in:The Journal of neuroscience 2009-08, Vol.29 (32), p.10171-10179
Hauptverfasser: Duann, Jeng-Ren, Ide, Jaime S, Luo, Xi, Li, Chiang-shan Ray
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Sprache:eng
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Adult
Basal Ganglia - physiology
Brain Mapping
Female
Frontal Lobe - physiology
Humans
Magnetic Resonance Imaging
Male
Middle Aged
Motor Cortex - physiology
Neural Pathways - physiology
Neuropsychological Tests
Psychomotor Performance - physiology
Psychophysics
Reaction Time
Task Performance and Analysis
Young Adult
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container_end_page 10179
container_issue 32
container_start_page 10171
container_title The Journal of neuroscience
container_volume 29
creator Duann, Jeng-Ren
Ide, Jaime S
Luo, Xi
Li, Chiang-shan Ray
description The neural basis of motor response inhibition has drawn considerable attention in recent imaging literature. Many studies have used the go/no-go or stop signal task to examine the neural processes underlying motor response inhibition. In particular, showing greater activity during no-go (stop) compared with go trials and during stop success compared with stop error trials, the right inferior prefrontal cortex (IFC) has been suggested by numerous studies as the cortical area mediating response inhibition. Many of these same studies as well as others have also implicated the presupplementary motor area (preSMA) in this process, in accord with a function of the medial prefrontal cortex in goal-directed action. Here we used connectivity analyses to delineate the roles of IFC and preSMA during stop signal inhibition. Specifically, we hypothesized that, as an integral part of the ventral attention system, the IFC responds to a stop signal and expedites the stop process in the preSMA, the primary site of motor response inhibition. This hypothesis predicted that preSMA and primary motor cortex would show functional interconnectivity via the basal ganglia circuitry to mediate response execution or inhibition, whereas the IFC would influence the basal ganglia circuitry via connectivity with preSMA. The results of Granger causality analyses in 57 participants confirmed this hypothesis. Furthermore, psychophysiological interaction showed that, compared with stop errors, stop successes evoked greater effective connectivity between the IFC and preSMA, providing additional support for this hypothesis. These new findings provided evidence critically differentiating the roles of IFC and preSMA during stop signal inhibition and have important implications for our understanding of the component processes of inhibitory control.
doi_str_mv 10.1523/JNEUROSCI.1300-09.2009
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subjects Adult
Basal Ganglia - physiology
Brain Mapping
Female
Frontal Lobe - physiology
Humans
Magnetic Resonance Imaging
Male
Middle Aged
Motor Cortex - physiology
Neural Pathways - physiology
Neuropsychological Tests
Psychomotor Performance - physiology
Psychophysics
Reaction Time
Task Performance and Analysis
Young Adult
title Functional Connectivity Delineates Distinct Roles of the Inferior Frontal Cortex and Presupplementary Motor Area in Stop Signal Inhibition
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