The effects of GABA-ergic drugs on enkephalin-induced motor seizure phenomena in the rat

Brain regions and genes affecting myoclonus in animals

Myoclonus is defined as large-amplitude rhythmic movements. Brain regions underlying myoclonic jerks include brainstem, cerebellum, and cortex. Gamma-aminobutyric acid (GABA) appears to be the main neurotransmitter involved in myoclonus, possibly interacting with biogenic amines, opiates, acetylcholine, and glycine. Myoclonic jumping is a specific subtype seen in rodents, comprising rearing and hopping continuously against a wall. Myoclonic jumping can be seen in normal mouse strains, possibly as a result of simply being put inside a cage. Like other types, it is also triggered by changes in GABA, 5HT, and dopamine neurotransmission. Implicated brain regions include hippocampus and dorsal striatum, possibly with respect to D(1) dopamine, NMDA, and δ opioid receptors. There is reason to suspect that myoclonic jumping is underreported due to insufficient observations into mouse cages.

Use of naloxone in valproic acid overdose: case report and review

We present a case of a mixed ingestion of valproic acid, gabapentin, mexilitine, and ethanol with central nervous system depression that was reversed by naloxone. This report represents the fourth case demonstrating the antidotal efficacy of naloxone in reversing central nervous system depression associated with acute valproic acid overdose. Increasing clinical experience will more fully elucidate indications for, and optimal dosing of, naloxone in valproic acid toxic states.

Pro- and anticonvulsant actions of morphine and the endogenous opioids: involvement and interactions of multiple opiate and non-opiate systems

The proconvulsant actions of high doses of systemic morphine are probably mediated by 3 different systems. One of them produces non-convulsant electrographic seizures and can be activated separately from the others both by intracerebroventricular injections as well as microinjections into discrete subcortical areas. The enkephalins and beta-endorphin, when administered to the same loci, produce similar effects. Pharmacological evidence suggests that specific opiate receptors of the delta-subtype mediate the epileptiform effects produced by this system. The second system mediating proconvulsant effects of systemic morphine is not mediated by stereo-specific opiate receptors. It produces behavioral convulsions, and the GABA-ergic system has been implicated in its action. A third proconvulsant action of systemic morphine can be activated separately from the other two systems by administering this compound with other convulsive agents or manipulations. Specific mu-type opiate receptors are implicated in this effect. In addition to potent proconvulsant effects, systemic morphine also has anticonvulsant properties which are mediated by specific opiate mu-receptors. The conditions under which morphine acts as a proconvulsant rather than an anticonvulsant agent are, as yet, not understood.

Correlation between the distribution of 3H-labelled enkephalin in rat brain and the anatomical regions involved in enkephalin-induced seizures

The correlation between the distribution of the intraventricularly (i.v.t.) administered delta agonist [3H](D-ala2,D-leu5)-enkephalin ([3H]DADL) and the anatomical regions involved in enkephalin-induced seizures has been studied in rat by using an autoradiographic method and recording of the electromyogram (EMG) and the electroencephalogram (EEG). The results indicate that within 10 min, the radioactivity of the intraventricularly administered drug reached all parts of the ventricular system, including the central canal of the spinal cord. However, within 2.5 min after the intraventricular administration of [3H]DADL, which corresponds to the onset of DADL-induced seizures, the substance appeared mainly in the left lateral ventricle and occasionally in the third ventricle. During the first 2.5 min the substance penetrated regularly into the surrounding periventricular tissue of the striatum, septum and hippocampus to a depth of about 100 microns. The most intensive and long-lasting epileptic discharges, exceeding 30 min were observed in the hippocampus, in contrast to the mild and short-lasting electrophysiological responses of the septum and corpus striatum. The experiments suggest that the short onset of enkephalin-induced excitatory phenomena is due to the rapid distribution and penetration of the substance in the surrounding periventricular tissue. According to these data, it is proposed that activation of delta opiate receptors, localized within the first 100 microns of the periventricular tissue, mainly in the hippocampus, is essential for the triggering of endorphin-induced seizure activity.

Possible mechanism of digoxin-induced convulsions

Intraventricular (IVT) administration of digoxin (7.5 micrograms) induced 'popcorn-type' convulsions in rats. Though the convulsions looked similar to morphine-induced seizures, naloxone failed to antagonize these effects. Other anticonvulsants like phenobarbitone, ethosuximide, or GABAergic substances like piracetam and semicarbazide also had no protective effect against digoxin-induced convulsions. While calcium chloride potentiated these effects of digoxin, phenytoin, magnesium chloride, and potassium chloride treatment showed blocking actions. These observations suggest the involvement of Na/K-ATPase system in digoxin-induced convulsions. Clonidine and diazepam also provided protection against digoxin-induced convulsions through an unknown mechanism.