Offline stimulation of human parietal cortex differently affects resting EEG microstates

Croce, Pierpaolo; Zappasodi, Filippo; Capotosto, Paolo

doi:10.1038/s41598-018-19698-z

Cited by 36 publications

(35 citation statements)

References 49 publications

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“…Notably, microstate B, associated with visual sensory processing 34 , 37 but also shown to decrease during hypnosis 47 , was not associated with prosociality, indicating a complex relationship between different kinds of sensory, bottom-up processing and prosociality. Furthermore, we found indications of a negative association of attention-related microstate D 34 , 37 , 48 with prosociality (this correlation was no longer significant after correction for multiple comparisons across microstate classes), tentatively suggesting an antagonistic relationship of specific kinds of top-down compared to bottom-up processing with prosociality which may be corroborated in future research.…”

Section: Discussionsupporting

confidence: 69%

Temporal dynamics of resting EEG networks are associated with prosociality

Schiller

Kleinert

Teige‐Mocigemba

et al. 2020

Sci Rep

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for example by experimentally modifying the environment of resting EEG recordings 68 , analyzing the relationship between task-independent and task-dependent neural activity 16,69,70 , analyzing brain-to-brain synchronization affecting prosociality 71 , and linking the four resting EEG networks to psychological constructs known to affect prosociality (e.g. empathy, perspective-taking 72-74). Methods Participants. Based on an estimated average medium effect size of associations between resting EEG networks' temporal dynamics and trait variables in similar research 75 , 55 participants (α = 0.05, β = 0.85) are needed to detect a significant effect (Correlation, bivariate normal model; G-Power 76). Our sample included 55 healthy, right-handed participants (M = 24.22 y, s.d. = 4.20, range: 19-40 y). Due to potential confounds associated with hormonal variation in the menstrual cycle and the complexities associated with controlling for this variation in the experimental design 62,63 , only male participants were enrolled in this initial project. All participants were right-handed, and free of current or previous history of physical and psychiatric disorders, and alcohol or drug abuse. The Ethics Committee of the University of Freiburg approved this study, which was conducted according to the principles expressed in the Declaration of Helsinki.

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Section: Discussionsupporting

confidence: 69%

Temporal dynamics of resting EEG networks are associated with prosociality

Schiller

Kleinert

Teige‐Mocigemba

et al. 2020

Sci Rep

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“…Compared to other EEG correlates that are local and require a period of a certain minimum duration, the EEG microstates have been proposed as a widespread measure of the temporary human brain activity that does not change continuously but remains quasi-stable for epochs of about 80-120 ms (Lehmann et al, 2005). The topography of the EEG microstates has been deeply investigated at rest (Britz et al, 2010;Croce et al, 2018a), and several studies associated such topographies with other EEG correlates and with BOLD activity. Specifically, Britz et al (2010) reported a link between the BOLD activations in areas belonging specifically to human networks and the four common resting EEG microstate topographies (A, B, C, and D), and more recently, the emergence of these four microstate topographies at rest was linked with intra-cortical alpha oscillations (Milz et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

Pre-stimulus EEG Microstates Correlate With Anticipatory Alpha Desynchronization

Spadone

Croce

Zappasodi

et al. 2020

Front. Hum. Neurosci.

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In the last decades, several electrophysiological markers have been investigated to better understand how humans precede a signaled event. Among others, the prestimulus microstates' topography, representing the whole brain activity, has been proposed as a promising index of the anticipatory period in several cognitive tasks. However, to date, a clear relationship between the metrics of the pre-stimulus microstates [i.e., the global explained variance (GEV) and the frequency of occurrence (FOO)] and well-known electroencephalography marker of the anticipation (i.e., the alpha power reduction) has not been investigated. Here, after extracting the microstates during the expectancy of the semantic memory task, we investigate the correlations between the microstate features and the anticipatory alpha (8-12 Hz) power reduction (i.e., the event-related de-synchronization of the alpha rhythms; ERD) that is widely interpreted as a functional correlate of brain activation. We report a positive correlation between the occurrence of the dominant, but not non-dominant, microstate and both the mean amplitude of high-alpha ERD and the magnitude of the alpha ERD peak so that the stronger the decrease (percentage) in the alpha power, the higher the FOO of the dominant microstate. Moreover, we find a positive correlation between the occurrence of the dominant microstate and the latency of the alpha ERD peak, suggesting that subjects with higher FOO present the stronger alpha ERD closely to the target. These correlations are not significant between the GEV and all anticipatory alpha ERD indices. Our results suggest that only the occurrence of the dominant, but not nondominant, microstate should be considered as a useful electrophysiological correlate of the cortical activation.

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“…More specifically, the applied spatio-temporal analysis approach clusters the resting EEG signal into a limited number of scalp electrical potential topographies that remain stable for certain time periods (60–120 ms) before dynamically changing into a different topography that remains stable again (for recent studies taking this approach, see 23,24 ). These time periods of stable topographies are known as “microstates”, and transitions between microstates are believed to represent sequential coordinated activity of various, distributed neural networks 6,7 .…”

Section: Introductionmentioning

confidence: 99%

Oxytocin modulates the temporal dynamics of resting EEG networks

Schiller

Koenig

Heinrichs

2019

Sci Rep

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Oxytocin is a key modulator of social interaction, but we possess little knowledge of its underlying effects on neuropsychological processes. We used a spatio-temporal EEG microstates analysis to reveal oxytocin’s effects on the temporal dynamics of intrinsically generated activity in neural networks. Given oxytocin’s known anxiolytic effects, we hypothesized that it increases the temporal stability of the four archetypal EEG resting networks. Eighty-six male participants had received oxytocin or placebo intranasally before we recorded their resting EEG. As hypothesized, oxytocin globally increased the average duration of the four archetypal resting networks and specifically decreased the occurrence and coverage of an autonomic processing-related network to benefit greater coverage of an attention-related network. Moreover, these neurophysiological changes were more pronounced in participants with high anxiety levels and strong subjectively experienced effects of the oxytocin administration. In sum, our study shows that oxytocin reduces rapid switching among neural resting networks by increasing their temporal stability. Specifically, it seems to reduce the brain’s need for preparing the internally-oriented processing of autonomic information, thus enabling the externally-oriented processing of social information. Changes in the temporal dynamics of resting networks might underlie oxytocin’s anxiolytic effects - potentially informing innovative psychobiological treatment strategies.

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Offline stimulation of human parietal cortex differently affects resting EEG microstates

Cited by 36 publications

References 49 publications

Temporal dynamics of resting EEG networks are associated with prosociality

Temporal dynamics of resting EEG networks are associated with prosociality

Pre-stimulus EEG Microstates Correlate With Anticipatory Alpha Desynchronization

Oxytocin modulates the temporal dynamics of resting EEG networks

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