Enhanced Plasma Availability of the Metabolites of Albendazole in Fasted Adult Sheep

Lifschitz, A., Virkel G., Mastromarino, M. and Lanusse C., 1997. Enhanced plasma availability of the metabolites of albendazole in fasted adult sheep. Veterinary Research Communications, 21 (3), 201-211The influence of fasting prior to treatment and of dosing rate on the plasma availability and disposition kinetics of albendazole (ABZ) and its sulphoxide (ABZSO) and sulphone (ABZSO2) metabolites was studied in adult sheep grazing on pasture. A micronized suspension of ABZ was administered orally at either 7.5 mg/kg (group A) or 11.3 mg/kg (group C) to sheep fed ad libitum, and at 7.5 mg/kg to sheep subjected to a 24 h fasting period prior to treatment (group B). Blood samples were taken serially over 96 h after treatment, and the plasma was analysed for ABZ and its metabolites by high-performance liquid chromatography. ABZSO and ABZSO2 were recovered from the plasma. Fasting induced marked modifications in the pharmacokinetic behaviour of the ABZ metabolites in sheep. An extended absorption process, with a delayed peak concentration in the plasma, was observed for both metabolites in the fasted sheep. Significantly higher area under the curve (AUC) and peak plasma concentration (Cmax) values were obtained for both metabolites in the fasted animals compared to those fed ad libitum. Delayed elimination with prolonged detection in plasma was also observed in the fasted sheep. Treatment with ABZ at 7.5 mg/kg in the starved animals resulted in bioequivalence to the administration of the compound at a 50% higher dose rate (11.3 mg/kg) in the fed animals. It is suggested that fasting enhances ABZ dissolution and absorption by delaying its passage down the digestive tract.     

Role of membrane phospholipids and glycolipids in cell-to-cell fusion by VSV

To identify membrane components of CER cells interacting with vesicular stomatitis virus (VSV) during fusion at acidic pH (fusion from without, FFWO) two different approaches have been used, i.e. (i) treating the whole cells with enzymes and (ii) testing the ability of isolated membrane molecules to interfere with FFWO. Phospholipase A₂ and C digestion of cells greatly reduced syncytia formation, pointing towards the involvement of lipid structures as target sites for VSV. Cell susceptibility to FFWO was also reduced after neuraminidase, β-galactosidase or periodate treatment, suggesting that carbohydrate residues may participate in a complex receptor structure required for virus fusion. When membrane molecules were examined separately for their ability to inhibit viral FFWO, phosphatidylserine, phosphatidylinositol, sphingomyelin, cholesterol and GM3 ganglioside were found to be active, confirming the role of membrane lipid moiety in the cell surface structures involved in the early phases of VSV infection.