Neuronal migration disorders increase susceptibility to hyperthermia-induced seizures in developing rats

PURPOSE: Retrospective studies suggest that adult patients with intractable epilepsy may have a history of febrile seizures in childhood. Risk factors for a febrile seizure may include the rate of increase in the core temperature (T-core), its peak (Tmax), the duration of the temperature increase, or an underlying brain pathology. Recently, neuronal migration disorders (NMD) have been diagnosed with increasing frequency in patients with epilepsy, but the link between NMD, febrile seizures, and epilepsy is unclear. We studied rat pups rendered hyperthermic to ascertain the incidence of seizures, mortality, and extent of hippocampal cell loss in each group. METHODS: We exposed 14-day-old rat pups with experimentally induced NMD (n = 39) and age-matched controls (n = 30) to hyperthermia (core body temperature > 42 degrees C). RESULTS: The incidence of hyperthermia-induced behavioral seizures and mortality rate were significantly higher in rats with NMD than in controls (p < 0.05). The longer duration of hyperthermia resulted in a higher incidence of behavioral seizures and higher mortality rate (p < 0.05). In rats with NMD, hyperthermia resulted in hippocampal pyramidal cell loss independent of seizure activity; the extent of neuronal damage correlated positively with the duration of hyperthermia. In control rats, occasional neuronal loss and astrocytosis occurred only after prolonged hyperthermia. CONCLUSIONS: In immature rats, NMD lower the threshold to hyperthermia-induced behavioral seizures and hyperthermia in the presence of NMD may cause irreversible hippocampal neuronal damage.     

Methionine sulfoximine increases acetylcholine level in the rat brain: no relation with epileptogenesis

Methionine sulfoximine induces epileptiform convulsions in rats. A possible involvement of acetylcholine in the onset of convulsions was investigated. A subconvulsive dose of methionine sulfoximine increased the brain acetylcholine concentration. After administration of a convulsive dose, atropine neither prevented the onset of the seizures nor prevented the increase in acetylcholine concentration. Physostigmine enhanced the increase in acetylcholine level but did not modify the time course nor the intensity of the convulsions. L-DOPA suppressed the seizures without inhibiting the increase in acetylcholine level. The choline content decreased after the convulsant dose. The increase in acetylcholine content is therefore not the unique cause of the seizures, which could result from the reduction of striatal inhibition due to a decrease in dopamine level induced by methionine sulfoximine.     

The amygdala is critical for seizure propagation from brainstem to forebrain

Audiogenic seizures, a model of brainstem epilepsy, are characterized by a tonic phase (sustained muscular contraction fixing the limbs in a flexed or extended position) associated with a short cortical electroencephalogram flattening. When sound-susceptible rats are exposed to repeated acoustic stimulations, kindled audiogenic seizures, characterized by a clonic phase (facial and forelimb repetitive jerks) associated with cortical spike-waves, progressively appear, suggesting that repetition of brainstem seizures causes a propagation of the epileptic discharge toward the forebrain. In order to determine the structures through which this propagation occurs, four kinds of experiments were performed in non-epileptic rats and in sound-susceptible rats exposed to single or repeated sound stimulations. The following results were obtained: (I) Electrical amygdalar kindling was similar in non-epileptic and naive-susceptible rats, but was facilitated in sound-susceptible rats submitted to 40 acoustic stimulations and presenting kindled audiogenic seizures. (2) Audiogenic seizures induced an increase in [(14)C]2-deoxyglucose concentration in the amygdala after a single seizure, and in the amygdala, hippocampus and perirhinal and piriform cortices after a kindled audiogenic seizure. (3) A single audiogenic seizure induced the expression of c-Fos protein mainly in the auditory nuclei. A few cells were stained in the amygdala. After 5-10 audiogenic seizures, a clear staining appeared in the amygdala, and perirhinal and piriform cortices. The hippocampus expressed c-Fos later, after 40 audiogenic seizures. (4) Injection of lidocaine into the amygdala did not modify single audiogenic seizures, but suppressed myoclonias and cortical spike-waves of kindled audiogenic seizures. Similar deactivation of the hippocampus failed to modify kindled audiogenic seizures. Taken together, these data indicate a critical role for the amygdala in the spread of audiogenic seizures from brainstem to forebrain.     

Minimal effect of brain temperature changes on glutamate release in rat following severe global brain ischemia: a dialysis electrode study

Using a dialysis electrode, we recently developed an oxygen-independent system for real-time measurement of the glutamate concentration in the extracellular space ([Glu]e) during ischemia. This system allows separate evaluation of intra-ischemic biphase [Glu]e elevation, i.e. release from synaptic vesicles (1st phase), reversed uptake of glutamate from metabolic pools in neuronal cells (2nd phase), and post-ischemic glutamate re-uptake in ischemia-reperfusion models. Using the system, we attempted to clarify the relationship between biphase glutamate release and brain temperature in a model of acute global ischemia produced by transecting both carotid arteries. Our results showed that, in contrast to mild hyperthermia, hypothermia did not inhibit the 1st phase of [Glu]e release, and changes in intra-ischemic brain temperature had a minimal effect on the 2nd phase of [Glu]e elevation during severe acute ischemia. These findings, together with our previous data, indicate that brain temperature change in the intra-ischemic period plays an important role in disturbance of the glutamate re-uptake system during ischemia.     

Alterations in GABAA receptor alpha 1 and alpha 4 subunit mRNA levels in thalamic relay nuclei following absence-like seizures in rats

Modification of GABAA receptor mRNA levels by seizure activity can regulate general neuronal excitability. The possibility of absence seizure-induced alteration in GABAA receptor alpha 1, alpha 4, beta 2, and gamma 2 subunit gene expression in thalamic relay nuclei was studied in a rat model of absence seizures induced by gamma-hydroxybutyric acid (GHB). We observed a marked increase in alpha 1 mRNA and a corresponding decrease in alpha 4 mRNA in thalamic relay nuclei 2-4 h after the onset of GHB-induced absence seizures (when the seizures were terminating). These changes were selective to these alpha isoforms as neither beta 2 nor gamma 2 mRNA changed following seizures and occurred only in thalamic relay nuclei but not in hippocampus, a structure from which absence seizures do not evolve. The alterations in alpha 1 and alpha 4 mRNA persisted until about 12 h, and by 24 h after the seizure-onset the mRNA levels normalized. Blocking GHB-seizures produced no change in the levels of alpha 1 and alpha 4 mRNA in thalamic relay nuclei, suggesting that seizures themselves were responsible for mRNA alterations. In order to determine if absence seizure-induced changes in alpha 1 and alpha 4 mRNA had any physiological significance, GHB was readministered in rats 6 and 24 h after the onset of seizures. The total duration of GHB-seizures was found to be significantly decreased when GHB was readministered at 6 h but not 24 h after the seizure-onset. These results suggest that absence seizures regulate GABAA receptor alpha 1 and alpha 4 gene expression in thalamic relay nuclei as a compensatory mechanism by which absence seizures are terminated.     

Neuroleptic malignant syndrome and mivacurium: a safe alternative to succinylcholine?

Neuroleptic malignant syndrome (NMS) and malignant hyperthermia (MH) may have a common pathogenic mechanism; therefore, it has been suggested that known triggering agents for MH (such as succinylcholine) should be avoided in patients with NMS. Electroconvulsive therapy (ECT) continues to play a major therapeutic role in contemporary psychiatry, and succinylcholine has been the muscle relaxant of choice in attenuating violent muscle contractions induced by ECT. Mivacurium is a non-depolarizing muscle relaxant with a relatively rapid onset and a short duration of action, and to date it has been proved safe in MH-susceptible patients. In this case report, following succinylcholine use during ECT, a patient with NMS developed an increase in temperature and serum creatine kinase (CK) level, possibly due to an MH reaction. Since the patient's mental status necessitated further ECT, mivacurium was administered during subsequent treatment and resulted in effective attenuation of muscle contractions without elevation of patient temperature or CK levels. In addition, there was no marked prolongation of the anaesthetic. Mivacurium is a suitable agent for patients with NMS undergoing ECT, as it has not been associated with precipitation of an MH response.     

Single-chain Fv with manifold N-glycans as bifunctional scaffolds for immunomolecules

PURPOSE: To investigate the significance of cortical pathology of tonic spasms in patients with tuberous sclerosis. METHODS: The subjects were 38 patients with epilepsy associated with tuberous sclerosis. We analyzed ictal EEGs of tonic spasms and partial seizures by means of video-EEG monitoring for a total of 763 tonic spasms in 20 patients and 107 partial seizures in 15 patients. We also investigated the relation between partial seizures and magnetic resonance imaging (MRI) findings of these patients. RESULTS: Ictal EEG patterns of tonic spasms were divided into generalized and focal patterns. Thirteen patients had only generalized patterns, whereas seven had both patterns. In five patients who had focal ictal patterns of tonic spasms and partial seizures, the location of focal patterns corresponded with the location of onset of partial seizures. Focal discharges were seen immediately before, after, and in the middle of tonic spasms in series in 13 patients. The location of focal discharges also corresponded with the location of the onset of partial seizures in 10 of the 13 patients. Regarding partial seizures, four patients had multiple active epileptogenic foci during the same period, and two others had shifting epileptogenic foci with increasing age. CONCLUSIONS: These findings indicate that cortical pathology plays an important role in the occurrence not only of partial seizures but also of tonic spasms in patients with tuberous sclerosis.     

Thermotolerance induces heat shock protein 72 expression and protects against ischaemia-reperfusion-induced lung injury

BACKGROUND: Ischaemia-reperfusion injury is mediated by neutrophil-endothelial interaction. Induction of heat shock proteins attenuates neutrophil-endothelial interactions. The aim of this study was to determine whether thermal preconditioning could have a protective effect on neutrophil-mediated lung injury in an animal model of lower torso ischaemia-reperfusion. METHODS: Sprague-Dawley rats were randomized into: control, ischaemia-reperfusion, and ischaemia-reperfusion preconditioned with hyperthermia groups. Ischaemia-reperfusion injury was induced by infrarenal aortic clamping for 30 min and reperfusion for 120 min. Thermotolerance was induced by raising the core body temperature to 40.5-41.5 degrees C for 15 min, 18 h before ischaemia-reperfusion. Wet:dry lung (W:D) weight ratio, bronchoalveolar lavage protein (BALprot) concentration, tissue myeloperoxidase (MPO) activity and bronchoalveolar lavage polymorphonuclear neutrophil (BAL PMN) count were measured. Heat shock protein 72 (hsp72) expression in lung, intestine and mesentery was measured using Western immunoblotting. RESULTS: Ischaemia-reperfusion resulted in a significant increase in tissue oedema (W:D weight ratio) and BALprot concentration. In addition there was a marked increase in tissue neutrophil infiltration (MPO activity, BAL PMN concentration). Preconditioning with hyperthermia resulted in increased expression of hsp72 and significantly reduced tissue oedema and neutrophil infiltration. CONCLUSION: Thermal preconditioning protects against neutrophil-mediated ischaemia-reperfusion-induced lung injury, possibly by increasing the expression of heat shock proteins.     

Spike-wave complexes and fast components of cortically generated seizures. I. Role of neocortex and thalamus

We explored the relative contributions of cortical and thalamic neuronal networks in the generation of electrical seizures that include spike-wave (SW) and polyspike-wave (PSW) complexes. Seizures were induced by systemic or local cortical injections of bicuculline, a gamma-aminobutyric acid-A (GABAA) antagonist, in cats under barbiturate anesthesia. Field potentials and extracellular neuronal discharges were recorded through arrays of eight tungsten electrodes (0.4 or 1 mm apart) placed over the cortical suprasylvian gyrus and within the thalamus. 1) Systemic injections of bicuculline induced SW/PSW seizures in cortex, whereas spindle sequences continued to be present in the thalamus. 2) Cortical suprasylvian injection of bicuculline induced focal paroxysmal single spikes that developed into full-blown seizures throughout the suprasylvian cortex. The seizures were characterized by highly synchronized SW or PSW complexes at 2-4 Hz, interspersed with runs of fast (10-15 Hz) activity. The intracellular aspects of this complex pattern in different types of neocortical neurons are described in the following paper. Complete decortication abolished the seizure, leaving intact thalamic spindles. Injections of bicuculline in the cortex of athalamic cats resulted in similar components as those occurring with an intact thalamus. 3) Injection of bicuculline in the thalamus decreased the frequency of barbiturate spindles and increased the synchrony of spike bursts fired by thalamocortical and thalamic reticular cells but did not induce seizures. Decortication did not modify the effects of bicuculline injection in the thalamus. Our results indicate that the minimal substrate that is necessary for the production of seizures consisting of SW/PSW complexes and runs of fast activity is the neocortex.     

Cortical induction of c-fos by intrastriatal endothelin-1 is mediated via NMDA receptors

Endothelin (ET) is a potent vasoconstrictor which has also been proposed to act as a neuromodulator. We have investigated the action of ET-1 on neurones in vivo, using c-fos as a marker of neuronal activation. Intrastriatal injection of ET-1 caused seizures and barrel rolling which were prevented by pretreatment with the N-methyl-D-aspartate (NMDA) receptor antagonist MK-801 and attenuated by the nitric-oxide synthase inhibitor N omega-nitro-L-arginine (L-NNA). In association with these behaviours, a dramatic increase in c-fos mRNA expression was seen in the cerebral cortex. This increase was blocked by both MK-801 and L-NNA. We suggest that ET-1 modulates the activity of cortical afferents to the striatum, and causes seizures via an NMDA receptor-dependent mechanism.     

Lactate and pyruvate changes in the cerebral gray and white matter during posthypoxic seizures in newborn pigs

Cerebral lactate rises after chemically induced seizures, but it is not known if this occurs with posthypoxic seizures. We examined changes in lactate and pyruvate in gray and white matter in the newborn pig brain after a hypoxic insult known to produce seizures and permanent brain damage. Fourteen halothane-anesthetized piglets aged 24-49 h, were instrumented with a two-channel scalp EEG and microdialysis probes positioned in white and gray matter. Forty-five minutes of hypoxia were induced by reducing the fraction of inspired O2 to the maximum concentration at which EEG amplitude was < 7 microV. Postinsult EEG was classified as electroconvulsive activity (ECA) (n = 4) or burst suppression (n = 2), persistently low amplitude (n = 2), or intermittent spikes on normal background activity (n = 6). Six hours after the insult the brains were perfusion fixed for histologic probe localization. Plasma lactate and brain lactate had different time courses with brain having a persistently elevated lactate/pyruvate (L/P) ratio. The highest L/P ratios in gray and white matter were in the two pigs with persistently low amplitude EEG. There was no association between onset of electroconvulsive activity and an increase in lactate or L/P ratio. Posthypoxic energy metabolism is disturbed in both gray and white matter probably because of mitochondrial dysfunction. Seizure activity does not increase cerebral lactate or L/P ratio above the already raised levels found in posthypoxic encephalopathy. These findings cast further doubt on the hypothesis that such seizures are, in themselves, damaging.     

Gastroduodenal lesions and non-steroidal anti-inflammatory agents. What role does Helicobacter pylori play in this relationship?

In order to elucidate the mechanisms of release of EAAs and their excitotoxicity in cerebral contusion, cortical contusion was produced in the rat parietal cortex, and the changes in extracellular levels of EAAs in the central and peripheral areas of contusion were investigated using microdialysis. The cortical contusion induced a rapid increase in dialysate concentration of glutamate ([Glu]d) from a baseline level of 4.6+/-2.8 microM to a maximum level of 36.3+/-12.8 microM. This elevation of glutamate was significantly attenuated by mild hypothermia (32 degrees C for 90 min, comprising 20 min before and 70 min after the injury induction) in the peripheral area of contusion (p < 0.01) but not in the central area. Histological evaluations revealed that the hypothermia reduced the necrosis volume of contusion to 38.3% of that in the normothermic control (p < 0.01). In situ administration of Co2+, an inhibitor of Co2+-dependent exocytotic release of EAAs from the nerve terminals, via the microdialysis system, also attenuated the [Glu]d elevation following cortical contusion, in the peripheral area of contusion (p < 0.01) but not in the central area. These findings indicate that cerebral contusion involves heterogeneous and complex mechanisms of EAA release into the extracellular space. The release of EAAs in the contusion core was nonsensitive to hypothermia and Co2+ administration, suggesting that such EAA release was related to primary disruption of the cell membrane or vascular wall by the physical force of the head trauma, resulting in leakage of EAAs from the metabolic pool in the cytosole or blood stream. In contrast, in the peripheral area, the effectiveness of hypothermia and Co2+ administration implied a presynaptic mechanism of EAA release, which consisted, at least in part, of Ca2+-dependent exocytotic EAA release from depolarized nerve terminals. The EAAs released in the contusion core may diffuse towards a peripheral direction and act on the postsynaptic receptors, causing neuronal depolarization. Such a diffusion-reaction process appears to induce additional release of EAAs from the depolarized nerve terminals. Hypothermia may block this diffusion-reaction process and eventually reduce the contusion volume.     

cDNA cloning and expression analysis of the murine ribonuclease L inhibitor

This study was designed to test the hypothesis that the immune changes seen during in vivo whole body hyperthermia are mediated by elevations in the plasma concentrations of either catecholamines, growth hormone or beta-endorphins. Eight healthy volunteers were immersed in a hot water bath (WI; water temperature 39.5 degrees C) for 2 h during which their rectal temperature rose to 39.5 degrees C. In a single blind, randomized, cross-over study the stress hormone effects were blocked one at a time by administration of propranolol, somatostatin or naloxone; the results were compared to those obtained during saline infusion (control). Blood samples were collected before, at the end of 2 h of WI (body temperature 39.5 degrees C), and 2 h later. Hormone blockade did not abolish the hyperthermia-induced recruitment of natural killer (NK) cells to the blood, and no influence was observed on the percentages or concentrations of any other subpopulations of blood mononuclear cells, except that the number of cluster designation (CD)3+ cells slightly increased after hyperthermia only in the propranolol experiment. Furthermore, the NK cell activity, both unstimulated and interferon-alpha or interleukin-2 stimulated, did not differ from the control situation. It is of interest, however, that somatostatin partly abolished the hyperthermia induced increase in the neutrophil number. Based on these data and previous results showing that growth hormone infusion increases the concentration of neutrophils in the blood, it is suggested that growth hormone is at least partly responsible for hyperthermia induced neutrocytosis.     

Excitation of hypothalamic nucleus arcuatus neuron induced decrease of plasma sialic acid level in rats

The effect of sodium glutamate (Glu) on plasma sialic acid (SA) level was studied by means of microinjection into the nucleus arcuatus (ARC) and ultraviolet spectrophotometry. The results indicate: (1) The plasma SA level was significantly decreased after microinjection of Glu into the ARC (P < 0.01). With increasing Glu concentration, the onset of the decrease occurred earlier. (2) When Glu was microinjected into ARC after intraventricular injection of apomorphine, the plasma SA level was significantly decreased (P < 0.01) and the time required to cause the decrease was shortened. (3) When Glu was microinjected into ARC after intraventricular injection of spiperone, no change was found in the plasma SA level (P > 0.05). The above results suggest that the mechanism underlying the decrease of plasma SA level is probably related to modulated dopamine (DA) release of hypothalamic dopaminergic neurons by DA-D2 receptor.     

Primary culture and expression of cytokine mRNAs by lipopolysaccharide in bovine Kupffer cells

To clarify the mechanisms of the antiepileptic activity of phenytoin (PHI), the effects of PHT on extracellular and total levels of monoamines (dopamine and serotonin), in rat striatum and hippocampus were studied. The plasma concentrations of PHT associated with therapeutic activity did not affect striatal and hippocampal extracellular levels of monoamines, whereas supratherapeutic concentrations of PHT decreased striatal and hippocampal extracellular levels of monoamines, in a concentration dependent manner. Toxic concentrations of PHT produced generalized seizures 'paradoxical intoxication' and an initial drastic decrease in striatal and hippocampal extracellular levels of monoamines before seizure onset, whereas the extracellular monoamines levels increased after seizures. In addition, the therapeutic concentrations of PHT did not affect monoamine turnover, whereas supratherapeutic concentrations of PHT inhibited monoamine turnover. These results suggest that monoaminergic transmission may not be involved in the antiepileptic mechanism of action of PHT, and that dysfunction of monoaminergic transmission can produce generalized tonic-clonic convulsions. Thus, the present study suggests that 'Paradoxical Intoxication' induced by toxic concentrations of PHT, at least partially, can be mediated by hypo-monoaminergic function in the brain.     

Spike-wave complexes and fast components of cortically generated seizures. III. Synchronizing mechanisms

The intracortical and thalamocortical synchronization of spontaneously occurring or bicuculline-induced seizures, consisting of spike-wave (SW) or polyspike-wave (PSW) complexes at 2-3 Hz and fast runs at 10-15 Hz, was investigated in cats under ketamine-xylazine anesthesia. We used single and dual simultaneous intracellular recordings from cortical areas 5 and 7, and extracellular recordings of unit firing and field potentials from neocortical areas 5, 7, 17, 18, as well as related thalamic nuclei. The evolution of time delays between paroxysmal depolarizing events in single neurons or neuronal pools recorded from adjacent and distant sites was analyzed by using 1) sequential cross-correlations between field potentials, 2) averaged activities triggered by the spiky component of cortical SW/PSW complexes, and 3) time histograms between neuronal discharges. In all instances, the paroxysmal activities recorded from the dorsal thalamus lagged the onset of seizures in neocortex. The time lags between simultaneously impaled cortical neurons were significantly smaller during SW complexes than during the prior epochs of slow oscillation. During seizures, as during the slow oscillation, the intracortical synchrony was reduced with increased distance between different cortical sites. Dual intracellular recordings showed that, during the same seizure, time lags were not constant and, instead, reflected alternating precession of the recorded foci. After transection between areas 5 and 7, the intracortical synchrony was lost, but corticothalamocortical volleys could partially restore seizure synchrony. These data show that the neocortex leads the thalamus during SW/PSW seizures, that time lags between cortical foci are not static, and that thalamus may assist synchronization of SW/PSW seizures after disconnection of intracortical synaptic linkages.     

Protection by L-2-oxothiazolidine-4-carboxylic acid of hydrogen peroxide-induced CD3zeta and CD16zeta chain down-regulation in human peripheral blood lymphocytes and lymphokine-activated killer cells

The cell lethality and permeability induced in Escherichia coli B/r and Escherichia coli BS-1 by 60Co gamma-ray irradiation, ultrasound and hyperthermia in media containing different concentrations of NaCl have been investigated. It was shown that independently from the nature of damaging factors hypotonic media increase while hypertonic media in certain range of osmolyte concentration decrease sensitivity of cells to action of this factors. It was proposed that discovered phenomenology was caused by salt modification of status of the cell osmotic homeostasis destabilizing by ionizing radiation, ultrasound or hyperthermia and was not related with the system of dark repair of DNA.     

A meta-analysis of nausea and vomiting following maintenance of anaesthesia with propofol or inhalational agents

Methamphetamine (m-AMPH) administration injures both striatal dopaminergic terminals and certain nonmonoaminergic cortical neurons. Fluoro-Jade histochemistry was used to label cortical cells injured by m-AMPH in order to identify factors that contribute to the cortical cell body damage. Rats given four injections of m-AMPH (4 mg/kg) at 2-h intervals showed hyperthermia (mean = 40.0 +/- 0.10 degrees C) and increased behavioral activation relative to animals given saline (SAL). Three days later, m-AMPH-treated animals showed indices of injury to striatal DA terminals (depletion of tyrosine hydroxylase immunoreactivity) and parietal cortical cell bodies (appearance of Fluoro-Jade stained cells). Pretreatment with a dopamine (DA) D1, D2, or N-methyl-D-aspartate (NMDA) receptor antagonist, or administration of m-AMPH in a 4 degrees C environment, prevented or attenuated m-AMPH-induced hyperthermia, behavioral activation, and injury to striatal DA terminals and parietal cortical cell bodies. Animals pretreated with a DA transport inhibitor prior to m-AMPH showed hyperthermia, behavioral activation, and parietal cortical cell body injury, but they did not show striatal DA terminal injury. Pretreatment with a 5HT transport inhibitor failed to prevent m-AMPH-induced damage to striatal DA terminals or parietal cortical cell bodies. Animals given four injections of SAL in a 37 degrees C environment became hyperthermic, but showed no injury to striatal DA terminals or cortical cell bodies. The ability of the DA transport inhibitor to block m-AMPH-induced striatal DA damage, but not cortical injury, and the inability of hyperthermia alone to cause the cortical cell body injury suggests that m-AMPH-induced behavioral activation and hyperthermia may both be necessary for the subsequent parietal cortical cell body damage.     

Caffeine attenuates CNS oxygen toxicity in rats

We tested the effect of caffeine, on hyperoxia-induced seizures. Thirty-seven rats with chronic cortical electrodes were injected i.p. with caffeine (1.25, 2.5, and 10 mg/kg) or vehicle before exposure to 0.5 MPa oxygen and 17 rats to oxygen with 5% CO2 at 0.5 MPa. EEG monitoring and spectral analysis of EEG activity were carried out. Caffeine significantly prolonged the latent period to the onset of seizures (P < 0.05 in ANOVA), in a dose-related manner. Our results suggest that caffeine may be used in low doses for protection against hyperoxia-induced seizures.     

A dual mechanism for the anticonvulsant action of aminooxyacetic acid

The intramuscular injection of aminooxyacetic acid (AOAA) into mice elevated the concentration of gamma-aminobutyric acid (GABA) in the brain, inhibited glutamic acid decarboxylase activity and delayed the onset of isonicotinic acid hydrazide induced seizures. Analyses of these results and of those obtained previously by the authors and other workers indicated that the anticonvulsant action of AOAA involved two mechanisms. One, involving GABA metabolism, was most effective 6 h after AOAA administration, and the other, not involving GABA, was maximally effective 1.5 h after AOAA injection and was completely absent after 6 h. Depending on the convulsant agent under study, the mechanism of the anticonvulsant action of AOAA was purely of the GABA type, purely of the non-GABA type or a combination of both types.