gamma-Acetylenic GABA produces axon-sparing neurodegeneration after focal injection into the rat hippocampus.

In exploring the recently discovered phenomenon of indirect excitotoxicity, we noted that intrahippocampal injections of the nonspecific aminotransferase inhibitor gamma-acetylenic GABA (GAG; 60-240 nmol) caused excitotoxic lesions in rats. When assessed 3 days following the injection, GAG was shown to be approximately equally toxic to CA3/hilar neurons and CA1 pyramids, while CA2 neurons and granule cells were clearly less vulnerable. Choline acetyltransferase activity, a marker of extrinsic afferents, remained unchanged in the GAG-lesioned hippocampus, indicating the axon-sparing nature of the insult. In contrast, a lesion caused by 240 nmol of GAG resulted in a significant reduction in 3H-MK-801 binding, which was used as a marker for NMDA receptor-bearing hippocampal neurons. GAG-induced lesions were blocked by the NMDA receptor antagonists MK-801 and AP7 but were not influenced by the nature of the anesthetic used during surgery. Iontophoretic application of GAG did not excite CA1/CA3 cells in the rat hippocampus. In vitro, GAG proved to be a relatively potent inhibitor (IC50: 43 microM) of kynurenine aminotransferase, the biosynthetic enzyme of the endogenous neuroprotectant kynurenic acid. GAG also inhibited the neosynthesis of kynurenic acid in hippocampal slices (IC50: 790 microM). Thus, GAG shares several characteristics of the recently described indirect excitotoxin aminooxyacetic acid (AOAA; Exp. Neurol. 113: 378, 1991). GAG and AOAA appear to belong to a new family of excitotoxic agents which produce lesions indirectly by metabolic derangement and/or inhibition of kynurenate production.

Sequential neuropathology of dogs treated with vigabatrin, a GABA-transaminase inhibitor.

Vigabatrin (Sabril) is a gamma-aminobutyric acid-transaminase (GABA-T) inhibitor that is effective in the treatment of certain types of drug-resistant or uncontrolled epilepsy but is known to cause microscopic vacuolation (intramyelinic edema) in the brains of treated rats, mice, and dogs. The effects of high oral doses (300 mg/kg/day) of vigabatrin administered orally to Beagle dogs were studied during treatment weeks 1-12 and recovery weeks 13, 14, 16, 20, 24, and 28. Emesis, loose stools, and anorexia and 3 drug-related deaths were observed during the first 4 wk of treatment but were virtually nonexistent thereafter because of adaptation to the drug aided by food supplementation. In more sensitive areas of the brain (columns of the fornix, thalamus, and hypothalamus), microscopic quantitative differences between background vacuolation in controls and drug-related vacuolation in treated dogs could be delineated after 4 wk, generally reached highest levels of severity between 8 and 12 wk, and were reversible upon cessation of dosing. Inhibition of brain GABA-T and elevation of brain GABA were noted after 1 wk of treatment. During the course of treatment vigabatrin ranged between 4-17 nmol/ml (plasma) and 42-1,570 nmol/ml [cerebrospinal fluid (CSF)] while CSF GABA concentrations were 4-32 nmol/ml (treated dogs) and 0.1-0.6 nmol/ml (control dogs). Although the cause of vigabatrin-induced microvacuolation is unknown, the results of the study demonstrated that GABA-T inhibition with subsequent GABA elevation occurred within the first week of treatment and was followed by the onset of detectable microvacuolation several weeks later.

Relative anticonvulsant effects of GABAmimetic and GABA modulatory agents.

Anticonvulsant properties of compounds that enhance GABA-mediated inhibition through modulatory sites on the GABAA receptor [phenobarbital (PB), clonazepam (CZP), alpha-ethyl-alpha-methyl-gamma-thiobutyrolactone (alpha-EMTBL)] were compared with anticonvulsant effects of compounds believed to be antagonists at these modulatory sites (Ro15-1788 and alpha-isopropyl-alpha-methyl-gamma-butyrolactone gamma-IMGBL)] and to 4,5,6,7-tetrahydroisoxazolo-[4,5-c]-pyridin-3-ol (THIP, GABAA receptor agonist), (+/-) baclofen (GABAB receptor agonist), and gamma-vinyl GABA, a compound that increases endogenous GABA. The compounds were tested for their ability to block experimental seizures caused by maximal electroshock, pentylenetetrazol, picrotoxin, methyl-6,7-dimethoxy-4-ethyl-beta-carboline-3-carboxylate (DMCM), bicuculline (BIC), aminophylline, strychnine, and t-butyl-bicyclophosphorothionate (TBPS) in mice. CZP blocked all but strychnine seizures. PB was also highly effective, blocking all but TBPS seizures. alpha-EMTBL, representing a new class of experimental anticonvulsant drugs, prevented all seizures except strychnine (STR)- and aminophylline-induced seizures. The antagonists are effective only against one convulsant stimulus. Ro15-1788 and alpha-IMGBL prevented only DMCM- and pentylenetetrazol (PTZ)-induced seizures, respectively. THIP and gamma-vinyl GABA both blocked only BIC and picrotoxin seizures. Baclofen had no anticonvulsant activity. These data demonstrate that compounds that increase neuronal inhibition by potentiating the action of GABA have a broader spectrum of anticonvulsant action than either antagonists or GABAmimetic agents or compounds that increase endogenous GABA.

Pharmacology of vigabatrin.

Vigabatrin (gamma-vinyl GABA) is a relatively new antiepileptic drug. Vigabatrin increases the concentration of gamma-aminobutyric acid (GABA) in the brain by inhibiting the major GABA metabolizing enzyme, GABA transaminase. Controlled clinical trials have demonstrated an excellent antiepileptic effect of vigabatrin, especially in the treatment of partial epilepsies. Long-term evaluations have shown no signs of tolerance development. Vigabatrin decreases the plasma concentration of phenytoin during concomitant therapy, the only drug with which an interaction seems to occur. In general, vigabatrin is well tolerated. Psychotic reactions occur in 3-6% of patients. Other frequent side effects are sedation and weight increase. Chronic vigabatrin intoxication in animals caused development of intramyelinic oedema, appearing as microvacuoles in brain white matter. No microvacuolation has been observed in humans, even after long-term treatment. Vigabatrin seems a very valuable new antiepileptic drug.

Chronic toxicity studies with vigabatrin, a GABA-transaminase inhibitor.

The GABA-transaminase inhibitor, vigabatrin, has been shown to have a rather low degree of acute toxicity in several animal species. Oral administration of the drug at 1,000 mg/kg/day for 2-4 weeks caused decreased food consumption and weight loss with resultant prostration and death in both rats and dogs. Dosages of 200 mg/kg/day were tolerated for a year without clinical signs in dogs, although rats suffered reduced weight gains and convulsions after 3-4 months when given the drug in the diet. The convulsions continued to occur frequently throughout the one-yr study, but abated 3-4 months after cessation of treatment. The only consistent histopathologic evidence of toxicity in rats and dogs has been the finding of intramyelinic edema (microvacuolation) in the brain, most notably in certain areas of white matter (cerebellum, reticular formation and optic tract in rats and columns of fornix and optic tract in dogs). No lesions were found in the spinal cord or peripheral nervous system. It took several weeks for the microvacuolation to develop, even at high dosages, but it did not continue to progress thereafter, even though a slight effect was noted at dosages as low as 30-50 mg/kg/day after one yr of treatment. The intramyelinic edemia disappeared within a few weeks after treatment was withdrawn. No residual effects were observed in dogs, whereas rats exhibited swollen axons and microscopic mineralized bodies in the cerebellum. Monkeys exhibited no adverse clinical effects except for occasional loose stools at 300 mg/kg/day. After 16 months of oral treatment at 300 mg/kg/day any suggestion of intramyelinic edema was considered to be equivocal, and there was no evidence of any effect in the 50 or 100 mg/kg/day monkeys after 6 yr of treatment. Higher doses caused chronic diarrhea, thus limiting the dosage in this species. Vigabatrin was shown to be well absorbed in rat, dog and man, whereas dose-limited absorption occurred in the monkey. Metabolism is practically nil in all 4 species and the primary elimination pathway is by glomerular filtration. Because vigabatrin is an irreversible inhibitor of GABA-transaminase and the enzyme has a slow turnover rate, plasma levels of the drug are not indicative of its pharmacologic activity. For this reason cerebrospinal fluid levels of GABA and vigabatrin were evaluated, with considerable species differences being noted. The significance of these differences in relation to the differences in toxic response is discussed.

Neuropathology of vigabatrin.

1. Neuropathological changes in experimental animals have been observed with vigabatrin treatment in mice, rats and dogs. 2. These changes have comprised intramyelinic oedema which is reversible on cessation of treatment. 3. In human studies so far, no intramyelinic oedema has been noted. It is not clear whether humans will show the neurotoxicity observed in animals; close monitoring of patients is indicated.

Micro-vacuolation in rat brains after long term administration of GABA-transaminase inhibitors. Comparison of effects of ethanolamine-O-sulphate and vigabatrin.

Two "suicide" inhibitors of GABA-aminotransferase which are known to raise the concentration of GABA in vivo and to have anti-convulsant properties, have been compared for the extent to which they produce micro-vacuoles in the brains of rats. The compounds gamma-vinyl-GABA (Vigabatrin) and ethanolamine-O-sulphate were administered orally for six months to rats at doses that produced the same increase in brain GABA levels. Micro-vacuolation was found to be present in the brains of animals treated with either compound but to be more severe in those treated with Vigabatrin. A quantitative assessment using computerised image analysis revealed that both the number of vacuoles, and the area occupied by them, was twice as high in the Vigabatrin treated animals as in those treated with ethanolamine-O-sulphate. This quantitative difference could be seen to be due to the fact that in the Vigabatrin treated animals the vacuoles extended into the white matter tracts between the cerebellar folia whereas in those animals treated with ethanolamine-O-sulphate it was confined to the roof nucleus.

A study of the effects of vigabatrin on the central nervous system and retina of Sprague Dawley and Lister-Hooded rats.

Vigabatrin (gamma-vinyl GABA), an enzyme-activated, irreversible inhibitor of GABA transaminase, was administered orally to albino Sprague Dawley and pigmented Lister-Hooded rats. A dose-dependent retinal lesion characterized histologically by disruption of the outer nuclear layer was observed in the Sprague Dawley rat but not in Lister-Hooded rats, indicating that this alteration is related to the absence of pigment. The lesion is similar to that induced in albino rats by light and certain drugs. In addition, myelin vacuolation of the brain was observed in both rat strains, consistent with the findings of other toxicity studies with vigabatrin. In all cases, the vacuolation was limited to myelinated tracts and resulted from separation of the myelin sheath at the intraperiod line. There was no evidence of demyelination, axonal degeneration or damage to contiguous structures in the affected areas. The vacuolation is histologically similar to that induced in rats by certain other compounds such as isoniazid, hexachlorophene, and triethyltin, but differs in that it is focal in distribution, it is limited to the brain, and is reversible upon cessation of treatment.

Promoting effects of various agents in rat urinary bladder carcinogenesis initiated by N-butyl-N-(4-hydroxybutyl)nitrosamine.

The effects of various chemicals on the development of neoplastic lesions in the urinary bladder were investigated in male F344 rats given 0.05% N-butyl-N-(4-hydroxybutyl)nitrosamine (BBN) as an initiator in their drinking water for 4 weeks. The compounds tested, indomethacin, acemetacin, epsilon-aminocaproic acid (EACA), diphenyl, allopurinol and acetaminophen (AAP), were added to the diet or drinking water for 32 weeks, and all animals were killed at the end of week 36. Of the chemicals tested, only diphenyl significantly increased the incidences and average numbers (per 10 cm basement membrane) of papillary or nodular hyperplasias (PN hyperplasia), papillomas and carcinomas of the urinary bladder over those in animals treated with BBN alone. These findings show that diphenyl is a promoter of urinary bladder carcinogenesis in male F344 rats.

Long-term study of gamma-vinyl GABA in the treatment of epilepsy.

The purpose of this study was to investigate the long-term efficacy and tolerability of gamma-vinyl GABA (GVG) in the treatment of epilepsy. 36 patients with severe therapy resistant epilepsies participated, the majority exhibiting complex partial seizures. The mean follow-up period was 9.3 months. GVG was administered as add-on therapy, to keep serum levels of concomitant treatment constant. The mean dose of GVG was 2.6 g's per day. Fifty-six per cent of the patients, including three patients with juvenile myoclonic epilepsy, experienced more than a 50% reduction in seizure frequency. No signs of tolerance development to the antiepileptic effect of GVG was demonstrated. Two patients were withdrawn from GVG treatment due to increased seizure frequency, and two due to side effects in the form of vomiting and nausea. Incidentally, the side effects observed were harmless and transient. Fifty per cent of the patients experienced no side effects at all. GVG seems to be a valuable antiepileptic compound. The results of this long-term study confirm observations from several short controlled trials.