Simon Vogrin scite author profile

Accurate identification of seizure-generating brain tissue is challenging, particularly when MRI shows no clear abnormality or extensive abnormality. Plummer et al. achieve this non-invasively by analysing the earliest detectable part of the electromagnetic seizure signal recordable across the head surface. Their findings challenge current practice with its reliance on invasive intracranial monitoring.

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Amygdala volumetry in "imaging-negative" temporal lobe epilepsy

Bower

Vogrin²,

Morris³

et al. 2003

Journal of Neurology, Neurosurgery & Psychiatry

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Centre of epileptogenic tubers generate and propagate seizures in tuberous sclerosis

Kannan

Vogrin

Bailey

et al. 2016

Brain

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SEE DUCHOWNY DOI101093/AWW216 FOR A SCIENTIFIC COMMENTARY ON THIS ARTICLE: Multiple seizure foci, seizure propagation and epileptic spasms complicate presurgical seizure localization in tuberous sclerosis. Furthermore, controversy exists about the contribution of tubers, perituberal cortex and the underlying genetic abnormality to epileptogenesis. We aimed to determine the epileptogenic substrate in tuberous sclerosis by studying spatio-temporal patterns of seizure onset and propagation on intracranial EEG recordings in which multiple depth and surface electrodes sampled multiple tubers and perituberal cortex. Ten intracranial EEG recordings (seven extraoperative, three intraoperative) from 10 children with tuberous sclerosis were analysed. Notable thickening and signal abnormality in the centre of many tubers on magnetic resonance imaging led to tuber centres being recorded with depth electrodes. Spatially-meaningful bipolar montages were reformatted incorporating channels recording only from the tuber centre, tuber rim and perituberal cortex. Interictal epileptiform discharges and ictal rhythms were analysed visually for location, field, morphology, frequency, latency and temporal dispersion. Fifteen electroclinically distinct seizures were recorded in the 10 patients. Seizure onset was recorded in tubers in all 15 electroclinically distinct seizures; in 9/10 electroclinically distinct seizures recorded with optimal spatial sampling, seizure onset was recorded in the tuber centre, with or without involvement of the tuber rim but not perituberal cortex. Quantitative electroencephalography analysis by pairwise cross-correlation confirmed that the tuber centre led the tuber rim and perituberal cortex during interictal, preictal and ictal spike trains. Seizure propagation was observed in 10/15 electroclinically distinct seizures, being tuber-to-tuber in all. Seven of the 17 tubers showing seizure propagation activated an independent ictal rhythm, morphologically distinct from that seen in seizure onset region (intra-ictal activation). Of the total 48 tubers sampled, 16 exhibited seizure onset, 17 were involved in seizure propagation and 40 exhibited interictal epileptiform discharges, 33 independent and seven propagated. Seizure onsets were recorded in 16/33 tubers with independent interictal epileptiform discharges, but 0/7 tubers with only propagated epileptiform discharges or 0/8 tubers with no epileptiform discharges (P = 0.003). Seizure onsets were recorded from 4/7 tubers with and 0/10 tubers without intra-ictal activation (P = 0.015). Thus, focal seizures and interictal epileptiform discharges in tuberous sclerosis arise in the centre of epileptogenic tubers and propagate to the tuber rim, perituberal cortex and other epileptogenic tubers. Rhythmic interictal epileptiform discharges and intra-ictal activation of propagated ictal rhythms are potential biomarkers of epileptogenic tubers. Interictal and ictal EEG features of epileptogenic tubers have similarities to focal cortical dysplasia type II, consistent ...

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Effects of a common transcranial direct current stimulation (tDCS) protocol on motor evoked potentials found to be highly variable within individuals over 9 testing sessions

et al. 2016

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Transcranial direct current stimulation (tDCS) uses a weak electric current to modulate neuronal activity. A neurophysiologic outcome measure to demonstrate reliable tDCS modulation at the group level is transcranial magnetic stimulation engendered motor evoked potentials (MEPs). Here, we conduct a study testing the reliability of individual MEP response patterns following a common tDCS protocol. Fourteen participants (7m/7f) each underwent nine randomized sessions of 1 mA, 10 min tDCS (3 anode; 3 cathode; 3 sham) delivered using an M1/orbito-frontal electrode montage (sessions separated by an average of ~5.5 days). Fifteen MEPs were obtained prior to, immediately following and in 5 min intervals for 30 min following tDCS. TMS was delivered at 130 % resting motor threshold using neuronavigation to ensure consistent coil localization. A number of non-experimental variables were collected during each session. At the individual level, considerable variability was seen among different testing sessions. No participant demonstrated an excitatory response ≥20 % to all three anodal sessions, and no participant demonstrated an inhibitory response ≥20 % to all three cathodal sessions. Intra-class correlation revealed poor anodal and cathodal test-retest reliability [anode: ICC(2,1) = 0.062; cathode: ICC(2,1) = 0.055] and moderate sham test-retest reliability [ICC(2,1) = 0.433]. Results also revealed no significant effect of tDCS at the group level. Using this common protocol, we found the effects of tDCS on MEP amplitudes to be highly variable at the individual level. In addition, no significant effects of tDCS on MEP amplitude were found at the group level. Future studies should consider utilizing a more strict experimental protocol to potentially account for intra-individual response variations.

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Clinical, EEG, and quantitative MRI differences in pediatric frontal and temporal lobe epilepsy

Lawson

Cook²,

Vogrin³

et al. 2002

Neurology

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The clinical syndrome of FLE is clearly distinct from MTLE. The etiology of this disorder is unknown in the majority of cases despite extensive investigation. Because of a lack of a clearly defined etiology and frequent nonlateralizing EEG changes, few of these children are considered optimal surgical candidates. The demonstration of bilateral frontal cortical volume loss and bilateral EEG abnormalities suggests that FLE is a bilateral disease in a high proportion of patients. The outcome in those patients who were deemed surgical candidates was significantly worse than the MTLE cases.

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Cerebral and Cerebellar Volume Reduction in Children with Intractable Epilepsy

Lawson

Vogrin

Bleasel³

et al. 2000

Epilepsia

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Summary:Purpme: Adult epilepsy studies have demonstrated cerebral and cerebellar volume reduction beyond the epileptogenic zone, correlating this with an inferior surgical outcome. We determined whether brain volumes were reduced in childhood epilepsy and the significance of this.Methods: Cerebral, cerebellar, and hippocampal volumes were measured by quantitative magnetic resonance imaging on 112 children (ages 4-18) with epilepsy syndrome determined by video-EEG telemetry. Eighty-seven had partial epilepsy and 25 had generalized epilepsy or indeterminate syndrome. Normative volumes were obtained from 44 child controls from the community.Results: A significant reduction in cerebral (12.6%) and cerebellar (7.9%) volume was present in the epilepsy group compared with controls. Analysis of subgroups revealed that cerebral volume was significantly decreased in frontal lobe and nonlocalized partial epilepsies. The mean hippocampal ratio of 0.73 for mesial temporal lobe epilepsy was significantly less than for all other syndromes and controls. There was no difference in the rate of hippocampal volume reduction between syndromes. There was a significant correlation between IQ and cerebral and cerebellar volume, but not duration or age of onset of epilepsy.Conclusions: Cerebral and cerebellar volume reduction is common in intractable epilepsy syndromes of childhood. These cross-sectional data suggest that brain volume reduction is present at epilepsy onset and is not a result of intractable seizures. Hippocampal asymmetry is more sensitive than volume reduction as a marker for mesial temporal lobe epilepsy, but neither measure is specific. Key Words: Cerebral-CerebellarEpilepsy-Reduction-Magnetic resonance imaging.Recent magnetic resonance imaging (MRI) studies have provided new insights into the question of loss of cerebral and cerebellar volume in patients with epilepsy. Quantitative MRI studies in adults with epilepsy have found loss of cerebral volume beyond the epileptogenic zone (1-3). Sisodiya et al. (1) demonstrated extrahippocampal volume loss in mesial temporal lobe epilepsy (MTLE) and correlated this with an inferior surgical outcome. Cerebellar atrophy is common in intractable epilepsy; the cause is still debated (4), but it has been correlated with a poorer surgical prognosis ( 5 ) and a lower threshold to drug side effects (6). Pediatric MRI studies have not addressed these issues. We aimed to determine whether cerebral and cerebellar volume reduction was evident in intractable childhood epilepsy syndromes, with potential significance for pathophysiology and treatment.

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Cerebral cortex: An MRI-based study of volume and variance with age and sex

Carne¹,

Vogrin²,

Litewka³

et al. 2006

Journal of Clinical Neuroscience

103

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Patient-specific bivariate-synchrony-based seizure prediction for short prediction horizons

et al. 2010

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Simon Vogrin

Interictal and ictal source localization for epilepsy surgery using high-density EEG with MEG: a prospective long-term study

Amygdala volumetry in "imaging-negative" temporal lobe epilepsy

Centre of epileptogenic tubers generate and propagate seizures in tuberous sclerosis

Effects of a common transcranial direct current stimulation (tDCS) protocol on motor evoked potentials found to be highly variable within individuals over 9 testing sessions

Clinical, EEG, and quantitative MRI differences in pediatric frontal and temporal lobe epilepsy

Cerebral and Cerebellar Volume Reduction in Children with Intractable Epilepsy

Cerebral cortex: An MRI-based study of volume and variance with age and sex

Patient-specific bivariate-synchrony-based seizure prediction for short prediction horizons

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