Exaggeration of epileptic-like patterns by nicotine receptor activation during the GABA withdrawal syndrome.

To understand how nicotinic cholinergic receptors may participate in epileptic seizures, we tested the effects of nicotine and of the competitive nicotinic antagonists dihydro-beta-erythroidine and alpha-bungarotoxin on synaptic paroxysmal depolarization shifts (PDSs) and intrinsic bursts of action potentials recorded in slices from rats presenting a cortical status epilepticus. This model named GABA-withdrawal syndrome (GWS) appears consecutive to the interruption of a prolonged intracortical GABA infusion. Effects of both nicotinic antagonists suggest a distinct involvement of alpha4-beta2 and alpha7 subunits in shaping individual PDSs and patterning repetitive bursts.

Muscarinic depression of synaptic transmission in the epileptogenic GABA withdrawal syndrome focus.

The GABA withdrawal syndrome (GWS) is a model of local status epilepticus consecutive to the interruption of a prolonged GABA infusion into the rat somatomotor cortex. Bursting patterns in slices from GWS rats include intrinsic bursts of action potentials (APs) induced by intracellular depolarizing current injection and/or paroxysmal depolarization shifts (PDSs) induced by white matter stimulation. Possible changes in the effects of cholinergic drugs after in vivo induction of GWS were investigated on bursting cells (n = 30) intracellularly recorded in neocortical slices.

The GABA-withdrawal syndrome: a model of local status epilepticus.

The GABA-withdrawal syndrome (GWS) is a model of local status epilepticus following the interruption of a chronic GABA infusion into the rat somatomotor cortex. GWS is characterized by focal epileptic electroencephalographic discharges and associated contralateral myoclonus. In neocortical slices obtained from GWS rats, most neurons recorded in the GABA-infused area are pyramidal neurons presenting bursting properties.

A potassium current controls burst termination in rat neocortical neurons after GABA withdrawal.

Bursting activities were investigated under conditions of reduced outward K+ currents in neocortical slices obtained from rats presenting the gamma-aminobutyric acid (GABA)-withdrawal syndrome (GWS), a focal epilepsy consecutive to the interruption of a chronic intracortical GABA infusion into the somatomotor cortex. These bursts were induced by intracellular depolarizing current injection and/or by white matter stimulation. Tetraethylammonium (TEA) at doses which did not change input resistance, spike duration or first interspike time interval abolished the burst terminating process and induced plateau-like potentials (up to 500 ms) which were tetrodotoxin-resistant and blocked by Ca2+ antagonists Cd2+ and Co2+.

Reflex epilepsy in the Papio-papio baboon, particularly photosensitive epilepsy.

Papio-papio baboons may present two types of reflex paroxysmal manifestations: --Myoclonia and generalized seizures are induced by intermittent light stimulation in predisposed animals; this photosensitive epilepsy resembles that observed in some human patients; it involves mainly the cerebral cortex during myoclonia which are accompanied by EEG paroxysmal discharges, and the mesencephalic reticular formation during seizures; --Myoclonia of a different type, never accompanied by EEG paroxysmal discharged and never evolving into seizures, may occur during movement or agitation of predisposed animals; these myoclonia are considered "non-epileptic" since they do not involve the cerebral cortex but probably the lower brain stem; they resemble that observed in startle disease or in some human degenerative disorders. The paper demonstrates that these manifestations constitute two different entities with clinical and electrophysiological characteristics as well as pharmacological reactivities completely different one from the other. Their "epileptic" or "non-epileptic" nature is discussed.

High expression of noradrenaline, choline acetyltransferase and glial fibrillary acidic protein in the epileptic focus consecutive to GABA withdrawal. An immunocytochemical study.

Interruption of a chronic GABA infusion into the rat somatosensory cortex induces the appearance of focal epileptic manifestations, known as the 'GABA withdrawal syndrome' (GWS). The aim of the present study was to determine, by immunocytochemistry, if neurotransmitters other than GABA are involved in GWS, namely: noradrenaline (NA), serotonin, choline acetyltransferase (CAT), cholecystokinin, neuropeptide Y, somatostatin and glial fibrillary acid protein (GFAP). Immunocytochemical data were compared in three animal groups: GABA-, saline- and L-aspartate (L-Asp)-infused rats.

Noradrenaline mediates paradoxical effects on rat neocortical neurons after GABA withdrawal.

1. The aim of the present study was to determine the role of noradrenergic neurotransmission in neuronal activities intracellularly recorded in neocortical slices obtained from rats presenting the gamma-aminobutyric acid (GABA) withdrawal syndrome (GWS), a focal epilepsy consecutive to the interruption of a chronic intracortical GABA infusion into the somatomotor cortex. Neurons recorded in the epileptic focus area (n = 52) were bursting or nonbursting cells.

The cholinergic system-dependent myoclonus of the baboon Papio papio is a reticular reflex myoclonus.

Neurophysiological studies were performed on four Papio papio baboons presenting with nonepileptic myoclonus (a startle response resembling stimulus-sensitive jerk). Investigations of the EEG, back-averaged EEG, and somatosensory evoked potentials revealed the absence of cortical correlates preceding the jerks, and exclusion of cerebral cortex involvement. No long-latency reflexes could be recorded in these animals.

Burst generation in neocortical neurons after GABA withdrawal in the rat.

1. gamma-Aminobutyric acid (GABA) withdrawal syndrome (GWS) represents a particular model of focal epilepsy consecutive to the interruption of a chronic intracortical GABA infusion and is characterized by the appearance of focal epileptic electroencephalographic (EEG) discharges and localized clinical signs on withdrawal of GABA. Effects of Ca2+ channel blockers and N-methyl-D-aspartate (NMDA) antagonists were evaluated in living rats presenting a GWS after interruption of a 5-day GABA infusion into the somatomotor cortex and in neocortical slices obtained from such rats.

Influence of cholinergic system on myoclonus in myoclonic epilepsies.

The effect of two drugs upon multifocal myoclonic jerks was evaluated. The drugs influence the central cholinergic system in opposite ways. Eight patients with progressive and nonprogressive myoclonic epilepsy were tested.

Drugs influencing the GABAergic neurotransmission have no effect on the non-epileptic myoclonus of baboons.

In Papio papio baboons benzodiazepines can facilitate the appearance of a naturally occurring non-epileptic myoclonus, suggesting a possible role of GABAergic transmission in their physiopathology. Nevertheless, as this myoclonus is blocked by physostigmine, the effect of benzodiazepines is probably due to their indirect action on the cholinergic system. Therefore, in this study, we report the effects on the non-epileptic myoclonus of drugs influencing GABAergic transmission.

Metabolic anatomy of the focal epilepsy produced by cessation of chronic intracortical GABA infusion in the rat.

Cessation of chronic (5 days), unilateral infusion of GABA into the somatomotor cortex of rats induces focal epileptic spikes which remain limited to the infused site and never evolve into generalized seizures. We have considered this finding as a new model of focal epilepsy and named it "GABA withdrawal syndrome". In the present study, we have measured local cerebral glucose utilization in order to map the cortical and subcortical regions involved in the GABA withdrawal syndrome.

Electroencephalographic study of the GABA-withdrawal syndrome in rats.

The spatial and temporal EEG features of the epileptogenic syndrome induced by cessation of chronic intracortical GABA infusion in normal rats are described. In the initial stages, the paroxysmal discharges (PDs) induced by withdrawal from unilateral GABA application may appear either unilaterally or bilaterally, although with greater amplitude on the infused side. PDs are transitorily accompanied by behavioral signs of distal myoclonus of the body territory corresponding to the infused area (contralateral hindlimb).

[Value of the monkey Papio papio for the study of epilepsy].

The baboon Papio papio is the only animal model showing a natural photosensitive epilepsy very similar to that observed in some human epileptic patients. In the baboon, intermittent light stimulation (ILS) induces bilateral and synchronous myoclonic twitches which are associated with paroxysmal discharges (PDs) predominating in the frontal cortex, and can be followed by generalized tonic-clonic seizures. We were able to demonstrate the motor cortical origin of all these manifestations since neuronal generators responsible for paroxysmal discharges are localized there and are activated by visual afferents from the occipital lobe.

Unexpected potentializing effect of a tacrine derivative (9-amino-7-methoxy-1,2,3,4 tetrahydroacridine) upon the non-epileptic myoclonus in baboons Papio papio.

1. The influence of 7-methoxytacrine (7-MEOTA) on the non epileptic myoclonus of the Papio papio baboon was studied in 5 animals. 2.

Relationship between tolerance to GABAA agonist and bursting properties in neocortical neurons during GABA-withdrawal syndrome.

The interruption of intracortical, chronic GABA infusion is known to give rise to 'GABA withdrawal syndrome' (GWS) consisting of electroencephalographic paroxysmal focal activities, associated with behavioral epileptic signs. Neocortical slices were obtained from rats presenting the GWS (GWS slices), and intracellular recordings were performed in the vicinity of the gamma-aminobutyric acid (GABA)-infused site. Electrical stimulation of the underlying white matter induced paroxysmal depolarization shifts (PDSs) in virtually all neurons.

Phosphorylated thiamine derivatives and cortical activity in the baboon Papio papio: effect of intermittent light stimulation.

The effect of intermittent light stimulation (ILS) on the distribution of thiamine derivatives in three brain areas (occipital, motor, and premotor) was compared in photosensitive and nonphotosensitive baboons. ILS induces paroxysmal discharges in the motor and premotor areas of photosensitive animals only. In baboons submitted to ILS, thiamine triphosphate (TTP) decreases in both photosensitive and nonphotosensitive animals; thiamine monophosphate (TMP) increases in photosensitive animals, which present ILS-induced paroxysmal discharges, whereas it is unaffected in nonphotosensitive animals.

Effects of localized, chronic GABA infusions into different cortical areas of the photosensitive baboon, Papio papio.

The effects of chronic (7 days) intracortical GABA infusions were investigated in both naturally photosensitive and non-photosensitive baboons. Bilateral and unilateral infusions into motor and occipital regions blocked photosensitivity, while premotor and prefrontal cortex infusions had no effect on the electro-clinical manifestations of this type of reflex epilepsy; the monkeys with prefrontal GABA infusions, however, showed selective attention deficits, detected with the delayed response test. In all cases a GABA withdrawal syndrome, appearing as epileptogenic spontaneous activity localized to the infused sites, was found at the cessation of GABA application.

Anticonvulsant effects of localized chronic infusions of GABA in cortical and reticular structures of baboons.

We studied the effects of chronic (7 day) infusions of GABA (100 and 20 micrograms/microliter, 10 microliter/h) applied in different cerebral structures of baboons made photosensitive by a subconvulsant dose of allylglycine. The GABA infusion has partial anticonvulsant effects when applied to the motor cortex, reticular magnocellular nucleus (RMC), or substantia nigra (SN), but when directed to the prefrontal cortex (area 8) it has no effect. These anticonvulsant effects of GABA infusion are more important when GABA is infused into the motor cortex, where paroxysmal discharges (PDs) originate, than when it is infused into the RMC.

The GABA-withdrawal syndrome: a new model of focal epileptogenesis.

A novel model of focal, cortical epilepsy is described. Chronic (6 h to 14 days), localized application of gamma-aminobutyric acid (GABA) into the somatomotor cortex of rats induces, upon withdrawal, the appearance of epileptogenic activity with maximal electrographic expression circumscribed to the infused site. This GABA-withdrawal syndrome (tested for a 100 micrograms/microliter/h dose) lasted from 24 to 168 h (mean values).