Barrel cortex development lacks a key stage of hyperconnectivity from deep to superficial layers in a rat model of Absence Epilepsy.

During development of the sensory cortex, the ascending innervation from deep to upper layers provides a temporary scaffold for the construction of other circuits that remain at adulthood. Whether an alteration in this sequence leads to brain dysfunction in neuro-developmental diseases remains unknown. Using functional approaches in a genetic model of Absence Epilepsy (GAERS), we investigated in barrel cortex, the site of seizure initiation, the maturation of excitatory and inhibitory innervations onto layer 2/3 pyramidal neurons and cell organization into neuronal assemblies. We found that cortical development in GAERS lacks the early surge of connections originating from deep layers observed at the end of the second postnatal week in normal rats and the concomitant structuring into multiple assemblies. Later on, at seizure onset (1 month old), excitatory neurons are hyper-excitable in GAERS when compared to Wistar rats. These findings suggest that early defects in the development of connectivity could promote this typical epileptic feature and/or its comorbidities.

Early alterations of the neuronal network processing whisker-related sensory signal during absence epileptogenesis.

OBJECTIVE: Epileptogenesis is the particular process during which the epileptic network builds up progressively before the onset of the first seizures. Whether physiological functions are impacted by this development of epilepsy remains unclear. To explore this question, we used Genetic Absence Epilepsy Rats From Strasbourg (GAERS), in which spike-and-wave discharges are initiated in the whisker primary somatosensory cortex (wS1) and first occur during cortical maturation. We studied the development of both the epileptic and the physiological wS1 circuits during cortical maturation to understand the interactions between them and the consequences for the animals' behavior. METHODS: In sedated and immobilized rat pups, we recorded in vivo epileptic and whisker sensory evoked activities across the wS1 and thalamus using multicontact electrodes. We compared sensory evoked potentials based on current source density analysis. We then analyzed the multiunit activities evoked by whisker stimulation in GAERS and control rats. Finally, we evaluated behavioral performance dependent on the functionality of the wS1 cortex using the gap-crossing task. RESULTS: We showed that the epileptic circuit changed during the epileptogenesis period in GAERS, by involving different cortical layers of wS1. Neuronal activities evoked by whisker stimulation were reduced in the wS1 cortex at P15 and P30 in GAERS but increased in the ventral posteromedial nucleus of the thalamus at P15 and in the posterior medial nucleus at P30, when compared to control rats. Finally, we observed lower performance in GAERS versus controls, at both P15 and P30, in a whisker-mediated behavioral task. SIGNIFICANCE: Our data show that the functionality of wS1 cortex and thalamus is altered early during absence epileptogenesis in GAERS and then evolves before spike-and-wave discharges are fully expressed. They suggest that the development of the pathological circuit disturbs the physiological one and may be responsible for both the emergence of seizures and associated comorbidities.

An on demand macaque model of mesial temporal lobe seizures induced by unilateral intra hippocampal injection of penicillin.

PURPOSE: Our objective was to propose a new on demand non-human primate model of mesial temporal lobe seizures suitable for pre-clinical innovative therapeutic research. METHODS: Five macaques were stereotaxically implanted unilaterally with a deep recording electrode in the hippocampus. For each experiment, penicillin was injected into the hippocampus and animals were monitored during five consecutive hours. A total of 12-27 experiments with a mean cumulative dose of 162644 ±â€¯70190 UI of penicillin have been performed per animal Injections were repeated at least once a week over a period of 98-276 days. The time-course of electro-clinical seizures and the response to diazepam have been quantified from, respectively, 84 and 11 experiments randomly selected. To evaluate brain injury produced by several penicillin injections and to characterize the changes occurring into the hippocampus, we performed an histological analysis, including neuronal nuclei and glial fibrillary acid protein immunostaining and electron microscopy. RESULTS: After each penicillin injection, we observed that the electro-clinical characteristics were reproducible among non-human primates and experiments. Seizures duration was stable (29.60 ±â€¯6.62 s) and the frequency of seizures reached a plateau with about 3 seizures/20 min during 180 min and that could be useful to test new treatments. Diazepam did not modify the course of the seizures. Hippocampal sclerosis was found similar to that encountered in epileptic patients with a neuronal loss and a glial cells proliferation. Electron microscopy analysis of CA1 revealed a decreased number of synapses and a large amount of glial fibrillary filaments in the injected hippocampus. Interestingly, this on-demand model of seizure, turned into a chronic model with spontaneous occurrence of seizures after a cumulative amount ranging from 119 to 145 KIU of penicillin injected. CONCLUSION: The present study shows that an on-demand model of mesial temporal lobe seizure can be developed by intra-hippocampal injection of penicillin. The seizures are reproducible, stable and resistant to diazepam. Brain damages are confined to the hippocampus with similar features to that found in human mesial temporal lobe epilepsy. This model reproduces the symptomatogenic and the irritative zone usually seen in human MTLE, with the additional advantage of having a clear delineation of the epileptogenic zone. However, the mechanism of actions of the penicillin as a proconvulsant agent does not replicate all of the much more complex physiological and cellular mechanisms that are involved in human epilepsy and represent a limitation of our study that one must be aware of.

Building Up Absence Seizures in the Somatosensory Cortex: From Network to Cellular Epileptogenic Processes.

The epileptogenic processes leading to recurrent seizures in Genetic Epilepsies are largely unknown. Using the Genetic Absence Epilepsy Rat from Strasbourg, we investigated in vivo the network and single neuron mechanisms responsible for the early emergence of epileptic activity. Local field potential recordings in the primary somatosensory cortex (SoCx), from the second post-natal week to adulthood, showed that immature cortical discharges progressively evolved into typical spike-and-wave discharges following a 3-step maturation process. Intracellular recordings from deep-layer SoCx neurons revealed that this maturation was associated with an age-dependent increase in cortical neurons intrinsic excitability, combining a membrane depolarization and an enhancement of spontaneous firing rate with a leftward shift in their input-output relation. These cellular changes were accompanied by a progressive increase in the strength of the local synaptic activity associated with a growing propensity of neurons to generate synchronized oscillations. Chronic anti-absence treatment before the occurrence of mature cortical discharges did not alter epileptogenesis or the drug efficiency at adulthood. These findings demonstrate that recurrent absence seizures originate from the progressive acquisition of pro-ictogenic properties in SoCx neurons and networks during the post-natal period and that these processes cannot be interrupted by early anti-absence treatment.

Seizure expression, behavior, and brain morphology differences in colonies of Genetic Absence Epilepsy Rats from Strasbourg.

OBJECTIVE: Originally derived from a Wistar rat strain, a proportion of which displayed spontaneous absence-type seizures, Genetic Absence Epilepsy Rats from Strasbourg (GAERS) represent the most widely utilized animal model of genetic generalized epilepsy. Here we compare the seizure, behavioral, and brain morphometric characteristics of four main GAERS colonies that are being actively studied internationally: two from Melbourne (MELB and STRAS-MELB), one from Grenoble (GREN), and one from Istanbul (ISTAN). METHODS: Electroencephalography (EEG) recordings, behavioral examinations, and structural magnetic resonance imaging (MRI) studies were conducted on GAERS and Non-Epileptic Control (NEC) rats to assess and compare the following: (1) characteristics of spike-and-wave discharges, (2) anxiety-like and depressive-like behaviors, and (3) MRI brain morphology of regions of interest. RESULTS: Seizure characteristics varied between the colonies, with MELB GAERS exhibiting the least severe epilepsy phenotype with respect to seizure frequency, and GREN GAERS exhibiting four times more seizures than MELB. MELB and STRAS-MELB colonies both displayed consistent anxiety and depressive-like behaviors relative to NEC. MELB and GREN GAERS showed similar changes in brain morphology, including increased whole brain volume and increased somatosensory cortical width. A previously identified mutation in the Cacna1h gene controlling the CaV 3.2 T-type calcium channel (R1584P) was present in all four GAERS colonies, but absent in all NEC rats. SIGNIFICANCE: This study demonstrates differences in epilepsy severity between GAERS colonies that were derived from the same original colony in Strasbourg. This multi-institute study highlights the potential impact of environmental conditions and/or genetic drift on the severity of epileptic and behavioral phenotypes in rodent models of epilepsy.

Animal models to study aetiopathology of epilepsy: what are the features to model?

In order to understand the physiopathology of epilepsies and develop antiepileptic drugs, animal models have been developed. These models appear to be valuable predictors of treatment efficacy; however, several of the currently used models remain questionable and probably inappropriate for the search for new treatments, in particular for epilepsies that cannot be treated by current antiepileptic drugs. In the present review, we report the results of a recent survey conducted by neurologists in charge of an epilepsy programme based at different hospitals in France. The 36 experts were questioned, via the internet, on the most critical features of four prototypic forms of epilepsy (idiopathic generalised epilepsies with convulsive seizures, absence epilepsy, focal epilepsy associated with dysplasia, and focal epilepsy associated with hippocampal sclerosis) that should be taken into account with regards to the relevance of animal models of epilepsy. Their answers suggest that most current models for focal epilepsies associated with either dysplasia or hippocampal sclerosis do not address the most relevant features. The models currently used in mice and rats are discussed in light of the data obtained in our survey.

Specific in vivo staining of astrocytes in the whole brain after intravenous injection of sulforhodamine dyes.

Fluorescent staining of astrocytes without damaging or interfering with normal brain functions is essential for intravital microscopy studies. Current methods involved either transgenic mice or local intracerebral injection of sulforhodamine 101. Transgenic rat models rarely exist, and in mice, a backcross with GFAP transgenic mice may be difficult. Local injections of fluorescent dyes are invasive. Here, we propose a non-invasive, specific and ubiquitous method to stain astrocytes in vivo. This method is based on iv injection of sulforhodamine dyes and is applicable on rats and mice from postnatal age to adulthood. The astrocytes staining obtained after iv injection was maintained for nearly half a day and showed no adverse reaction on astrocytic calcium signals or electroencephalographic recordings in vivo. The high contrast of the staining facilitates the image processing and allows to quantify 3D morphological parameters of the astrocytes and to characterize their network. Our method may become a reference for in vivo staining of the whole astrocytes population in animal models of neurological disorders.

Identifying neural drivers with functional MRI: an electrophysiological validation.

Whether functional magnetic resonance imaging (fMRI) allows the identification of neural drivers remains an open question of particular importance to refine physiological and neuropsychological models of the brain, and/or to understand neurophysiopathology. Here, in a rat model of absence epilepsy showing spontaneous spike-and-wave discharges originating from the first somatosensory cortex (S1BF), we performed simultaneous electroencephalographic (EEG) and fMRI measurements, and subsequent intracerebral EEG (iEEG) recordings in regions strongly activated in fMRI (S1BF, thalamus, and striatum). fMRI connectivity was determined from fMRI time series directly and from hidden state variables using a measure of Granger causality and Dynamic Causal Modelling that relates synaptic activity to fMRI. fMRI connectivity was compared to directed functional coupling estimated from iEEG using asymmetry in generalised synchronisation metrics. The neural driver of spike-and-wave discharges was estimated in S1BF from iEEG, and from fMRI only when hemodynamic effects were explicitly removed. Functional connectivity analysis applied directly on fMRI signals failed because hemodynamics varied between regions, rendering temporal precedence irrelevant. This paper provides the first experimental substantiation of the theoretical possibility to improve interregional coupling estimation from hidden neural states of fMRI. As such, it has important implications for future studies on brain connectivity using functional neuroimaging.

Deep layer somatosensory cortical neurons initiate spike-and-wave discharges in a genetic model of absence seizures.

Typical absence has long been considered as the prototypic form of generalized nonconvulsive epileptic seizures. Recent investigations in patients and animal models suggest that absence seizures could originate from restricted regions of the cerebral cortex. However, the cellular and local network processes of seizure initiation remain unknown. Here, we show that absence seizures in Genetic Absence Epilepsy Rats from Strasbourg, a well established genetic model of this disease, arise from the facial somatosensory cortex. Using in vivo intracellular recordings, we found that epileptic discharges are initiated in layer 5/6 neurons of this cortical region. These neurons, which show a distinctive hyperactivity associated with a membrane depolarization, lead the firing of distant cortical cells during the epileptic discharge. Consistent with their ictogenic properties, neurons from this "focus" exhibit interictal and preictal oscillations that are converted into epileptic pattern. These results confirm and extend the "focal hypothesis" of absence epilepsy and provide a cellular scenario for the initiation and generalization of absence seizures.