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. Local cerebral glucose utilization increased two- to three-fold in a 1-1.5 mm diameter area, involving all the cortical layers at the GABA-infusion site. This hypermetabolic area contained a central (1-2 mm diameter) hypometabolic zone showing neuronal depopulation in some animals. Except for the epileptic focus, the hemisphere ipsilateral to the infusion site was slightly hypometabolic. However, there was a large increase (three- to five-fold) in some ipsilateral thalamic nuclei (posterior oralis, ventralis postero-lateralis, centralis lateralis, ventralis lateralis and reticularis thalami nucleus). The local cerebral glucose utilization of the contralateral cortex and thalamus were unchanged. The present results confirm the focal nature of the epileptogenic syndrome produced by stopping chronic, intracortical GABA infusion. These results are markedly different from those described in the penicillin focal epilepsy model. Our data also show that specific ipsilateral thalamic relays may, by an as yet unknown mechanism, play a role in maintaining paroxysmal activity during the GABA withdrawal syndrome.

Relationships between benzodiazepine receptors, impairment of GABAergic transmission and convulsant activity of beta-CCM: a PET study in the baboon Papio papio

Central type benzodiazepine receptors were studied in vivo by positron emission tomography in brain areas of 2 different groups of the baboon Papio papio: non-photosensitive (group 1) and those with an allylglycine-induced decrease in GABA-mediated inhibition (group 2). Further, a naturally photosensitive Papio papio (+3 level of photosensitive response) was compared to both groups. Regional brain binding of the specific benzodiazepine receptor ligand, [11C]Ro 15-1788, was not significantly different between groups 1 and 2. In addition, the data from the naturally photosensitive Papio papio did not seem to differ markedly from groups 1 and 2 either. Pharmacological effects of increasing doses of beta-CCM (0.05-3 mg/kg i.v.) and regional benzodiazepine receptor occupancy by the drug were simultaneously studied using electroencephalographic activity recording and positron emission tomography. A positive correlation was observed between the degree of photosensitivity of the baboon and sensitivity to the action of beta-CCM, with increasing convulsant efficacy of beta-CCM in going from group 1 to the naturally photosensitive baboon, then to group 2. Dose-related displacement curves of [11C]Ro 15-1788 binding by beta-CCM revealed that reduction in brain GABA concentration did not modify the inhibitory potency of beta-CCM on [11C]Ro 15-1788 binding in cerebral cortex. This suggests a lack of detectable in vivo allosteric effects of GABA on beta-CCM binding during beta-CCM-induced seizures. Thus, a given dose of beta-CCM displayed increasing pharmacological potency in going from baboons with the lowest photosensitivity to those with the highest, whereas benzodiazepine receptor occupancy by beta-CCM was similar in the cerebral cortex of the different baboons. Conversely, a given level of convulsant activity of beta-CCM was related to a different benzodiazepine receptor occupancy by the drug, depending on the photosensitivity of Papio papio. A given dose of a drug may, thus, have a different pharmacological potency when occupying the same number of receptors, depending on the physiopathological state of the subject.

Status epilepticus induced by pentylenetetrazole modulates in vivo [11C]Ro 15-1788 binding to benzodiazepine receptors. Effects of ligands acting at the supramolecular receptor complex

Positron emission tomography (PET) was used to investigate, in the living baboon, the in vivo modulation of [11C]Ro 15-1788 binding to benzodiazepine receptors in brain and the changes with ligands acting at the supramolecular complex during status epilepticus induced by pentylenetetrazole. The central type benzodiazepine receptors were labelled in vivo by intravenous injection of [11C]Ro 15-1788. Simultaneous positron emission tomography and electroencephalographic activity recording evidenced a modulation of the brain binding of [11C]Ro 15-1788 during pentylenetetrazole-induced status epilepticus. We investigated the changes in the modulation of radioligand kinetics and in seizure activity after intravenous administration of a benzodiazepine agonist (diazepam, 1.5 mg/kg), a benzodiazepine antagonist (Ro 15-1788, 2 mg/kg), a GABA agonist (progabide, 50 mg/kg) and a ligand of the picrotoxin/barbiturate binding sites (LY81067, 3.5 mg/kg). The results showed that there is an in vivo competitive interaction of pentylenetetrazole with the benzodiazepine receptors, as reflected by the low displacement of [11C]Ro 15-1788 in the first 10 min of the status epilepticus. However, in contrast to diazepam, progabide and LY81067, a dose (2 mg/kg) of Ro 15-1788 that saturates the benzodiazepine receptors was unable to block the seizures induced by pentylenetetrazole. This indicates that the benzodiazepine receptors play only a minor role in the status epilepticus induced by pentylenetetrazole. The contribution of other binding sites within the supramolecular complex is assessed.