Cortical Auditory-Evoked Responses in Preterm Neonates: Revisited by Spectral and Temporal Analyses.

Characteristic preterm EEG patterns of "Delta-brushes" (DBs) have been reported in the temporal cortex following auditory stimuli, but their spatio-temporal dynamics remains elusive. Using 32-electrode EEG recordings and co-registration of electrodes' position to 3D-MRI of age-matched neonates, we explored the cortical auditory-evoked responses (AERs) after 'click' stimuli in 30 healthy neonates aged 30-38 post-menstrual weeks (PMW). (1) We visually identified auditory-evoked DBs within AERs in all the babies between 30 and 33 PMW and a decreasing response rate afterwards. (2) The AERs showed an increase in EEG power from delta to gamma frequency bands over the middle and posterior temporal regions with higher values in quiet sleep and on the right. (3) Time-frequency and averaging analyses showed that the delta component of DBs, which negatively peaked around 550 and 750 ms over the middle and posterior temporal regions, respectively, was superimposed with fast (alpha-gamma) oscillations and corresponded to the late part of the cortical auditory-evoked potential (CAEP), a feature missed when using classical CAEP processing. As evoked DBs rate and AERs delta to alpha frequency power decreased until full term, auditory-evoked DBs are thus associated with the prenatal development of auditory processing and may suggest an early emerging hemispheric specialization.

[Cellular mechanisms of the epilepsies: In vitro studies on human tissue]. / Etudes in vitro sur tissu humain des mécanismes cellulaires des épilepsies.

BACKGROUND AND PURPOSE: Animal models have provided very valuable data to specify the physiopathological mechanisms of the various forms of epilepsy. However, the question arises of knowing which of these experimental results are relevant to the human epileptic brain. The development of epileptic surgery makes it possible to directly study the functional properties of human brain tissue in vitro and to analyze the mechanisms underlying seizures and epileptogenesis. We review some of the results obtained over the last few years in our laboratory based on electrophysiological, immunocytochemical and molecular experiments conducted on human brain tissue. RESULTS: This review covers a number of the mechanisms of neuronal synchronizations generating epileptiform discharges, including the role of electrical synapses connecting the inhibitory interneurons, particularly in Taylor-type focal cortical dysplasia and the functional lability of GABAergic inhibition in epileptogenic human cortical tissue, which may sustain triggering and propagation of seizures. Some of these mechanisms have not been described in animal models. CONCLUSIONS: Studies on human tissue, when carefully designed, are necessary to validate the data collected on animal models and will continue to provide us with new and important information on the cerebral changes related to epilepsy. Moreover, these studies allow development of a class of antiepileptic drugs that have a completely new mechanism of action, which could be effective in the treatment of drug-resistant epilepsies.

Effects of gap junction blockers on human neocortical synchronization.

Field potentials and intracellular recordings were obtained from human neocortical slices to study the role of gap junctions (GJ) in neuronal network synchronization. First, we examined the effects of GJ blockers (i.e., carbenoxolone, octanol, quinine, and quinidine) on the spontaneous synchronous events (duration = 0.2-1.1 s; intervals of occurrence = 3-27 s) generated by neocortical slices obtained from temporal lobe epileptic patients during application of 4-aminopyridine (4AP, 50 muM) and glutamatergic receptor antagonists. The synchronicity of these potentials (recorded at distances up to 5 mm) was decreased by GJ blockers within 20 min of application, while prolonged GJ blockers treatment at higher doses made them disappear with different time courses. Second, we found that slices from patients with focal cortical dysplasia (FCD) could generate in normal medium spontaneous synchronous discharges (duration = 0.4-8 s; intervals of occurrence = 0.5-90 s) that were (i) abolished by NMDA receptor antagonists and (ii) slowed down by carbenoxolone. Finally, octanol or carbenoxolone blocked 4AP-induced ictal-like discharges (duration = up to 35 s) in FCD slices. These data indicate that GJ play a role in synchronizing human neocortical networks and may implement epileptiform activity in FCD.

Atheroprotective effect of adjuvants in apolipoprotein E knockout mice.

Strategies aimed at treating atherosclerosis by immunization protocols are emerging. Such protocols commonly use adjuvants as non-specific stimulators of immune responses. However, adjuvants are known to modify various disease processes. The aim of this study was to determine whether adjuvants alter the development of atherosclerosis. We performed immunization protocols in apolipoprotein E knockout mice (E degrees ) following chronic administration schedules commonly employed in experimental atherosclerosis. Our results point out a dramatic effect of several adjuvants on the development of atherosclerosis; three of the four adjuvants tested reduced lesion size. The Alum adjuvant, which is the adjuvant currently used in most vaccination protocols in humans, displayed a strong atheroprotective effect. Mechanisms accounting for atheroprotective effect of Freund's adjuvants included their capacity to increase both Th2 responses and anti-MDA-LDL IgM titers, and/or to impose atheroprotective lipoprotein profiles. The present study indicates that adjuvants have potent atheromodulating capabilities, and thus, implies that the choice of adjuvant is crucial in long-term immunization protocols in experimental atherosclerosis.

Role of the intrinsic coagulation pathway in atherogenesis assessed in hemophilic apolipoprotein E knockout mice.

OBJECTIVE: The contribution of thrombosis and coagulation in atherogenesis is largely unknown. We investigated the contribution of the coagulation intrinsic factor VIII (FVIII)-dependent pathway in atherogenesis. METHODS AND RESULTS: Apolipoprotein E and FVIII double-deficient mice (E degrees/FVIII degrees) were generated. Aortic root lesions were analyzed in 14-week-old and 22-week-old female mice maintained for 8 or 16 weeks, respectively, on a normal chow diet or a hypercholesterolemic diet. CONCLUSIONS: Despite a higher plasma total cholesterol concentration compared with E degrees mice, E degrees/FVIII degrees mice developed dramatically less early-stage atherosclerotic lesions. Whereas early lesions in E degrees mice contained abundant fibrin(ogen) deposits on which few platelets adhered, lesions in E degrees/FVIII degrees were almost devoid of fibrin(ogen), and no platelets could be detected. The genotype effect on development and composition of lesions tended to decrease with time. This study demonstrates that the activation of the intrinsic pathway of coagulation is potently proatherogenic at the early stage of atherogenesis.

Non-viral gene transfer of murine spleen cells achieved by in vivo electroporation.

Gene electrotranfer is an attractive physical method to deliver genes to target tissues. The aim of this study was to evaluate in vivo gene electrotransfer into spleen, one of the most important lymphoid organ, in order to create a new tool to modulate the immuno-inflammatory system. C57Bl/6 mice were submitted either to intramuscular electrotransfer (IME) as a reference method or to intrasplenic (ISE) gene electrotransfer. In the naked injected plasmids, the CMV promoter controlled the expression of luciferase, secreted alkaline phosphatase, EGFP, or IFNgamma. The ISE optimal electrotransfer conditions were first determined and ISE was found to be an efficient gene transfer method, which can be used to express secreted or intracellular proteins transiently. Although transfected cells were still present in the spleen 30 days after ISE, transfected spleen cells could recirculate since they were detected in extrasplenic locations. Using a T-lymphocyte-specific promoter controlling the expression of EGFP, splenic T cells could be targeted. Finally, it appeared that ISE procedure does not impair by itself the immune response and does not result in a significant production of antibodies directed to the transgenic proteins in C57Bl/6 mice. This strategy constitutes a new method to manipulate the immune response that can be used in various experimental designs.

Endogenous phosphorylation of the GABA(A) receptor protein is counteracted by a membrane-associated phosphatase.

Incubation of bovine brain membranes with [gamma-33P]ATP phosphorylated mainly a 51-kDa band. Electrophoretic co-migration was observed for 33P- and [3H]flunitrazepam-labeled bands in both membrane fractions and in affinity-purified GABA(A) receptor (GABAA-R) preparations. An alpha-subunit monoclonal antibody adsorbed most of the radiolabeled-band, suggesting that the labeled-membrane polypeptide corresponds to the GABA(A)-R alpha1-subunit, which is the only GABA(A)-R subunit with a molecular weight of 51 kDa. The phosphorylation rate was much faster in membranes than in purified receptor. Dephosphorylation was detected in membranes only. The membrane-bound phosphatase was potently inhibited by vanadate and Zn2+>>Mn2+ , but was insensitive to okadaic acid (a phosphatase 1, 2 and 2B inhibitor), cyclosporin (specific calcineurin inhibitor) and phosphatase-1 inhibitor. Endogenous kinase was activated by divalent cations including calcium (Mg2- > Mn2+ > Ca2+), whilst dephosphorylation did not require the presence of Ca2+ ions. This suggests that at least one membrane-bound phosphatase counteracts the endogenous phosphorylation of the GABA(A)-R: the lack of dephosphorylation in the purified receptor preparation indicates that, in contrast to the endogenous kinase, no phosphatase is closely associated with the receptor protein complex.

Heterogeneous distribution of polyamines in temporal lobe epilepsy.

Polyamine contents were determined in human temporal lobe epilepsy. In the seven patients studied, stereoelectroencephalography (SEEG) located the epileptogenic focus in Ammon's horn and neuropathological findings were limited to hippocampal gliosis and sclerosis. Each polyamine exhibited a specific regional distribution. The most important variations were observed for spermidine and spermine while putrescine levels varied less. The regional variation was predominant in middle > posterior > anterior parts of the temporal lobe. Spermine contents and the spermidine/spermine (SPD/SPM) index varied especially in the middle and posterior parts of the hippocampus. Metabolic SPD/SPM index and spermidine levels were found to be drastically increased in almost all limbic parts when compared to neocortical regions. The opposite was observed for spermine. The heterogeneous distribution of polyamines was compared to abnormal electrical activities recorded by SEEG: SPD/SPM index and spermidine levels were sharply increased in seizure onset areas and high levels of spermine were detected in temporal cortex propagation areas. The presently reported heterogeneity of polyamine contents might contribute to modulate differentially the local control of excitability in human temporal epilepsy.

[Intervention of GABAergic neurotransmission in partial epilepsies]. / Intervention de la neurotransmission GABAergique dans les épilepsies partielles.

The gamma-aminobutyric acid (GABA) is one of the most important inhibitory transmitter in the CNS. When GABA is released in the synaptic cleft, it can act on two types of receptors, type A (GABAA-R) and type B. The GABAA-R is an ionotropic receptor whose subunits form a chloride channel. It contains specific binding sites at least for GABA, benzodiazepines, picrotoxin, barbiturates, anesthetic steroids, divalent cations such as Zn2+ and other compounds. Neurotransmitters and neuropeptides that regulate intracellular second messengers may modulate the responses of GABAA-R in the post-synaptic membrane and thus affect the synaptic plasticity. While consensus sites for several kinases are present on many subunit-subtypes, the functional consequences of these phosphorylations are unclear. However, the maintenance of normal GABA currents required the activity of a unique kinase specific for the GABAA-R. This intracellular regulation site might be involved in synaptic plasticity and considered as a site of vulnerability for epileptogenesis. The generation of epileptic discharge, synchronized burst firing and interictal spikes, can be subsequent to the alteration of GABAA-R function. A consequence of GABAergic disinhibition is the formation of new polysynaptic pathways leading to a network of neurons that were previously not connected. Cell loss and plasticity are currently observed in most patients with temporal lobe epilepsy. CA1 pyramidal cells are missing and mossy fibers of dentate granule cells project back through the granule cell layer to form recurrent terminals on granule cell dendrites. This mossy fiber sprouting leads to the destruction of most dentate hilar somatostatine interneurons. Nevertheless, local circuit neurons containing glutamic acid decarboxylase survive in this layer and in all regions of the sclerotic hippocampus. A decrease of the GABA release has been proposed as a basis for disinhibition temporal-lobe epilepsy is partially characterized by a loss of glutamate-stimulated GABA release that is secondary to a reduction in the number of GABA transporters. A molecular reorganization of GABAA-R subunits has been suggested in the kindling model of temporal lobe epilepsy because the zinc released from abberantly sprouted mossy fiber terminals is responsible for a collapse of augmented inhibition by GABA. These results support the concept of a loss of inhibition in chronic epilepsy models and probably in human epilepsies.

Astroglial cells express large amounts of GABAA receptor proteins in mature brain.

GABAA receptors were characterized in cellular fractions isolated from adult bovine brain. The fraction enriched in cortical astrocytes is very rich in high-affinity binding sites for [3H]flunitrazepam and other "central-type" benzodiazepine ligands. The amount of specific [3H]flunitrazepam binding was more than five times higher in the glial fraction than in synaptosomal and perikaryal fractions. [3H]Flunitrazepam was displaced by low concentrations of clonazepam and other specific ligands for central GABAA receptors. Specific binding sites for GABA, flunitrazepam, barbiturates, and picrotoxin-like convulsants were characterized. Allosteric interactions between the different sites were typical of central-type GABAA receptors. The presence of alpha-subunit(s), as revealed by [3H]flunitrazepam photoaffinity labeling, was demonstrated in all brain fractions at molecular mas 51-53 kDa. Photoaffinity labeling was highest in the glial fraction. However, in primary cultured astrocytes from neonate rat cortex, no photoaffinity labeling was detected. Information obtained from astrocytes in culture should thus be taken with caution when extrapolated to differentiated astroglial cells. Our results actually show that, in mature brain, most of the fully pharmacologically active GABAA receptors are extrasynaptic and expressed in astroglia.

Endogenous phosphorylation of distinct gamma-aminobutyric acid type A receptor polypeptides by Ser/Thr and Tyr kinase activities associated with the purified receptor.

We have investigated the phosphorylation of gamma-aminobutyric acid type A (GABAA) receptor purified from bovine cerebral cortex in the absence of added kinases. Incubation of the affinity-purified receptor with [gamma-32P]ATP and 500 microM MnCl2 yielded incorporation of 0.45 mol of 32P/mol of muscimol binding sites within 2 h at 30 degrees C. Mn2+ was much more effective than Mg2+ as activator. Phosphorylation of the receptor was observed on at least three different polypeptides of 51, 53, and 55 kDa. It was predominant on 51- and 53-kDa polypeptides that co-migrate with the [3H]flunitrazepam photoaffinity-labeled bands, suggesting that 32P incorporation mainly occurs on alpha-subunits. A monoclonal antibody specific for alpha-subunits adsorbed the endogenously phosphorylated GABAA receptor with a stoichiometry close to 1 mol of phosphate/mol of muscimol. The phosphorylation of the 51-kDa polypeptide, corresponding to alpha 1-subunit, exhibited a micromolar affinity for ATP and sigmoid kinetics (nH = 2). Major incorporation of phosphate occurred on serine and threonine residues in roughly equimolar ratio. By enzyme-linked immunosorbent assay and immunoblotting studies we also detected a minor incorporation on tyrosine residues; this was specific for a 55-kDa polypeptide. Comparison with molecular data suggests that at least alpha 1- and alpha 2-subunits (Ser and Thr residues) and possibly gamma 2-subunits (Tyr residue) are endogenously phosphorylated by multiple kinases, with a clear preference for alpha 1-subunit. The beta-subunits were not phosphorylated in our experimental conditions. The corresponding kinase activities are closely associated to the receptor protein, indicating a new complexity in the regulation of the GABAA receptor.

Thiamine deficiency in cultured neuroblastoma cells: effect on mitochondrial function and peripheral benzodiazepine receptors.

When neuroblastoma cells were transferred to a medium of low (6 nM) thiamine concentration, a 16-fold decrease in total intracellular thiamine content occurred within 8 days. Respiration and ATP levels were only slightly affected, but addition of a thiamine transport inhibitor (amprolium) decreased ATP content and increased lactate production. Oxygen consumption became low and insensitive to oligomycin and uncouplers. At least 25% of mitochondria were swollen and electron translucent. Cell mortality increased to 75% within 5 days. [3H]PK 11195, a specific ligand of peripheral benzodiazepine receptors (located in the outer mitochondrial membrane) binds to the cells with high affinity (KD = 1.4 +/- 0.2 nM). Thiamine deficiency leads to an increase in both Bmax and KD. Changes in binding parameters for peripheral benzodiazepine receptors may be related to structural or permeability changes in mitochondrial outer membranes. In addition to the high-affinity (nanomolar range) binding site for peripheral benzodiazepine ligands, there is a low-affinity (micromolar range) saturable binding for PK 11195. At micromolar concentrations, peripheral benzodiazepines inhibit thiamine uptake by the cells. Altogether, our results suggest that impairment of oxidative metabolism, followed by mitochondrial swelling and disorganization of cristae, is the main cause of cell mortality in severely thiamine-deficient neuroblastoma cells.

[Comparative biochemistry of the triune brain]. / Biochimie comparée des trois cerveaux.

The contribution of the phylogenesis to the study of the functional organisation of brain constitutes an essential component in the integration of the current data regarding the knowledge of the central nervous system. The three evolutive structures evidenced by McLean allowed manifestation of a biological diversity particularly expressed in the neommamalian brain. Studying this biological diversity constitutes one of the field of comparative biochemistry. In this article, the authors attempt to characterize evolution through the study of GABA-receptors.

Polyamine metabolism in epileptic cortex.

Polyamine (tissue) concentrations have been studied in hippocampus and temporal neocortex from patients with temporal lobe epilepsy. Depth electrode recordings demonstrated hippocampal origin of the seizures, the temporal neocortex being involved during the discharge propagation. Neuropathological examination of excised tissues showed glial proliferation or glioma in Ammon's horn (CA), whereas the temporal neocortex did not exhibit any histological abnormality. Polyamine (putrescine or PUT, spermidine or SPD, spermine or SPM) concentrations were determined on surgical samples from the hippocampus and various areas of temporal neocortex. Human post-mortem tissue from temporal lobe regions was used for controls. In post-mortem controls and temporal neocortex specimens from epileptic patients, polyamine levels were similar (in nmol/g wet weight: PUT = 40-100; SPD = 200-350; SPM = 100-200). In CA, polyamine levels exhibited striking changes: SPD content was significantly increased (350-700 nmol/g) while SPM was lowered (50-100). PUT was only increased in CA invaded by the tumoral process (100-180). Accordingly, a very high SPD/SPM molar ratio in the abnormal CA region was observed, indicating an acceleration of polyamine neosynthesis which is usually related to ornithine decarboxylase induction. Metabolic changes in polyamines appear to be selective of human epileptic hippocampus. A relationship between glial proliferation (gliosis or neoplasia), epileptic firing and polyamines is discussed.

Characteristics of putrescine uptake and subsequent GABA formation in primary cultured astrocytes from normal C57BL/6J and epileptic DBA/2J mouse brain cortices.

Brain maturation and GABA metabolism are known to play a key role in epileptogenesis. The metabolism of the polyamines (putrescine, spermidine and spermine) is closely linked to the process of brain maturation. Putrescine has been shown to be catabolized to GABA in brain tissue and astrocytes. In order to better understand the importance of glial putrescine transport and metabolism, a model of age-dependent epilepsy was used to study the kinetic properties of [14C]putrescine uptake into cultured astrocytes from normal C57/BL and audiogenic DBA/2 newborn mice, and the subsequent GABA formation. (1) Putrescine uptake exhibited non-Michaelian allosteric kinetics with positive co-operativity (Hill factor = 2), suggesting a physiological importance of putrescine uptake by astrocytes. (2) The Vmax of putrescine uptake was significantly higher in C57/BL astrocytes than in DBA/2J, but the uptake affinity for putrescine was higher in DBA/2J than in C57/BL. (3) Higher K+ concentrations (18 mM) had little effect on putrescine uptake in either strain. (4) Ten-micromolar N-acetylputrescine, the first putrescine metabolite, stimulated putrescine uptake into astrocytes of both strains, but to a different degree: +46% in C57/BL and + 102% in DBA/2J. (5) The specific radioactivity of the GABA formed from labelled putrescine was four times higher in astrocytes from DBA/2J than from C57/BL mice. (6) The molar ratio of glutamate/GABA in the cerebral cortex of the DBA/2J mice was significantly higher during the period of audiogenic seizure susceptibility than in age-matched C57/BL mice. Our results show characteristics of putrescine uptake into astrocytes; we demonstrated distinct kinetic properties between normal and epileptic strains of mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphorylation of brain (Na+,K+)-ATPase alpha catalytic subunits in normal and epileptic cerebral cortex: I. The audiogenic mice and the cat with a freeze lesion.

Partially purified (Na+,K+)-ATPase (E.C. 3.6.1.3.) was investigated in the epileptic cortex of audiogenic DBA/2 mice and in the primary and secondary foci of cats with acute or chronic freeze lesions. No differences in specific activities measured at 3 mM K+ were observed between epileptic and control cortex, except an increase of enzymic activities in the primary focus of acutely lesioned cats. The (Na+,K+)-ATPase catalytic subunits were resolved by SDS-gel electrophoresis and their phosphorylation levels were measured in presence of K+ ions and phenytoin. K+ was more effective in inducing maximal dephosphorylation of (Na+,K+)-ATPase in C57/BL, with identical affinity in the two strains. Phenytoin decreased the net phosphorylation level of (Na+,K+)-ATPase by about 50% in C57/BL mice, but only by 20% in DBA/2 mice. Both K+ and phenytoin dephosphorylating influences were decreased in primary and secondary foci of acutely lesioned cats. Those changes were limited to the alpha(-) subunit. In chronic cats, the dephosphorylating step of the (Na+,K+)-ATPase catalytic subunit recovered a normal affinity to K+, but its sensitivity to phenytoin remained decreased. Those differences in K+ and phenytoin influences on brain (Na+,K+)-ATPases between control and epileptic cortex might be responsible for the ictal transformation and seizure spread. In cats, the alteration of the alpha(-) isoform could mainly affect the glial cells.

Phosphorylation of brain (Na+,K+)-ATPase alpha catalytic subunits in normal and epileptic cerebral cortex: II. Partial seizures in human epilepsy.

We examined the activity and phosphorylation level of (Na+,K+)-ATPase (E.C. 3.6.1.3) partially purified from normal and epileptic human cortices. Control patients (n = 11) were operated on for a non-epileptogenic deep brain lesion, while epileptic patients (n = 10) were operated on for temporal or frontal originating partial seizures, resistant to medications or secondary to evolutive brain tumors. No differences in the specific activity of microsomal (Na+,K+)-ATPase were observed between the two groups of patients. After partial purification of the enzyme followed by SDS-polyacrylamide gel electrophoresis, (Na+,K+)-ATPase catalytic subunit had a decreased affinity for K+ in human epileptic cortex and lost its sensitivity to phenytoin dephosphorylation. Indirect evidence suggests that those abnormalities of (Na+,K+)-ATPase in human epileptic cortex hold preferentially true for the alpha(-) enzymatic subunit. Those results indicate that, in human epileptic cortex, (Na+,K+)-ATPase and most probably its glial subtype is altered in its K+ regulation and phenytoin sensitivity and could be responsible for ictal transformation and seizure spread.

Effect of milacemide on audiogenic seizures and cortical (Na+, K+)-ATPase of DBA/2J mice.

Milacemide (MLM, CP 1552 S, 2-N-pentylaminoacetamide), a glycinamide derivative, is currently being evaluated clinically for antiepileptic activity. Anticonvulsant properties have been shown in various animal models, but the mechanism of action of MLM is unclear. We studied its activity in audiogenic seizures of DBA/2J mice. MLM was effective in inhibiting the convulsions induced by sound with a biphasic dose-effect relation. The ED50 was 109 mg/kg orally against tonic extension. Higher doses were necessary to abolish clonic convulsion and running response. Because impaired cerebral (Na+, K+)-ATPase activity is supposed to play a role in epileptogenesis, we tested MLM on in vitro cortical enzymatic activity of DBA/2J mice. Basal (Na+, K+)-ATPase activity was unchanged by several concentrations of MLM in normal C57BL/6J and audiogenic DBA/2J mice. K+ activation (from 3 to 18 mM) of (Na+, K+)-ATPase is abolished in DBA/2J mice as compared with C57BL/6J mice, suggesting impaired glial (Na+, K+)-ATPase. In the presence of MLM (from 30 to 1000 mg/L), cortical (Na+, K+)-ATPase of DBA/2J mice is activated by high concentrations of K+, as in C57BL/6J mice. Results suggest that the antiepileptic activity of MLM in audiogenic mice may be secondary to an activation of a deficient glial (Na+, K+)-ATPase.

Milacemide stimulates deficient glial Na+, K(+)-ATPase in freezing-induced epileptogenic cortex of cats.

We investigated the influence of milacemide, a glycinamide derivative with putative antiepileptic activity, on the K(+)-activation of Na+,K(+)-ATPase in bulk isolated glial cells and synaptosomes of control and epileptogenic cortex of cats with a chronic freeze lesion. In the primary and secondary epileptic foci of non-treated animals, glial Na+,K(+)-ATPase lost its physiological K(+)-activation, while the synaptosomal enzyme was unchanged. These data reproduced previous work done on the kinetic measurement of the enzymic activities. In treated animals (500 mg/kg milacemide given orally for 2 weeks after the freeze lesion), the glial enzyme showed a normal K(+)-activation in the epileptic foci. These results confirm the existence of an abnormal glial Na+,K(+)-ATPase in cold-induced focal epilepsy and suggest that the antiepileptic activity of milacemide might be secondary to an activation of glial Na+,K(+)-ATPase, contributing to antagonize ictal transformation and seizure spread.