Low doses of ethanol markedly potentiate the anti-seizure effect of diazepam in a mouse model of difficult-to-treat focal seizures.

Ethanol is commonly used as a solvent in injectable formulations of poorly water-soluble drugs. The concentrations of ethanol in such formulations are generally considered reasonably safe. It is long known that ethanol can potentiate central effects of sedatives and tranquillizers, particularly the benzodiazepines, most likely as a result of a synergistic interaction at the GABAA receptor. However, whether this occurs at the low systemic doses of ethanol resulting from its use as solvent in parenteral formulations of benzodiazepines is not known. In the present study we evaluated whether a commercial ethanol-containing aqueous solution of diazepam exerts more potent anti-seizure effects than an aqueous solution of diazepam hydrochloride or an aqueous emulsion of this drug in the intrahippocampal kainate model of temporal lobe epilepsy in mice. Spontaneous epileptic seizures in this model are known to be resistant to major antiepileptic drugs. Administration of the ethanol-containing formulation of diazepam caused an almost complete suppression of seizures. This was not seen when the same dose (5 mg/kg) of diazepam was administered as aqueous solution or emulsion, although all three diazepam formulations resulted in similar drug and metabolite concentrations in plasma. Our data demonstrate that ethanol-containing solutions of diazepam are superior to block difficult-to-treat seizures to other formulations of diazepam. To our knowledge, this has not been demonstrated before and, if this finding can be translated to humans, may have important consequences for emergency treatment of acute seizures, series of seizures, and initial treatment of status epilepticus in patients.

Treatment with valproate after status epilepticus: effect on neuronal damage, epileptogenesis, and behavioral alterations in rats.

Epileptogenesis, i.e. the process leading to epilepsy with spontaneous recurrent seizures, can be initiated by a number of brain damaging insults, including traumatic brain injury, status epilepticus (SE), and stroke. Such acquired epilepsy is often associated with memory impairment and behavioral problems. There has been a growing interest in the use of antiepileptic drugs (AEDs) for neuroprotection and prevention or modification of epileptogenesis induced by such brain insults. One promising candidate in this respect is valproic acid (VPA), a widely used AED that has been reported to exert neuroprotective activity in a number of in vitro and in vivo models. The present study investigated whether VPA reduces brain damage and improves functional outcome in a rat model of post-SE epilepsy. A self-sustaining SE was induced by prolonged electrical stimulation of the basal amygdala via a depth electrode. SE was terminated after 4 h by diazepam, immediately followed by onset of treatment with VPA. VPA was injected i.p. at a bolus dose of 400 mg/kg, followed by three times daily administration of 200 mg/kg for 4 weeks. A control group received vehicle instead of VPA after SE. Spontaneous seizures were recorded in all rats of both groups following termination of treatment, without significant inter-group difference in seizure frequency or severity. However, treatment with VPA after SE prevented the hyperexcitability and locomotor hyperactivity observed in vehicle-treated epileptic rats. Furthermore, VPA completely counteracted the neuronal damage in the hippocampal formation, including the dentate hilus. The data demonstrate that, although VPA does not prevent the occurrence of spontaneous seizures after SE, it exerts powerful neuroprotective effects and prevents part of the behavioral alterations, demonstrating that administration of VPA immediately after SE exerts a favorable effect on long-term functional outcome.