Causality within the Epileptic Network: An EEG-fMRI Study Validated by Intracranial EEG

Vaudano, Anna Elisabetta; Avanzini, Pietro; Tassi, Laura; Ruggieri, Andrea; Cantalupo, Gaetano; Benuzzi, Francesca; Nichelli, Paolo Frigio; Lemieux, Louis; Meletti, Stefano

doi:10.3389/fneur.2013.00185

Cited by 24 publications

(31 citation statements)

References 35 publications

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“…After offline correction of the gradient artifacts and filtering of the EEG signal, the EEG data were reviewed and preprocessed according to a previously published method . The following electrical events were identified and marked in both patients (EMA and IGE) and HC: Eye closure time 0 (EC‐T0).…”

Section: Methodsmentioning

confidence: 99%

The visual system in eyelid myoclonia with absences

Vaudano

Ruggieri

Tondelli

et al. 2014

Annals of Neurology

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Results demonstrated altered anatomo-functional properties of the visual system in EMA. These abnormalities involve a circuit encompassing the occipital cortex and the cortical/subcortical systems physiologically involved in the motor control of eye closure and eye movements. Our work supports EMA as an epileptic condition with distinctive features and provides a contribution to its classification among epileptic syndromes.

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Section: Methodsmentioning

confidence: 99%

The visual system in eyelid myoclonia with absences

Vaudano

Ruggieri

Tondelli

et al. 2014

Annals of Neurology

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“…Spikes are manually detected in EEG data and, in traditional “spike-correlated” analysis, they are treated as zero-duration events, convolved with canonical hemodynamic response function (HRF), and included as regressors of interest in a General Linear Model (GLM) along with simultaneously acquired BOLD time series as dependent variables. fMRI maps related to IEDs often show multiple regions or “networks,” rather than focal singularities, and thus effective connectivity approaches such as Dynamic Causal Modeling (DCM) have been proposed to identify which brain regions drive the generation of seizures within the epileptic network [ 6 , 7 ].…”

Section: Introductionmentioning

confidence: 99%

Using network dynamic fMRI for detection of epileptogenic foci

et al. 2015

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BackgroundEpilepsy is one of the most prevalent neurological disorders. It remains medically intractable for about one-third of patients with focal epilepsy, for whom precise localization of the epileptogenic zone responsible for seizure initiation may be critical for successful surgery. Existing fMRI literature points to widespread network disturbances in functional connectivity. Per previous scalp and intracranial EEG studies and consistent with excessive local synchronization during interictal discharges, we hypothesized that, relative to same regions in healthy controls, epileptogenic foci would exhibit less chaotic dynamics, identifiable via entropic analyses of resting state fMRI time series.MethodsIn order to first validate this hypothesis on a cohort of patients with known ground truth, here we test individuals with well-defined epileptogenic foci (left mesial temporal lobe epilepsy). We analyzed voxel-wise resting-state fMRI time-series using the autocorrelation function (ACF), an entropic measure of regulation and feedback, and performed follow-up seed-to-voxel functional connectivity analysis. Disruptions in connectivity of the region exhibiting abnormal dynamics were examined in relation to duration of epilepsy and patients’ cognitive performance using a delayed verbal memory recall task.ResultsACF analysis revealed constrained (less chaotic) functional dynamics in left temporal lobe epilepsy patients, primarily localized to ipsilateral temporal pole, proximal to presumed focal points. Autocorrelation decay rates differentiated, with 100 % accuracy, between patients and healthy controls on a subject-by-subject basis within a leave-one-subject out classification framework. Regions identified via ACF analysis formed a less efficient network in patients, as compared to controls. Constrained dynamics were linked with locally increased and long-range decreased connectivity that, in turn, correlated significantly with impaired memory (local left temporal connectivity) and epilepsy duration (left temporal – posterior cingulate cortex connectivity).ConclusionsOur current results suggest that data driven functional MRI methods that target network dynamics hold promise in providing clinically valuable tools for identification of epileptic regions.

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“…It can be used to test which brain region drives which making it a very appealing tool in epilepsy diagnostics, where the main question is that of the actual focus or origin of epileptic activity. DCM has already been successfully used to investigate effective connectivity in epileptic networks on a single‐subject patient‐specific level, as well as in a small group of patients with GGE . The latter study investigated the effective connectivity between precuneus, thalamus, and prefrontal cortex to identify a causal hierarchy during GSWDs.…”

Section: Discussionmentioning

confidence: 99%

Unravelling the brain networks driving spike‐wave discharges in genetic generalized epilepsy—common patterns and individual differences

et al. 2018

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SummaryObjectiveGenetic generalized epilepsies (GGEs) are characterized by generalized spike‐wave discharges (GSWDs) in electroencephalography (EEG) recordings without underlying structural brain lesions. The origin of the epileptic activity remains unclear, although several studies have reported involvement of thalamus and default mode network (DMN). The aim of the current study was to investigate the networks involved in the generation and temporal evolution of GSWDs to elucidate the origin and propagation of the underlying generalized epileptic activity.MethodsWe examined 12 patients with GGE and GSWDs using EEG–functional magnetic resonance imaging (fMRI) and identified involved brain areas on the basis of a classical general linear model (GLM) analysis. The activation time courses of these areas were further investigated to reveal their temporal sequence of activations and deactivations. Dynamic causal modeling (DCM) was used to determine the generator of GSWDs in GGE.ResultsWe observed activity changes in the thalamus, DMN, dorsal attention network (DAN), salience network (SN), basal ganglia, dorsolateral prefrontal cortex, and motor cortex with supplementary motor area, however, with a certain heterogeneity between patients. Investigation of the temporal sequence of activity changes showed deactivations in the DMN and DAN and activations in the SN and thalamus preceding the onset of GSWDs on EEG by several seconds. DCM analysis indicated that the DMN gates GSWDs in GGE.SignificanceThe observed interplay between DMN, DAN, SN, and thalamus may indicate a downregulation of consciousness. The DMN seems to play a leading role as a driving force behind these changes. Overall, however, there were also clear differences in activation patterns between patients, reflecting a certain heterogeneity in this cohort of GGE patients.

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Causality within the Epileptic Network: An EEG-fMRI Study Validated by Intracranial EEG

Cited by 24 publications

References 35 publications

The visual system in eyelid myoclonia with absences

The visual system in eyelid myoclonia with absences

Using network dynamic fMRI for detection of epileptogenic foci

Unravelling the brain networks driving spike‐wave discharges in genetic generalized epilepsy—common patterns and individual differences

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