Anxiety disrupts performance monitoring: integrating behavioral, event-related potential, EEG microstate, and sLORETA evidence

Nash, Kyle; Leota, Josh; Kleinert, Tobias; Hayward, Dana A.

doi:10.1093/cercor/bhac307

Cited by 6 publications

(4 citation statements)

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“…The temporal characteristics of microstates, including their average duration in milliseconds, their average number of occurrences per second, and their percentage contribution to the EEG, have been found to reflect momentary mental states (e.g. Nash et al 2022b;Bréchet and Michel 2022) and stable trait characteristics (e.g. Schiller et al 2020;Zanesco et al 2020;Nash et al 2022a).…”

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confidence: 99%

Normative Intercorrelations Between EEG Microstate Characteristics

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EEG microstates are brief, recurring periods of stable brain activity that reflect the activation of large-scale neural networks. The temporal characteristics of these microstates, including their average duration, number of occurrences, and percentage contribution have been shown to serve as biomarkers of mental and neurological disorders. However, little is known about how microstate characteristics of prototypical network types relate to each other. Normative intercorrelations among these parameters are necessary to help researchers better understand the functions and interactions of underlying networks, interpret and relate results, and generate new hypotheses. Here, we present a systematic analysis of intercorrelations between EEG microstate characteristics in a large sample representative of western working populations (n = 583). Notably, we find that microstate duration is a general characteristic that varies across microstate types. Further, microstate A and B show mutual reinforcement, indicating a relationship between auditory and visual sensory processing at rest. Microstate C appears to play a special role, as it is associated with longer durations of all other microstate types and increased global field power, suggesting a relationship of these parameters with the anterior default mode network. All findings could be confirmed using independent EEG recordings from a retest-session (n = 542).

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Normative Intercorrelations Between EEG Microstate Characteristics

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“…Microstate analysis of ERPs enables the researcher to identify, time, and sequence neurophysiological processes across distinct experimental conditions or trial types, such as anxiety vs. no-anxiety (Nash et al 2023 ), conditioned fear vs. safety stimuli (Pizzagalli et al 2003 ; Mueller and Pizzagalli 2016 ), direct vs. averted gaze (Burra et al 2016 ), honest vs. dishonest decisions (Globig et al 2023 ), ingroup- vs. outgroup-related information (Walker et al 2008 ; Schiller et al 2020a ), less vs. more attractive faces (Han et al 2020 , 2022 ), self- vs. other-voice processing (Iannotti et al 2022 ), social vs. non-social stimuli/contexts (Thierry et al 2006 ; Ortigue et al 2009 , 2010 ; Cacioppo et al 2012 , 2015 , 2016 , 2018 ; Koban et al 2012 ; Decety and Cacioppo 2012 ; Pegna et al 2015 ), stereotype-congruent vs. stereotype-incongruent information (Schiller et al 2016 ), stress vs. no stress (Schiller et al 2023a ) and neutral vs. emotional stimuli (Pizzagalli et al 2000 ; Gianotti et al 2007 , 2008 ; Cacioppo et al 2016 ; Tanaka et al 2021 ; Zerna et al 2021 ; Liang et al 2022 ; Prete et al 2022 ) (Fig. 3 ).…”

Section: Applications Of Eeg Microstatesmentioning

confidence: 99%

“…Microstate analysis of continuous EEG has been used to illuminate the sources of individual differences in socio-affective traits, in domains such as aggression (Kleinert and Nash 2022 ), anxiety (Schiller et al 2019b ; Du et al 2022 ; Nash et al 2023 ), approach vs. withdrawal tendency (Takehara et al 2020 ; Kaur et al 2020 ), disgust sensitivity (Li et al 2021 ), empathy (Zhang et al 2021 ), personality (Zanesco et al 2020 ; Guo et al 2020 ; Tomescu et al 2022 ), prosociality (Schiller et al 2020b ), religious belief (Schlegel et al 2012 ; Nash et al 2022 ), or somatic awareness (Pipinis et al 2017 ; Tarailis et al 2021 ; Zanesco et al 2021a ). The majority of these studies have relied on regression or correlation analysis to uncover associations between features of the prototypical microstate classes (e.g., duration, occurrence, coverage, transition probabilities; see Box 4 ) and socio-affective traits (see Fig.…”

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confidence: 99%

EEG Microstates in Social and Affective Neuroscience

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Social interactions require both the rapid processing of multifaceted socio-affective signals (e.g., eye gaze, facial expressions, gestures) and their integration with evaluations, social knowledge, and expectations. Researchers interested in understanding complex social cognition and behavior face a “black box” problem: What are the underlying mental processes rapidly occurring between perception and action and why are there such vast individual differences? In this review, we promote electroencephalography (EEG) microstates as a powerful tool for both examining socio-affective states (e.g., processing whether someone is in need in a given situation) and identifying the sources of heterogeneity in socio-affective traits (e.g., general willingness to help others). EEG microstates are identified by analyzing scalp field maps (i.e., the distribution of the electrical field on the scalp) over time. This data-driven, reference-independent approach allows for identifying, timing, sequencing, and quantifying the activation of large-scale brain networks relevant to our socio-affective mind. In light of these benefits, EEG microstates should become an indispensable part of the methodological toolkit of laboratories working in the field of social and affective neuroscience.

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“…Thus, microstate analysis has emerged as a promising tool to study trait-related functions of the human brain. Another advance in microstate research is the increasing number of freely available tools to conduct microstate analyses, including the microstate toolbox for EEGLAB (Koenig 2017), CARTOOL (Brunet et al 2011), RAGU (Koenig et al 2011), or the Python library Pycrostates (Férat et al 2022b), enabling standardized microstate analyses based on both resting state and event-related EEG data (for examples of event-related microstate analysis, see Schiller et al 2016;Nash et al 2022b).…”

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confidence: 99%

On the Reliability of the EEG Microstate Approach

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EEG microstates represent functional brain networks observable in resting EEG recordings that remain stable for 40–120ms before rapidly switching into another network. It is assumed that microstate characteristics (i.e., durations, occurrences, percentage coverage, and transitions) may serve as neural markers of mental and neurological disorders and psychosocial traits. However, robust data on their retest-reliability are needed to provide the basis for this assumption. Furthermore, researchers currently use different methodological approaches that need to be compared regarding their consistency and suitability to produce reliable results. Based on an extensive dataset largely representative of western societies (2 days with two resting EEG measures each; day one: n = 583; day two: n = 542) we found good to excellent short-term retest-reliability of microstate durations, occurrences, and coverages (average ICCs = 0.874-0.920). There was good overall long-term retest-reliability of these microstate characteristics (average ICCs = 0.671-0.852), even when the interval between measures was longer than half a year, supporting the longstanding notion that microstate durations, occurrences, and coverages represent stable neural traits. Findings were robust across different EEG systems (64 vs. 30 electrodes), recording lengths (3 vs. 2 min), and cognitive states (before vs. after experiment). However, we found poor retest-reliability of transitions. There was good to excellent consistency of microstate characteristics across clustering procedures (except for transitions), and both procedures produced reliable results. Grand-mean fitting yielded more reliable results compared to individual fitting. Overall, these findings provide robust evidence for the reliability of the microstate approach.

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Anxiety disrupts performance monitoring: integrating behavioral, event-related potential, EEG microstate, and sLORETA evidence

Cited by 6 publications

References 85 publications

Normative Intercorrelations Between EEG Microstate Characteristics

Normative Intercorrelations Between EEG Microstate Characteristics

EEG Microstates in Social and Affective Neuroscience

On the Reliability of the EEG Microstate Approach

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