Retinal and Systemic Toxicity of Vigabatrin Is Driven by the S-Enantiomer in the Long Evans Rat.

In this study, we assessed the toxicity and toxicokinetics of racemic vigabatrin and its S- and R-enantiomers (vigabatrin consists of 50:50% of the two enantiomers) by administering doses of the three test articles to male Long Evans rats via oral gavage. The animals were housed under high-intensity light conditions and the study consisted of an escalating dose phase and a 21-day fixed-dose phase. Systemic toxicity of vigabatrin appears to be due to the Vig-S-enantiomer only, as increasing doses of Vig-S or Vig-RS caused body weight loss, decreased food consumption, and affected activity. Administration of the Vig-R-enantiomer did not cause any such effects. Systemic exposure to R- and S-enantiomers was approximately linear with dose. Compared to administration of the racemate, there appeared to be a tendency for animals to take up higher amounts of Vig-R and lower amounts of Vig-S when administered as enantiomer. Bilateral retinal atrophy was observed in the fixed-dose phase in rats receiving Vig-S (either alone or as part of Vig-RS) and was characterized by irregular thinning and disorganization of the outer nuclear layer and thinning of the photoreceptor layer. The administration of the R-enantiomer alone did not cause any microscopic retinal change.

Gelucire and Gelucire-PEG400 formulations; tolerability in species used for non-clinical safety testing after oral (gavage) dosing.

The selection of a vehicle for oral formulations of compounds to be used in non-clinical safety studies is a challenge for poorly soluble compounds. Typically a compromise between solubility and tolerability has to be reached. Vehicle tolerability data are not readily available for a number of vehicles, and a series of oral tolerability studies were, therefore, conducted with Gelucire and Gelucire:PEG400 formulations in rats, dogs and minipigs in order to determine tolerable daily dose volumes in these species. Gelucire and Gelucire:PEG400 formulations were assessed in studies for up to 5 days in minipigs, 7 days in rats and up to 39 weeks in dogs. Gastrointestinal side effects in terms of soft and/or liquid faeces were noted in all species, but the sensitivity to these effects differed between species with the dog being the most sensitive. It was concluded that Gelucire:PEG400 (90:10) was tolerated in Beagle dogs when administered at 1 ml kg(-1) once daily for 39 weeks, and 100% Gelucire was tolerated in the rat and the minipig when administered once daily at 5 ml kg(-1) for 5 days. Copyright © 2016 John Wiley & Sons, Ltd.

Detection of Mild and Reversible Neurohistopathological Changes in the Brain of Juvenile (Preweaned) Beagle Dogs Treated with Vigabatrin for up to 91 Days.

Neurohistopathological changes in the brain were assessed in juvenile beagle dogs given vigabatrin at 30 or 100 mg/kg/day by oral gavage from postnatal day 22 (PND22) until 16 weeks of age (PND112), when brain myelination is considered to reach the adult stage in dogs. Separate subgroups were treated from PND22 to PND35 or PND36 to PND49 to assess early effects. In addition to extensive brain histopathology, there were assessments of toxicokinetics, clinical condition, body weight, organ weights, and macroscopic pathology. In animals treated for 14 days from PND22, minimal or slight vacuolation was seen in the neuropil of the septal nuclei, hippocampus, hypothalamus, thalamus, cerebellum, and globus pallidus at 100 mg/kg/day and minimal vacuolation in the thalamus, globus pallidus, and cerebellum at 30 mg/kg/day. In animals given 100 mg/kg/day for 91 days from PND22, minimal or slight vacuolation was observed only in the hippocampus, hypothalamus, and thalamus. No vigabatrin-related brain vacuolation was observed in animals given 30 or 100 mg/kg/day for 14 days from PND36. Clear evidence of recovery was observed after 14-day and 6-week off-dose periods that followed treatment from PND22 to PND35 or PND22 to PND112, respectively.

Use of barusiban in a novel study design for evaluation of tocolytic agents in pregnant and neonatal monkeys, including behavioural and immunological endpoints.

The oxytocin receptor antagonist barusiban, currently being developed for treatment of preterm labour, was investigated in pregnant cynomolgus monkeys with a 9-month postnatal follow-up of their offspring. The nature of barusiban, its indication, and the potential exposure of pre- and postnatal infants entailed the design of a unique protocol to investigate all aspects of maternal and offspring well-being. Barusiban was administered to the mothers from gestation day 85 until delivery with daily subcutaneous dosages up to 2.5mg/kg body weight/day. There were no test article-related effects seen in the mothers at any time during the study. The postnatal examination of offspring included routine toxicological parameters, as well as specialised investigation of the immune, cardiovascular, renal and central nervous systems, including a full behavioural assessment. A full pathology examination of offspring was performed at the end of the 9-month postnatal period. No adverse infant findings occurred.

Intramuscular injection of hypertonic saline: in vitro and in vivo muscle tissue toxicity and spinal neurone c-fos expression.

Intramuscular injection of hypertonic saline (4-6% NaCl) is widely used to induce muscle pain in volunteers. The quality of the pain is comparable to clinical muscle pain with localised and referred pain. The objective was to evaluate the muscle toxicity of hypertonic saline by characterisation of 1) cytotoxicity in vitro, 2) local muscle toxicity in rabbits and 3) number of spinal dorsal horn neurones expressing c-fos after intramuscular injection in pigs as an indicator of nociception. Rat myocyte cultures and erythrocyte suspensions were treated with hypertonic NaCl solutions. The creatine kinase activity remaining in the myocytes and haemolysis were measured. Groups of six rabbits were given an intramuscular injection of 0.5 ml of 0.9, 3 or 6% NaCl. Three days later, creatine kinase activity was determined in injection site muscle tissue and normal contralateral muscle. The amount of injection site muscle tissue totally depleted of creatine kinase was calculated. Groups of two pigs were given an intramuscular injection of 3.0 ml of 6% NaCl. The spinal cord was sampled 1, 2 or 3 hr later and processed for stereological quantification of the number of dorsal horn neurones expressing c-fos. Saline was not toxic in vitro at 0.9-6%, but toxic to erythrocytes at 7% or higher and rat myocytes at 15% or higher. No muscle toxicity was seen in rabbits. The number of dorsal horn neurones expressing c-fos was not above basal level. In conclusion, 6% saline caused no in vitro or in vivo toxicity in sensitive models. Consequently, the pain caused by intramuscular injection of hypertonic saline is most likely not related to tissue damage. Consistently, intramuscular injection of 6% NaCl did not activate dorsal horn neurones in pigs to express c-fos beyond basal level.

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.

Vigabatrin-induced CNS changes in juvenile rats: Induction, progression and recovery of myelin-related changes.

The purpose of this study was to expand on the knowledge previously published on the central nervous system effects of Vigabatrin in juvenile animals. By employing extended sectioning of the brain and by using four different tissue staining techniques it is demonstrated that oral administration of Vigabatrin to juvenile rats (treatment periods of post-natal day (PND) 4-7, 7-14 or 14-30) will cause histological CNS changes at dose levels of 15 and 50mg/kg/day, but not at a dose level of 5mg/kg/day. No evidence of neuronal degeneration or gliosis was seen at any stage of treatment. Consistent with previous reports microvacuolation, as well as effects on myelination and on oligodendrocytes were recorded. The present study expands on these findings and demonstrates that the variation in the location of the vigabatrin-induced lesions in the juvenile rat brain (both neuropil vacuolation and reduction of myelin) appears to be consistent with the process of myelination: In the youngest animals (PND 4-7) myelination occurs mainly in the hind brain (medulla oblongata and pons) where neuropil vacuolations is recorded. In animals dosed during PNDs 7-14 or during PNDs 14-30, the first changes were found in the thalamus. It seems likely that the earlier stages of myelination are more vulnerable to treatment related effects and the swollen oligodendrocytes seen as the initial change in the thalamus in animals treated during PNDs 4-7 and 7-14 represents an early stage in the development of the myelin lesion which is seen later as neuropil vacuolation.