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

Skippen, Patrick; Fulham, W. Ross; Michie, Patricia T.; Matzke, Dora; Heathcote, Andrew; Karayanidis, Frini

doi:10.1111/psyp.13619

Cited by 26 publications

(27 citation statements)

References 75 publications

(139 reference statements)

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“…Indeed, EMG and MEP recordings show that the first signs of motor-system inhibition in these measures emerge as early as ∼150ms after the onset of a stop-signal (Jana, Hannah, Muralidharan, & Aron, 2020; Raud & Huster, 2017). In line with this, recent studies have shown that cortical signals that are related to stopping success can also be found in similar time ranges (Huster et al, 2020; Jana et al, 2020; Skippen et al, 2020; Wessel, 2019). Just like the beforementioned EMG and MEP measurements of functional motor inhibition, these cortical signatures often precede both SSRT, as well as the typical onset latency of the fronto-central P3, by several dozens of milliseconds.…”

Section: Discussionsupporting

confidence: 66%

“…While this latter association has since been independently replicated (Huster, Messel, Thunberg, & Raud, 2020) the association between the stop-signal P3 and inhibitory processing still remains controversial. One argument is that additional ERPs, including ERPs that predate the P3 and likely reflect attentional processes, also correlate with SSRT (Huster et al, 2020; Skippen et al, 2020). In addition to this debate focusing on the electrophysiology of stopping, the fundamental assumptions underlying the SSRT computation have also recently been called into question themselves, with some authors arguing that SSRT systematically overestimates the latency of the stopping process – specifically because the classic SSRT computation does not take into account trials in which the inhibitory control process is not triggered at all (Matzke, Curley, Gong, & Heathcote, 2019; Patrick Skippen et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex

Hynd

Soh

Rangel

et al. 2020

Preprint

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By stopping actions even after their initiation, humans can adapt their ongoing behavior rapidly to changing environmental circumstances. The neural processes underlying the implementation of rapid action-stopping are still controversially discussed. In the early 1990s, a fronto-central P3 event-related potential (ERP) was identified in the human EEG response following stop-signals in the classic stop-signal task, accompanied by the proposal that this ERP reflects the “inhibitory” side of the purported horse-race underlying successful action-stopping. Later studies have lent support to this interpretation by finding that the amplitude and onset of the stop-signal P3 relate to both overt behavior and to movement-related EEG activity in ways predicted by the race model. However, such studies are limited by the ability of EEG to allow direct inferences about the presence (or absence) of true, physiologically inhibitory signaling at the neuronal level. To address this, we here present a cross-modal individual differences investigation of the relationship between the features stop-signal P3 ERP and GABAergic neurotransmission in primary motor cortex (M1, as measured by paired-pulse transcranial magnetic stimulation). Following recent work, we measured short-interval intracortical inhibition (SICI), a marker of inhibitory GABAa activity in M1, in a group of 41 human participants who also performed the stop-signal task while undergoing EEG recordings. In line with the P3-inhibition hypothesis, we found that subjects with stronger inhibitory GABA activity in M1 also showed both faster onsets and larger amplitudes of the stop-signal P3. This provides direct evidence linking the properties of this ERP to a true physiological index of motor system inhibition. We discuss these findings in the context of recent theoretical developments and empirical findings regarding the neural implementation of inhibitory control during action-stopping.

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Section: Discussionsupporting

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex

Hynd

Soh

Rangel

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Second, compared with experiments with humans, monkeys are well trained and well accustomed to the task, typically completing up to 10 times more trials than humans. This may be demonstrated through our observation that monkeys have a much smaller proportion of trigger failures (;5%) compared with what has been previously observed in human (;20%) studies (Skippen et al, 2019(Skippen et al, , 2020. However, although RTs and SSRTs are typically shorter in macaques than humans, the relative relationship between the two is similar between species.…”

Section: Discussionsupporting

confidence: 57%

Dissociation of Medial Frontal β-Bursts and Executive Control

2020

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The neural mechanisms of executive and motor control concern both basic researchers and clinicians. In human studies, preparation and cancellation of movements are accompanied by changes in the b-frequency band (15-29 Hz) of electroencephalogram (EEG). Previous studies with human participants performing stop signal (countermanding) tasks have described reduced frequency of transient b-bursts over sensorimotor cortical areas before movement initiation and increased b-bursting over medial frontal areas with movement cancellation. This modulation has been interpreted as contributing to the trial-bytrial control of behavior. We performed identical analyses of EEG recorded over the frontal lobe of macaque monkeys (one male, one female) performing a saccade countermanding task. While we replicate the occurrence and modulation of b-bursts associated with initiation and cancellation of saccades, we found that b-bursts occur too infrequently to account for the observed stopping behavior. We also found b-bursts were more common after errors, but their incidence was unrelated to response time (RT) adaptation. These results demonstrate the homology of this EEG signature between humans and macaques but raise questions about the current interpretation of b band functional significance.

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“…Another potential explanation is that we relied on the stopping speed derived from a button press to measure SSRT. While this is a widely used measure in response inhibition research, it has its drawbacks (e.g., Skippen et al, 2020). Most importantly for our study, the SSRT is only a summary measure for each participant and does not provide single trial information.…”

Section: Discussionmentioning

confidence: 99%

Volume of β-Bursts, But Not Their Rate, Predicts Successful Response Inhibition

et al. 2021

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In humans, impaired response inhibition is characteristic of a wide range of psychiatric diseases and of normal aging. It is hypothesised that the right inferior frontal cortex plays a key role by inhibiting the motor cortex via the basal ganglia. The electroencephalographyderived β-rhythm (15-29 Hz) is thought to reflect communication within this network, with increased right frontal β-power often observed prior to successful response inhibition. Recent literature suggests that averaging spectral power obscures the transient, burst-like nature of β-activity. There is evidence that the rate of β-bursts following a Stop signal is higher when a motor response is successfully inhibited. However, other characteristics of β-burst events, and their topographical properties, have not yet been examined. Here, we used a large human (male and female) electroencephalography Stop Signal Task dataset (n=218) to examine averaged normalised β-power, β-burst rate and β-burst 'volume' (which we defined as burst duration x frequency span x amplitude). We first sought to optimise the β-burst detection method. In order to find predictors across the whole scalp, and with high temporal precision, we then used machine learning to (1) classify successful vs. failed stopping and to (2) predict individual Stop Signal Reaction Time. β-Burst volume was significantly more predictive of successful and fast stopping than β-burst rate and normalised β-power. The classification model generalised to an external dataset (n=201). We suggest β-burst volume is a sensitive and reliable measure for investigation of human response inhibition. 3 Significance StatementThe electroencephalography-derived β-rhythm (15-29 Hz) is associated with the ability to inhibit ongoing actions. In this study, we sought to identify the specific characteristics of βactivity that contribute to successful and fast inhibition. In order to search for the most relevant features of β-activityacross the whole scalp and with high temporal precisionwe employed machine learning on two large datasets. Spatial and temporal features of β-burst 'volume' (duration x frequency span x amplitude) predicted response inhibition outcomes in our data significantly better than β-burst rate and normalised β-power. These findings suggest that multidimensional measures of β-bursts, such as burst volume, can add to our understanding of human response inhibition.

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

Cited by 26 publications

References 75 publications

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex

Dissociation of Medial Frontal β-Bursts and Executive Control

Volume of β-Bursts, But Not Their Rate, Predicts Successful Response Inhibition

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

Cited by 26 publications

References 75 publications

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABAaactivity in primary motor cortex

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABAaactivity in primary motor cortex

Dissociation of Medial Frontal β-Bursts and Executive Control

Volume of β-Bursts, But Not Their Rate, Predicts Successful Response Inhibition

Contact Info

Product

Resources

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Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex

Latency and amplitude of the stop-signal P3 event-related potential are related to inhibitory GABA_aactivity in primary motor cortex