Epileptogenesis

About: Epileptogenesis is a research topic. Over the lifetime, 4218 publications have been published within this topic receiving 170809 citations.

The progression of electrophysiologic abnormalities during epileptogenesis after experimental traumatic brain injury.

Abstract: SummaryObjective Posttraumatic epilepsy (PTE) accounts for 20% of acquired epilepsies. Experimental models are important for studying epileptogenesis. We previously reported that repetitive high-frequency oscillations with spikes (rHFOSs) occur early after lateral fluid percussion injury (FPI) and may be a biomarker for PTE. The objective of this study was to use multiple electrodes in rat hippocampal and neocortical regions to describe the long-term electroencephalographic and behavioral evolution of rHFOSs and epileptic seizures after traumatic brain injury (TBI). Methods Adult male rats underwent mild, moderate, or severe FPI or sham injury followed by video–electroencephalography (EEG) recordings with a combination of 16 neocortical and hippocampal electrodes at an early, intermediate, or late time-point after injury, up to 52 weeks. Recordings were analyzed for the presence of rHFOSs and seizures. Results Analysis was done on 28 rats with FPI and 7 shams. Perilesional rHFOSs were recorded in significantly more rats after severe (70.3%) than mild (20%) injury or shams (14.3%). Frequency of occurrence was significantly highest in the early (10.8/h) versus late group (3.2/h). Late focal seizures originating from the same electrodes were recorded in significantly more rats in the late (87.5%) versus early period (22.2%), occurring almost exclusively in injured rats. Seizure duration increased significantly over time, averaging 19 s at the beginning of the early period and 27 s at the end of the late period. Seizure frequency also increased significantly over time, from 4.4 per week in the early group to 26.4 per week in the late group. Rarely, rats displayed early seizures or generalized seizures. Significance FPI results in early rHFOSs and later spontaneous focal seizures arising from peri-lesional neocortex, supporting its use as a model for PTE. Epilepsy severity increased over time and was related to injury severity. The association between early rHFOSs and later focal seizures suggests that rHFOSs may be a potential noninvasive biomarker of PTE.

Localized overexpression of FGF-2 and BDNF in hippocampus reduces mossy fiber sprouting and spontaneous seizures up to 4 weeks after pilocarpine-induced status epilepticus

Abstract: Summary Purpose: We have recently reported that viral vector–mediated supplementation of fibroblast growth factor-2 (FGF-2) and brain-derived neurotrophic factor (BDNF) in a lesioned, epileptogenic rat hippocampus limits neuronal damage, favors neurogenesis, and reduces spontaneous recurrent seizures. To test if this treatment can also prevent hippocampal circuit reorganization, we examined here its effect on mossy fiber sprouting, the best studied form of axonal plasticity in epilepsy. Methods: A herpes-based vector expressing FGF-2 and BDNF was injected into the rat hippocampus 3 days after an epileptogenic insult (pilocarpine-induced status epilepticus). Continuous video–electroencephalography (EEG) monitoring was initiated 7 days after status epilepticus, and animals were sacrificed at 28 days for analysis of cell loss (measured using NeuN immunofluorescence) and mossy fiber sprouting (measured using dynorphin A immunohistochemistry). Key Findings: The vector expressing FGF-2 and BDNF decreased both mossy fiber sprouting and the frequency and severity of spontaneous seizures. The effect on sprouting correlated strictly with the cell loss in the terminal fields of physiologic mossy fiber innervation (mossy cells in the dentate gyrus hilus and CA3 pyramidal neurons). Significance: These data suggest that the supplementation of FGF-2 and BDNF in an epileptogenic hippocampus may prevent epileptogenesis by decreasing neuronal loss and mossy fiber sprouting, that is, reducing some forms of circuit reorganization.

Advances in Understanding the Process of Epileptogenesis Based on Patient Material: What Can the Patient Tell Us?

Abstract: Summary: Many different types of epileptic seizures and epileptic syndromes exist. The process of epileptogenesis and the progressive nature of epilepsy, however, can most easily be investigated in the acquired epilepsies, in which a brain insult presumably gives rise to changes in neuronal systems that ultimately become capable of generating spontaneous ictal events. Invasive in vivo and in vitro research can be carried out in patients with acquired epileptogenic lesions in the course of epilepsy surgery; however, such studies are possible only for those epileptic conditions that can be treated surgically, and can be used only to examine an end stage of the epileptogenic process. Consequently, experimental animal models of human epileptic conditions are still required to study mechanisms by which specific cerebral insults initiate the epileptogenic process and the progression of an epileptic disturbance. Most current parallel human/animal invasive research has been focused on temporal lobe epilepsy, and particularly that form associated with hippocampal sclerosis, the most common human epileptogenic lesion. Studies indicate that epileptogenesis in this condition is initiated by specific types of cell loss and neuronal reorganization, which results not only in enhanced excitation, but also in enhanced inhibition, predisposing to hypersynchronization. Even within this single, well-studied epileptic disorder, evidence is found for more than one type of ictal onset, and individual seizures can demonstrate a transition from one ictal mechanism to another. Recent in vivo and in vitro parallel, reiterative investigations in patients with mesial temporal lobe epilepsy, and in rats with intrahippocampal kainate-induced hippocampal seizures, have revealed the presence of interictal epileptiform events, termed “fast ripples,” which appear to be unique in tissue capable of generating spontaneous seizures. Pursuit of the fundamental mechanisms underlying these abnormalities should elucidate the neurobiologic basis of epileptogenicity in this disorder. Furthermore, if these events are markers for epileptogenicity, they may have clinical value for diagnosis and pharmacologic, as well as surgical, treatment. Further research is needed to determine if these observations are relevant to other types of epilepsies.

Seizures and neuronal damage induced in the rat by activation of group I metabotropic glutamate receptors with their selective agonist 3,5‐dihydroxyphenylglycine

Abstract: While it is well documented that the overactivation of ionotropic glutamate receptors leads to seizures and excitotoxic injury, little is known about the role of metabotropic glutamate receptors (mGluRs) in epileptogenesis and neuronal injury. Intracerebroventricular (i.c.v.) infusion of the group I mGluR specific agonist (R,S)-3,5-dihydroxyphenylglycine (3,5-DHPG) (1.5 micromol) to conscious rats produced severe and delayed seizures (onset at 4 hr) in 70% of the animals. The i.c.v. infusion of the group I mGluR non-selective agonist 1S,3R-1-aminocyclopentane-1,3-dicarboxylic acid (1S,3R-ACPD) (2 micromol) produced a similar rate of severe seizures, but with an early onset (0.6 hr). The analysis of motor activity showed that 3,5-DHPG elicited higher central stimulatory action than did 1S,3R-ACPD. Histopathological analysis of the hippocampus showed that 3,5-DHPG produced severe neuronal damage mainly in the CA1 pyramidal neurons and, to a lesser extent, in the CA3. Although 1S,3R-ACPD infusion also induced a slight injury of the CA1 and CA3 pyramidal neurons, damage was greater in the CA4 and dentate gyrus cells. In conclusion, the in vivo activation of group I mGluRs with the selective agonist 3,5-DHPG produces hyperexcitatory effects that lead to seizures and neuronal damage, these effects being more severe than those observed after infusion of the non-selective agonist 1S,3R-ACPD.