The effects of taurine on vigabatrin, high light intensity and mydriasis induced retinal toxicity in the pigmented rat.

The overall purpose of this study was to establish a model that may be used for examining the effect of Vigabatrin-induced retinal toxicity in pigmented rats, and subsequently examine the possible effects of taurine on the retinal toxicity. In the first part of the study, pigmented Long Evans rats were subjected to combinations of induced mydriasis, low/high light intensities (40/2000 lx) and oral administration of near-MTD (Maximum Tolerated Dose) doses (200 mg/kg/day) of Vigabatrin for up to 6 weeks. The combination of mydriasis and high light intensity applied to Long Evans rats resulted in retinal damage that was increased by the administration of Vigabatrin. In the second part of the study Long Evans rats were subjected to combinations of induced mydriasis and high/low light intensity (40/2000 lx) while being orally administered low (30 mg/kg/day) or high (200 mg/kg/day) doses of Vigabatrin for up to 6 weeks. In addition, selected groups of animals were administered taurine via the drinking water (20 mg/ml), resulting in systemic taurine concentrations of approximately threefold the endogenous concentration. The combined results of the studies demonstrate that retinal damage can be induced in pigmented animals when combining mydriasis and high light intensity. Retinal damage was functionally evaluated by electroretinography (ERG), then confirmed by histopathology. While depending on mydriasis and high light intensity, administration of Vigabatrin increased the retinal toxicity and resulted in the formation of rosette-like structures in the retina in a dose-related manner. Administration of taurine did not alleviate the Vigabatrin-induced retinal toxicity, as demonstrated either functionally by ERG or morphologically, although systemic concentrations of 3-fold the endogenous levels were reached, and it was thus not possible to demonstrate a protective effect of taurine in these pigmented animals.

Intestinal absorption of the antiepileptic drug substance vigabatrin in Göttingen mini-pigs is unaffected by co-administration of amino acids.

The anti-epileptic drug substance vigabatrin is used against infantile spasms. In vitro evidence suggests that vigabatrin is transported via the proton coupled amino acid transporter (PAT1). The aim of the present study was to investigate whether the intestinal absorption of vigabatrin in vivo was mediated via PAT1 in non-rodents. This was investigated by oral co-administration of vigabatrin and PAT1-ligands to Göttingen mini-pigs. Vigabatrin had an oral absorption fraction (Fabs) of 75-80%, and the maximal plasma concentration (Cmax) was reached within 0.5-1.0 h (tmax). Co-administration of vigabatrin and amino acids generally did not significantly affect Fa, Tmax or Cmax. However, co-administration with sarcosine prolonged the time to reach Cmax. After co-administration with amino acids, vigabatrin absorption showed a slightly lowered onset. This may indicate an effect of amino acids on either the rate of gastric emptying or an effect directly on the absorption of vigabatrin, possibly via inhibition of PAT1 or another drug transporter. In conclusion, co-administration of PAT1-ligands together with vigabatrin did not significantly alter the pharmacokinetic profile of vigabatrin.