Temporal cascade of frontal, motor and muscle processes underlying human action-stopping

Jana, Sumitash; Hannah, Ricci; Muralidharan, Vignesh; Aron, Adam R.

doi:10.7554/elife.50371

Cited by 139 publications

(207 citation statements)

References 89 publications

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“…Consistent with recent studies, this parametric estimation technique resulted in an attenuation of SSRT compared to the traditional nonparametric integration method (Band et al, 2003;Jana et al, 2020;Matzke, Love, et al, 2017;Skippen et al, 2019;Weigard et al, 2019). Importantly, SSRT int was only moderately correlated with SSRT EXG3 , but was strongly associated with trigger failure.…”

Section: Nonparametric Versus Parametric Estimates Of Ssrtsupporting

confidence: 81%

“…The notion of an automatic response inhibition process is supported by both the fast estimates of SSRT (≈130 ms; see also Matzke, Hughes, et al, 2017;Skippen et al, 2019) and by motor evoked potential studies that suggest the inhibition processes occurs around 140 ms (Coxon, Stinear, & Byblow, 2006;Jana et al, 2020;Raud & Huster, 2017;Waldvogel et al, 2000;Wilcoxon, Nadolski, Samarut, Chassande, & Redei, 2007). In fact, a recent multi-modal study by Jana et al (2020) showed that the cascade of processing that occurs during the stop-signal task suppresses muscle activity within 160 ms after a visual stop-signal onset. As the registration of auditory signals occurs around 30 ms earlier than visual signals (Jain, Bansal, Kumar, & Singh, 2015;Ramautar, Kok, et al, 2006), the 130 ms estimate of SSRT found here is consistent with the fast inhibition process described by Jana et al (2020).…”

Section: The Stop-n1-an Index Of Automatic Inhibition Processes?mentioning

confidence: 94%

“…Trigger failure, or the failure to initiate the stop process, has long been acknowledged as possibly contributing to performance on the stop-signal task (Logan, 1994), but cannot easily be taken into account with nonparametric methods of estimating SSRT (Band et al, 2003). Not accounting for trigger failure has been shown to produce biased estimates of SSRT (Band et al, 2003;Jana, Hannah, Muralidharan, & Aron, 2020;Matzke, Love, et al, 2017;Skippen et al, 2019;Weigard, Heathcote, Matzke, & Huang-Pollock, 2019), indicating that effective inhibitory control relies not only on fast SSRT, but also on the reliability of triggering the stop process (Chatham et al, 2012;Matzke, Love, et al, 2017).…”

Section: Implications Of Biased Ssrt Estimationsmentioning

confidence: 99%

“…In fact, a recent multi-modal study by Jana et al (2020) showed that the cascade of processing that occurs during the stop-signal task suppresses muscle activity within 160 ms after a visual stop-signal onset. As the registration of auditory signals occurs around 30 ms earlier than visual signals (Jain, Bansal, Kumar, & Singh, 2015;Ramautar, Kok, et al, 2006), the 130 ms estimate of SSRT found here is consistent with the fast inhibition process described by Jana et al (2020).…”

Section: The Stop-n1-an Index Of Automatic Inhibition Processes?mentioning

confidence: 99%

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Reconsidering electrophysiological markers of response inhibition in light of trigger failures in the stop‐signal task

et al. 2020

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This study investigates the neural correlates underpinning response inhibition using a parametric ex‐Gaussian model of stop‐signal task performance, fit with hierarchical Bayesian methods, in a large healthy sample (N = 156). The parametric model accounted for both stop‐signal reaction time (SSRT) and trigger failure (i.e., failures to initiate the inhibition process). The returned SSRT estimate (SSRTEXG3) was attenuated by ≈65 ms compared to traditional nonparametric SSRT estimates (SSRTint). The amplitude and latency of the N1 and P3 event‐related potential components were derived for both stop‐success and stop‐failure trials and compared to behavioral estimates derived from traditional (SSRTint) and parametric (SSRTEXG3, trigger failure) models. Both the fronto‐central N1 and P3 peaked earlier and were larger for stop‐success than stop‐failure trials. For stop‐failure trials only, N1 peak latency correlated with both SSRT estimates as well as trigger failure and temporally coincided with SSRTEXG3, but not SSRTint. In contrast, P3 peak and onset latency were not associated with any behavioral estimates of inhibition for either trial type. While the N1 peaked earlier for stop‐success than stop‐failure trials, this effect was not found in poor task performers (i.e., high trigger failure/slow SSRT). These findings are consistent with attentional modulation of both the speed and reliability of the inhibition process, but not for poor performers. Together with the absence of any P3 onset latency effect, our findings suggest that attentional mechanisms are important in supporting speeded and reliable inhibition processes required in the stop‐signal task.

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Section: Nonparametric Versus Parametric Estimates Of Ssrtsupporting

confidence: 81%

Section: The Stop-n1-an Index Of Automatic Inhibition Processes?mentioning

confidence: 94%

Section: Implications Of Biased Ssrt Estimationsmentioning

confidence: 99%

Section: The Stop-n1-an Index Of Automatic Inhibition Processes?mentioning

confidence: 99%

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Reconsidering electrophysiological markers of response inhibition in light of trigger failures in the stop‐signal task

et al. 2020

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“…In fact, studies have shown that both the peak and onset latency of the P3 might correlate with the SSRT [13][14][15][16] , suggesting that P3 latency measures could be potential neural markers of inhibitory capability. In addition to this, studies have found that the effects of inhibitory control can be measured by electromyographic (EMG) activity at response effector muscles in successful stop trials 4,[17][18][19] . While the onset of this so-called partial response EMG (prEMG) reflects the response to the preceding go stimuli, the point for the prEMG decline (i.e.…”

mentioning

confidence: 99%

tDCS over the inferior frontal gyri and visual cortices did not improve response inhibition

Thunberg

Messel

Raud

et al. 2020

Sci Rep

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The ability to cancel an already initiated response is central to flexible behavior. While several different behavioral and neural markers have been suggested to quantify the latency of the stopping process, it remains unclear if they quantify the stopping process itself, or other supporting mechanisms such as visual and/or attentional processing. the present study sought to investigate the contributions of inhibitory and sensory processes to stopping latency markers by combining transcranial direct current stimulation (tDcS), electroencephalography (eeG) and electromyography (eMG) recordings in a withinparticipant design. Active and sham tDcS were applied over the inferior frontal gyri (ifG) and visual cortices (VC), combined with both online and offline EEG and EMG recordings. We found evidence that neither of the active tDCS condition affected stopping latencies relative to sham stimulation. Our results challenge previous findings suggesting that anodal tDCS over the IFG can reduce stopping latency and demonstrates the necessity of adequate control conditions in tDcS research. Additionally, while the different putative markers of stopping latency showed generally positive correlations with each other, they also showed substantial variation in the estimated latency of inhibition, making it unlikely that they all capture the same construct exclusively.

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A new multimodality fusion classification approach to explore the uniqueness of schizophrenia and autism spectrum disorder

Kochunov

et al. 2022

Human Brain Mapping

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Schizophrenia (SZ) and autism spectrum disorder (ASD) sharing overlapping symptoms have a long history of diagnostic confusion. It is unclear what their differences at a brain level are. Here, we propose a multimodality fusion classification approach to investigate their divergence in brain function and structure. Using brain functional network connectivity (FNC) calculated from resting-state fMRI data and gray matter volume (GMV) estimated from sMRI data, we classify the two disorders using the main data (335 SZ and 380 ASD patients) via an unbiased 10-fold cross-validation pipeline, and also validate the classification generalization ability on an independent cohort (120 SZ and 349 ASD patients). The classification accuracy reached up to 83.08% for the testing data and 72.10% for the independent data, significantly better than the results from using the single-modality features. The discriminative FNCs that were automatically selected primarily involved the sub-cortical, default mode, and visual domains. Interestingly, all discriminative FNCs relating to the default mode network showed an intermediate strength in healthy controls (HCs) between SZ and ASD patients. Their GMV differences were mainly driven by the frontal gyrus, temporal gyrus, and insula.Regarding these regions, the mean GMV of HC fell intermediate between that of SZ and ASD, and ASD showed the highest GMV. The middle frontal gyrus was associated with both functional and structural differences. In summary, our work reveals the unique neuroimaging characteristics of SZ and ASD that can achieve high and generalizable classification accuracy, supporting their potential as disorder-specific neural substrates of the two entwined disorders.

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Temporal cascade of frontal, motor and muscle processes underlying human action-stopping

Cited by 139 publications

References 89 publications

Reconsidering electrophysiological markers of response inhibition in light of trigger failures in the stop‐signal task

Reconsidering electrophysiological markers of response inhibition in light of trigger failures in the stop‐signal task

tDCS over the inferior frontal gyri and visual cortices did not improve response inhibition

A new multimodality fusion classification approach to explore the uniqueness of schizophrenia and autism spectrum disorder

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