Pathophysiology of generalized penicillin epilepsy in the cat: the role of cortical and subcortical structures. I. Systemic application of penicillin

The effects of transient functional depression of the thalamus on spindles and on bilateral synchronous epileptic discharges of feline generalized penicillin epilepsy

A transient functional depression of thalamic activity (TFDTA) was induced in acute experiments in cats by the microinjection of 25% KCl into the thalamus. Spontaneous and evoked thalamic electrical activity was markedly depressed at the site of KCl microinjection. Spread of this depression to other thalamic areas often occurred, mainly when KCl was injected into the midline thalamus. In normal cats both spontaneous and evoked cortical spindle bursts as well as other evoked thalamocortical responses were reduced or abolished during the KCl-induced TFDTA. The generalized spike-and-wave discharges of feline generalized epilepsy were also suppressed for the duration of TFDTA, while incidental focal cortical interictal and ictal epileptic discharges, as well as generalized tonic-clonic seizure discharge, remained unaffected. The same effects were observed in animals with lesions of the mesencephalic reticular formation, indicating that the suppression of spindles and spike-and-wave discharges cannot be attributed to a release of the activity of the reticular formation by the TFDTA. An unexplained occurrence of generalized tonic-clonic EEG seizure was observed in most cases late after thalamic KCl microinjection, usually after the spike-and-wave discharges had recovered. These data are consistent with the hypothesis that the spontaneous bilaterally synchronous epileptic bursts of feline generalized penicillin epilepsy are not only closely related to spindles but are crucially dependent on thalamic inputs to the cerebral cortex.

Activating effects of homotaurine and taurine on corticoreticular epilepsy

Homotaurine and taurine are two powerful inhibitory aminoacids with anticonvulsant properties against various experimental models of focal epilepsy. This study reports on their effects in the feline model of corticoreticular epilepsy induced by parenteral administration of large amounts of penicillin. Both aminoacids, but particularly homotaurine, remarkably potentiate epileptiform discharges in cats. Brainstem transection at the precollicular level does not modify the activation, thus ruling out the intervention of mesoromboencephalic structures in the observed effect. The opposing action of these two amino acids on focal epilepsy as compared to corticoreticular epilepsy suggests that the two types of epileptiform activity stem from very different pathophysiological mechanisms. Homotaurine is a powerful GABA agonist that exerts a central action upon parenteral administration. Other GABA analogs such as muscimol, imidazole acetic acid, and gamma-hydroxybutyrate have been reported to potentiate experimental models of spike and wave epilepsy. Thus, the activating effects of homotaurine in this epilepsy model are in keeping with the demonstrated GABAmimetic properties of the compound.

Spontaneous generalized spike-wave discharges in the electrocorticograms of albino rats

Generalized epileptiform discharges occur spontaneously in the electrocorticograms of some albino laboratory rats. These discharges occur during periods of quiet wakefulness, are composed of 6-10/sec spike-wave complexes, are accompanied by locomotor arrest and often by mild clonic facial movements. The occurrence of these discharges is unrelated to surgical procedures used to create chronic recording preparations. Similar discharges and behavior have been induced in controls by injections of pentylenetetrazol.

The role of the corpus callosum in bilateral interhemispheric synchrony of spike and wave discharge in feline generalized penicillin epilepsy

In this study on interhemispheric synchrony of spike and wave discharges in feline generalized penicillin epilepsy, four groups of cats were treated in the following manner: Group A underwent complete section of the corpus callosum and anterior commissure; group B underwent division of the massa intermedia alone; group C underwent partial section of the corpus callosum; and in group D, a slab of the cortex on one side, comprising the middle parts of the lateral and suprasylvian gyri, was severed from all its subcortical inputs, without disturbing its connections with the opposite hemisphere through the corpus callosum. Two weeks after surgery or later the cats received an i.m. injection of penicillin. Bilateral synchrony of the epileptic discharges was abolished in group A, but not in group B. In group C, bilateral synchrony of the epileptic bursts was impaired, but not abolished. In group D, epileptic bursts synchronous with those occurring in the intact hemisphere continued to occur in the slab, but at lower amplitude. It is concluded that the corpus callosum is the main, if not the exclusive, pathway ensuring bilateral synchrony of the epileptic discharges of feline generalized penicillin epilepsy.

Hypersomnia with simultaneous waking and sleep patterns in the electroencephalogram. A case report with neurotransmitter studies

A mildly dyslexic boy of 11 years, with no neurological deficit or history of epileptic seizures, had marked hypersomnia for 2 years, which was most pronounced in the morning hours. Repeated EEG studies and power spectral analysis revealed simultaneous posterior alpha rhythm and sleep patterns (spindles, vertex waves, K complexes) over vertex and frontocentral regions, while the patient was behaviorally awake. Bilateral synchronous anterior spikes were frequently noted in association with sleep patterns. A polysomnogram over 24 h confirmed excessive sleep, night and day (especially morning hours) and there was evidence of a large REM sleep percentage (on EMG and EOG basis) while the EEG had predominantly non-REM sleep patterns. Special neurotransmitter studies were performed in view of a presumed disturbance affecting the neurobiochemical sleep regulation. These studies were based on CSF metabolite levels and provided evidence for a high serotonin metabolite (5HIAA) level. It is tempting to hypothesize that the biochemical disturbance has led to encroachment of non-REM sleep patterns on both wakefulness and REM sleep. Further discussion deals with the bilateral-synchronous spike activity and its relationship to arousal patterns in sleep.

Effects of changes in cortical excitability upon the epileptic bursts in generalized penicillin epilepsy of the cat

Previous studies had suggested that the epileptic bursts of feline generalized penicillin epilepsy represent the response of hyperexcitable cortex to thalamocortical volleys normally evoking spindles. If this were the case, it should be possible to convert the epileptic bursts of generalized penicillin epilepsy into spindles by decreasing the excitability of cortical neurons. In cats exhibiting the EEG signs of feline generalized penicillin epilepsy cortical excitability was decreased by hypoxia, by the topical application to the cortex of KCl (inducing spreading depression), barbiturates, GABA, AMP or noradrenaline. During generalized penicillin epilepsy, hypoxia and KCl-induced spreading depression abolished epileptic bursts which were replaced by spindles. When spindles and epileptic complexes occurring in the same animal were compared, a direct correlation between the frequencies of these two rhythms could be demonstrated, that of the epileptic complexes being about half that of the spindle waves. These observations support the hypothesis that the epileptic bursts of feline generalized penicillin epilepsy are induced by thalamocortical volleys normally involved in spindle genesis. Topical cortical applications of barbiturates, GABA, AMP and noradrenaline reduced or inverted the negative spikes of the spike and wave complexes, while augmenting the negative slow waves, or revealing them clearly in instances in which they had been poorly developed. This effect is interpreted as being due to a selective inactivation of the superficial cortical layers. That topical cortical application of barbiturates, GABA, AMP and noradrenaline was capable of transforming into typical spike and wave complex epileptic bursts, which had not previously conformed to this pattern, indicates that the intracortical electrophysiological events of typical and atypical epileptic bursts in feline generalized penicillin epilepsy are fundamentally the same and reflect an alternation between excitatory and inhibitory sequences.

Chronically isolated cerebral hemisphere in the cat: effects of parenteral administration of penicillin

Brain electrical activity (EEG) of cats with chronic, complete, neural isolation of the cortex of an entire cerebral hemisphere was studied prior to and following intramuscular administration of penicillin (250,000--300,000 units/kg). The most prominent feature of the isolated hemisphere's EEG during base-line recordings was irregular, aperiodic, slow-wave activity with intermittent sharp waves and occasional spike discharges. Following penicillin administration there was an increase in the number of spikes and sharp waves in the isolated hemisphere and an increase in amplitude of the background activity. Simultaneously recorded EEG activity of the intact hemisphere demonstrated the paroxysmal burts of sharp waves or spike-wave complexes that have been described previously in normal animals. There was complete independence of the electrical activity recorded from intact and isolated hemispheres. These results indicate that intramuscularly administered penicillin can exert a convulsant effect on cortical structures in the absence of subcortical connections, but the generalized epileptiform activity seen in normal animals is dependent on thalamocortical connections.

Ethanol dependence in the rat: role of non-specific and limbic regions in the withdrawal reaction

Chronic bipolar electrodes were implanted in cortical, limbic, diencephalic and mesencephalic regions of the rat. Following recovery from surgery the rats were maintained for 14--26 days on a liquid diet in which 35--42% of total calories were provided by ethanol. Following ethanol withdrawal, electrographic and behavioral monitoring was continued for 8--10 h. The withdrawal of ethanol resulted in the time-dependent appearance of a variety of withdrawal signs including tail arching, ataxia, rigidity, tremor and spontaneous and audiogenic convulsions. These behavioral signs were accompanied by the development of epileptiform abnormalities across wide-spread brain regions. Analysis of preconvulsive spike activity revealed a greater spike frequency in limbic, mesencephalic and non-specific diencephalic regions, as compared to those in cortex and specific diencephalon. Seizure discharge during the tonic-clonic phase of the primary audiogenic convulsion was initiated in the mesencephalon or amygdala, but spread rather extensively to the remainder of the brain. In those instances, however, where multiple convulsions occurred following the audiogenic convulsions, there was a marked decline in spread of seizure discharge to the cortex. These results were interpreted to support the notion that some degree of neuroanatomical specificity exists in the genesis of epileptiform abnormalities during ethanol withdrawal. A comparison of these results with those studying the neural mechanisms underlying other forms of generalized epilepsy was made. It is hypothesized that central pacemaking regions such as medial thalamus or reticular formation may serve to organize isolated epileptiform activity into coherent patterns of paroxysmal activity throughout the brain during the ethanol withdrawal syndrome.