The Cause of the Imbalance in the Neuronal Network Leading to Seizure Activity Can Be Predicted by the Electrographic Pattern of the Seizure Onset

Bragin, Anatol; Azizyan, Avetis; Almajano, Joyel; Engel, Jerome

doi:10.1523/jneurosci.5309-08.2009

Cited by 40 publications

(36 citation statements)

References 42 publications

(46 reference statements)

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“…As in our previous studies involving hippocampal picrotoxin infusions , observations of the rats following infusions and between infusion days, did not reveal infusion-induced motor convulsions or more subtle indicators of seizure development, such as facial twitches, tremor, movement arrest or wet-dog shakes, which may result from higher doses of GABA antagonists (Bragin et al 2009). Furthermore, our electrophysiological studies did not indicate electrophysiological seizure signs (see below).…”

Section: Microinfusions For Behavioural Studiessupporting

confidence: 59%

Hippocampal Neural Disinhibition Causes Attentional and Memory Deficits

et al. 2016

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Section: Microinfusions For Behavioural Studiessupporting

confidence: 59%

Hippocampal Neural Disinhibition Causes Attentional and Memory Deficits

et al. 2016

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“…3). Excitatory field events similar to PID have been detected just before seizures in animal models 6,8,15,43,44 . PID do not involve barrages of hyperpolarizing synaptic events which may act as an inhibitory restraint, to protect against the spread of seizure-like activities 45 .…”

Section: Discussionmentioning

confidence: 94%

“…3b). The amplitude of stable PID (185±106 μV, 95% CI: , n=66 events from 8 slices) was significantly higher than that of simultaneous IID (49±24 μV, 95% CI: [42][43][44][45][46][47][48][49][50][51][52][53][54][55], n=66 events from 8 slices) (Wilcoxon test, Z(7)=3.99, P<0.01) (Fig. 3e) Fig.…”

Section: Pid Emerge During the Transition To The Ictal Statementioning

confidence: 99%

Glutamatergic pre-ictal discharges emerge at the transition to seizure in human epilepsy

et al. 2011

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Mechanisms involved in the transition to an epileptic seizure remain unclear. We studied this question in tissue slices from human subjects with mesial temporal lobe epilepsies. Ictal-like discharges were induced in the subiculum by increasing excitability together with an alkalinization or low Mg 2+ . During the transition, distinct pre-ictal discharges emerged concurrently with interictal events. Intracranial recordings from the mesial temporal cortex of epileptic subjects revealed similar discharges before seizures were restricted to seizure onset sites. In vitro, pre-ictal events spread faster, have a larger amplitude and a distinct initiation site than interictal discharges. They depend on glutamatergic mechanisms and are preceded by pyramidal cell firing, while interneuron firing precedes interictal events which depend on both glutamatergic and depolarizing GABAergic transmission. Once established, recurrence of these pre-ictal discharges triggers seizures. Thus the subiculum supports seizure generation and the transition to seizure involves a novel, emergent glutamatergic population activity.3

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“…3 LVF and HYP seizures may mirror the activity of distinct limbic structures. 4 Accordingly, Velasco et al 2 have reported that LVF seizures rest on the activity of hippocampal and parahippocampal networks, whereas HYP seizures originate from local circuits in the hippocampal formation. In addition, TLE patients presenting with HYP seizures have histopathological patterns of atrophy that are consistent with hippocampal sclerosis, whereas LVF seizures are linked to a more diffuse and bilateral distribution of atrophy.…”

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confidence: 99%

Activation of specific neuronal networks leads to different seizure onset types

Shiri

Manseau

Lévesque

et al. 2016

Annals of Neurology

100

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Objective-Ictal events occurring in temporal lobe epilepsy patients and in experimental models mimicking this neurological disorder can be classified, based on their onset pattern, into lowvoltage, fast versus hypersynchronous onset seizures. It has been suggested that the low-voltage, fast onset pattern is mainly contributed by interneuronal (γ-aminobutyric acidergic) signaling, whereas the hypersynchronous onset involves the activation of principal (glutamatergic) cells.Methods-Here, we tested this hypothesis using the optogenetic control of parvalbumin-positive or somatostatin-positive interneurons and of calmodulin-dependent, protein kinase-positive, principal cells in the mouse entorhinal cortex in the in vitro 4-aminopyridine model of epileptiform synchronization.Results-We found that during 4-aminopyridine application, both spontaneous seizure-like events and those induced by optogenetic activation of interneurons displayed low-voltage, fast onset patterns that were associated with a higher occurrence of ripples than of fast ripples. In contrast, seizures induced by the optogenetic activation of principal cells had a hypersynchronous onset pattern with fast ripple rates that were higher than those of ripples.Interpretation-Our results firmly establish that under a similar experimental condition (ie, bath application of 4-aminopyridine), the initiation of low-voltage, fast and of hypersynchronous onset seizures in the entorhinal cortex depends on the preponderant involvement of interneuronal and principal cell networks, respectively.Seizures in patients presenting with temporal lobe epilepsy (TLE) are mainly characterized by 2 distinct electrographic onset patterns, defined as low-voltage, fast (LVF) and hypersynchronous (HYP). 1,2 LVF seizures are characterized at onset by the occurrence of a sentinel spike followed by low-amplitude, high-frequency activity, whereas the initiation of Recently, the analysis of high-frequency oscillations (HFOs; ripples: 80-200Hz, fast ripples: 250-500Hz) during spontaneous HYP and LVF seizures in the pilocarpine and kainic acid model of TLE has suggested that these 2 seizure onset patterns may rely on distinct mechanisms of initiation. LVF seizures were found to be mainly associated with HFOs in the ripple frequency range, thus suggesting the predominant involvement of interneuronal (inhibitory) networks; in contrast, HYP seizures were mostly accompanied by fast ripple occurrence, thus highlighting the potential role of principal (glutamatergic) networks. 6,7 Evidence obtained to date suggests that pathologic HFOs in the ripple band should represent population inhibitory postsynaptic potentials generated by principal neurons entrained by synchronously active interneuron networks, whereas those in the fast ripple band reflect the synchronous firing of abnormally active principal cells, and thus are not dependent on inhibitory processes. [8][9][10] It has been demonstrated that 4-aminopyridine (4AP) application induces LVF onset discharges in several limbic and para...

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The Cause of the Imbalance in the Neuronal Network Leading to Seizure Activity Can Be Predicted by the Electrographic Pattern of the Seizure Onset

Cited by 40 publications

References 42 publications

Hippocampal Neural Disinhibition Causes Attentional and Memory Deficits

Hippocampal Neural Disinhibition Causes Attentional and Memory Deficits

Glutamatergic pre-ictal discharges emerge at the transition to seizure in human epilepsy

Activation of specific neuronal networks leads to different seizure onset types

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