Correlation of lactulose-to-mannitol ratios in plasma and urine for intestinal permeability assessment in pigs.

OBJECTIVE: The lactulose-to-mannitol ratio test is a test to assess the disorders associated with gut permeability. The test requires an oral administration of the mixture of lactulose and mannitol and urine collection. The urinary ratio of lactulose to mannitol is an indicator of intestinal permeability. Due to the complexity of urine collection in animal studies, plasma exposure ratios of lactulose to mannitol compared to their urinary concentration ratios were evaluated following an oral administration of the sugar mixture in pigs. ANIMALS: 10 pigs were orally dosed with a solution of lactulose and mannitol mixture. PROCEDURES: Plasma samples were collected at predose, 10 and 30 minutes and 2, 4, and 6 hours postdosing, and cumulated urinary samples were collected at 6 hours for liquid chromatography-mass spectrometry analysis. The ratios of pharmacokinetic parameters of lactulose to mannitol and the plasma sugar ratios at a single time point or the mean values of several time points were compared to their urinary sugar ratios. RESULTS: The results revealed that the lactulose-to-mannitol ratios of AUC0-6h, AUCextrap, and Cmax were correlated to the urinary sugar ratios, and the plasma sugar ratios of a single time point at 2, 4, or 6 hours and the mean values of those time points were also appropriate to replace their urinary ratios in pigs. CLINICAL RELEVANCE: Following an oral administration of lactulose and mannitol mixture, blood collection, and assay can be an option for assessing intestinal permeability, especially in animal studies.

Stability of Ketoprofen Methylester in Plasma of Different Species.

BACKGROUND: Pharmacokinetic and pharmacodynamic assessment of ester-containing drugs can be impacted by hydrolysis of the drugs in plasma samples post blood collection. The impact is different in the plasma of different species. OBJECTIVE: This study evaluated the stability of a prodrug, ketoprofen methylester (KME), in commercially purchased and freshly collected plasma of mouse, rat, dog, cat, pig, sheep, cattle and horse. METHODS: KME hydrolysis was determined following its incubation in commercially purchased and freshly collected plasma of those species. Different esterase inhibitors were evaluated for prevention of the hydrolysis in rat, dog and pig plasma. RESULTS: KME was rapidly hydrolyzed in both commercially purchased and freshly collected plasma of mouse, rat, and horse. The hydrolysis was initially quick and then limited in cat plasma. KME hydrolysis was minimum in commercially purchased plasma of dog, pig, sheep and cattle but substantial in freshly collected plasma of those species. Different esterase inhibitors showed different effects on the stability of KME in rat, dog and pig plasma. CONCLUSION: These results indicate that plasma of different species has different hydrolytic activities to estercontaining drugs. The activities in commercially purchased and freshly collected plasma may be different and species-dependent. Esterase inhibitors have different effects on preventing hydrolysis of the ester-containing drugs in the plasma of different species.

Pharmacokinetics and brain distribution of amitraz and its metabolites in rats.

Amitraz is an acaricide and insecticide widely used in agriculture and veterinary medicine. Although central nervous system (CNS) toxicity is one of major toxicities following oral ingestion of amitraz, the understanding of the cause of the toxicity is limited. This study evaluated the systemic and brain exposure of amitraz and its major metabolites, BTS27271, 2',4'-formoxylidide, and 2,4-dimethylaniline following administration of amitraz in male Sprague-Dawley rats. Significant metabolism of amitraz was observed following the intravenous and oral administration. Amitraz related metabolites were majority of the total exposure observed, especially following oral administration. BTS27271 had higher brain exposure than amitraz and its other metabolites, which was due to low plasma protein binding but high brain tissue binding of BTS27271. Since BTS27271 has similar or higher toxicity and α2-adrenoreceptor agonist potency than amitraz, its exposure in brain tissues may be the major cause of CNS toxicity of amitraz in animals and humans.