When three is greater than five: EEG and fMRI signatures of errors in numerical and physical comparisons

Beldzik, Ewa; Domagalik, Aleksandra; Gawłowska, Magda; Marek, Tadeusz; Mojsa-Kaja, Justyna

doi:10.1007/s00429-017-1527-7

Cited by 8 publications

(9 citation statements)

References 62 publications

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“…Regarding the neural substrate for error processing, there is little controversy. In line with the EEG source analysis, the aMCC was found a brain locus for a greater activity for erroneous trials than correct ones (Beldzik et al, 2018;Holroyd et al, 2004;Iannaccone et al, 2015;Wessel et al, 2012) in line with current aMCC accounts suggesting its central role in signaling surprise and the need for adaptive behavior (Ullsperger et al, 2014;Vassena et al, 2020). Interestingly, other fMRI studies provided evidence that the preSMA activity is sensitive to congruency effect (Iannaccone et al, 2015;Nachev et al, 2008;Ullsperger and Von Cramon, 2001) and unbiased by the RT effect (Beldzik et al, 2015b).…”

Section: Introductionsupporting

confidence: 82%

Conflict- and error-related theta activities are coupled to BOLD signals in different brain regions

Beldzik

Ullsperger

Domagalik

et al. 2022

Preprint

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Both conflict and error processing have been linked to the midfrontal theta power (4-8 Hz) increase as indicated by EEG studies and greater hemodynamic activity in the anterior midcingulate cortex (aMCC) as indicated by fMRI studies. Conveniently, the source of the midfrontal theta power was estimated in or nearby aMCC. However, previous studies using concurrent EEG and fMRI recordings in resting-state or other cognitive tasks observed only a negative relationship between theta power and BOLD signal in the brain regions typically showing task-related deactivations. In this study, we used a simultaneous EEG-fMRI technique to investigate a trial-by-trial coupling between theta power and hemodynamic activity during the performance of two conflict tasks. Independent component analysis (ICA) was applied to denoise the EEG signal and select individual midfrontal EEG components, whereas group ICA was applied to fMRI data to obtain a functional parcellation of the frontal cortex. Using a linear mixed-effect model, theta power was coupled with the peak of hemodynamic responses from various frontal, cingulate, and insular cortical sites to unravel the potential brain sources that contribute to conflict- and error-related theta variability. Although several brain regions exhibited conflict-related increases in hemodynamic activity, the conflict pre-response theta showed only a negative correlation to BOLD signal in the midline area 9 (MA9), a region exhibiting conflict-sensitive deactivation. Conversely, and more expectedly, error-related theta showed a positive relationship to activity in the aMCC. Our results provide novel evidence suggesting that the amplitude of pre-response theta reflects the process of active inhibition that suppresses the MA9 activity. This process is affected independently by the stimulus congruency, reaction times variance, and is susceptible to the time-on-task effect. Finally, it predicts the commitment of an omission error. Together, our findings highlight that conflict- and error-related theta oscillations represent fundamentally different processes.

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Section: Introductionsupporting

confidence: 82%

Conflict- and error-related theta activities are coupled to BOLD signals in different brain regions

Beldzik

Ullsperger

Domagalik

et al. 2022

Preprint

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“…The middle occipital cortex putatively supports sensory processing, especially in the case of novel stimuli (Gur et al, 2007;Kiehl, Laurens, Duty, Forster, & Liddle, 2001 precuneus is involved in a wide spectrum of cognitive tasks, including visuo-spatial imagery, episodic memory retrieval, and self-processing operations (Cavanna & Trimble, 2006). However, in this case, its activation, together with adjacent bilateral intraparietal sulci, supports the idea of a transition from the exogenous attentional state, required for the visual perceptual decision, to form response strategies during goaldirected behavior (Beldzik et al, 2018;Paulus et al, 2001;Walz et al, 2014). Finally, bilateral anterior insular and anterior cingulate cortices are crucial for evidence accumulation and decision signaling in perceptual decision-making tasks (Krueger et al, 2017;Rebola, Castelhano, Ferreira, & Castelo-Branco, 2012).…”

Section: Discussionmentioning

confidence: 92%

“…The occipito‐parietal network, which is less commonly observed, involved extensive activations in the occipital and parietal cortices, together with small activations in the bilateral anterior insular and cingulate cortices (Table ). The executive control, dorsal attention, motor, and auditory networks are also commonly observed in the resting and task paradigms (Beckmann et al, ; Beldzik et al, ; Varoquaux et al, ). The fronto‐parietal network was separated into four components and the default mode network into two parts.…”

Section: Resultsmentioning

confidence: 99%

“…The second research question of this study concerns the networks' architecture. Depending on the task, visual networks often reorganize and exhibit functional connections with many other cortical regions (Beldzik, Domagalik, Gawlowska, Marek, & Mojsa-Kaja, 2018;Domagalik, Beldzik, Fafrowicz, Oginska, & Marek, 2012;Specht & Laeng, 2011;Wu et al, 2009); therefore, regions connected to extrastriate cortex would modulate or be modulated by gamma activity. We aim to explore whether fMRI functional connectivity reveals potential loci of gamma projections beyond the visual cortex.…”

Section: Introductionmentioning

confidence: 99%

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Linking visual gamma to task‐related brain networks—a simultaneous EEG‐fMRI study

et al. 2019

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There is a growing interest in human gamma‐band oscillatory activity due to its direct link to neuronal populations, its associations with many cognitive processes, and its positive relationship with fMRI BOLD signal. Visual gamma has been successfully detected using concurrent EEG‐fMRI recordings and linked to activity in the visual cortex using voxel‐wise regression analysis. As gamma‐band oscillations reflect predominantly feedforward projections between brain regions, its inclusion in functional connectivity analysis is highly recommended; however, very few studies have investigated this line of research. In the current study, we aimed to explore this gap by asking which fMRI brain network is related to gamma activity induced by the color discrimination task. Advanced denoising strategies and multitaper spectral decomposition were applied to EEG data to detect gamma oscillations, and group independent component analysis was performed on fMRI data to identify task‐related neural networks. Despite using only trials without motor response (50% of the trials), the two neural measures were successfully coupled. One of the six task‐related networks, the occipito‐parietal network, exhibited significant trial‐by‐trial covariations with gamma oscillations. In addition to the expected extrastriate visual cortex, the network encompasses extensive brain activations in the precuneus, bilateral intraparietal, and anterior insular cortices. We argue that the visual cortex is the source of gamma, whereas the remaining brain regions exhibit feedforward and feedback connections related to this oscillatory activity. Our findings provide evidence for the electrophysiological basis of the connectivity revealed by BOLD signal and impart novel insights into the neural mechanism of color discrimination.

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“…For example, C4 (which we describe as a parietal component), can be found as a posterior alpha component (Artoni et al, 2014;Delorme et al, 2012;Tsai et al, 2006). Others, have a similar parietal label (Beldzik et al, 2017;Chen et al, 2013;Lai et al, 2012;Lin et al, 2012;Wang et al, 2019Wang et al, , 2020, and naturally some don't label the component at all (Bian et al, 2006;Gholamipour & Ghassemi, 2021;Radüntz et al, 2015). The labeling procedure is subjective, and it is difficult to assess the exact position of the component.…”

Section: Discussionmentioning

confidence: 99%

Reproducible Neuronal Components found using Group Independent Component Analysis in Resting State Electroencephalographic Data

Ochoa-Gómez,

Mantilla-Ramos,

Isaza

et al. 2023

Preprint

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ObjectiveEvaluate the reliability of neural components obtained from the appli-cation of the group ICA (gICA) methodology to resting-state EEG datasets acquired from multiple sites.MethodsFive databases from three sites, covering a total of 292 healthy subjects, were analyzed. Each dataset was segmented into groups of 15 subjects, for a total of 19 groups. Data were pre-processed using an automatic pipeline leveraging robust average referencing, wavelet-ICA and automatic rejection of epochs. On each group, stable gICA decompositions were calculated using the ICASSO methodology through a range of orders of decompositions. Each order was characterized by reliability and neuralness metrics, which were evaluated to select a single order of decomposition. Finally, using the decompositions of the selected order, a clustering analysis was performed to find the common components across the 19 groups. Each cluster was characterized by the mean scalp map, its dipole generator with its localization in Talairach coordinates, the spectral behavior of the associated time-series of the components, the assigned ICLabel class and metrics that reflected their reproducibility.ResultsLower order of decompositions benefits the gICA methodology. At this, using an order of ten, the number of reproducible components with high neuronal information tends to be around nine. Of these, the bilateral motor, frontal medial, and occipital neuronal components were the most reproducible across the different datasets, appearing in more than 89% of the 19 groups evaluated.ConclusionWe developed a workflow that allows finding reproducible spatial filters between different data sets. This contributes to the improvement of the spatial resolution of the EEG as a brain mapping technique.

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When three is greater than five: EEG and fMRI signatures of errors in numerical and physical comparisons

Cited by 8 publications

References 62 publications

Conflict- and error-related theta activities are coupled to BOLD signals in different brain regions

Conflict- and error-related theta activities are coupled to BOLD signals in different brain regions

Linking visual gamma to task‐related brain networks—a simultaneous EEG‐fMRI study

Reproducible Neuronal Components found using Group Independent Component Analysis in Resting State Electroencephalographic Data

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