The effect of di-isopropyl 1,3 dithiol-2-ylidenemalonate (malotilate) on the hepatic changes induced by ethanol administration in the rat.

The sulphur-containing drug, di-isopropyl-1,3-dithiol-2-ylidenemalonate (Malotilate) protects against the increase in hepatic triglyceride concentration after acute ethanol administration (either 6 g/kg p.o. or 2 g/kg i.p.) in rats. The compound had no influence on the increased hepatic NADH:NAD ratio (measured as the lactate:pyruvate and 3-hydroxybutyrate:acetoacetate ratios) after acute ethanol dosing (2 g/kg i.p.), but was found to lower hepatic acetaldehyde concentrations and prevent some of the disturbances in lipid metabolism observed in liver slices from ethanol-treated animals (e.g. decreased oxidation of [1-14C]palmitate to 14CO2) after this ethanol dose. The drug did not inhibit ethanol metabolism in this acute experiment. Administration of Malotilate to Wistar rats (100 mg/kg/day orally) during chronic feeding of ethanol as 36% of the total calorie intake in a liquid diet, resulted in a lower intake of the alcohol-containing diet by ethanol-fed animals and reduced body weight gain in rats which received the drug, without blood ethanol levels or the ethanol intake (expressed in g/kg body weight/day) being affected. In ethanol-fed animals, Malotilate prevented the production of fatty liver and the adaptive increase in the ethanol elimination rate (EER) normally seen in ethanol-fed animals, although the drug actually caused a slight increase in EER in glucose pair-fed controls. Malotilate did not significantly decrease the degree of induction of microsomal cytochrome P-450 by ethanol, but the increase in aniline hydroxylation was much less marked in animals receiving ethanol and Malotilate, suggesting that the activity of the inducible microsomal ethanol oxidising system (MEOS) may be reduced by the compound. Determination of hepatic acetaldehyde concentrations during ethanol feeding, and during an acute ethanol challenge test following long-term ethanol treatment showed that the compound significantly lowered the level of this ethanol metabolite in the liver under both circumstances. This reduction of hepatic acetaldehyde concentrations, probably resulting in part from the reduced EER as well as increased low-Km aldehyde dehydrogenase activities and glutathione contents seen in the livers of Malotilate-treated rats, are possible mechanisms by which the drug protects against triglyceride accumulation after ethanol administration.