Pharmacokinetic and tissue distribution study of [14C]fluasterone in male Beagle dogs following intravenous, oral and subcutaneous dosing routes.

The purpose of this work was to compare the pharmacokinetics (PK) and tissue distribution of [14C]fluasterone following intravenous (iv), subcutaneous (sc) and oral (po) administration in male Beagle dogs. The main goal of the investigation was to discover if non-oral routes would alter parameters observed in this study following the administration of [14C]fluasterone. The oral formulation had a lower bioavailability (47%) compared to the sc formulation (84%). Po and sc administration resulted in a similar t(max); however, the observed C(max) following sc dosing was less than half of that after oral dosing. The sc route had the greatest overall exposure (AUC(0-infinity)). Tissue distribution analysis 2 h post-intravenous dosing showed that connective tissue (adipose and bone), liver, and skeletal muscle accumulated relatively high levels of fluasterone. The majority of the dose was retained during the first 24 h. Elimination of [14C]fluasterone-derived radioactivity following intravenous dosing resulted in urine and feces containing 7.6% and 28%, respectively, of the total dose over the first 24 h. Elimination of [14C]fluasterone-derived radioactivity following subcutaneous dosing resulted in 4.6% in urine and 7.8% in feces of the total dose over the first 24 h. Following oral dosing, elimination resulted in 3.8% in urine and 36% in feces over the first 24h. In conclusion, the sc route of administration offers some advantages to po and iv due to the prolonged release and increased retention through 24 h.

Identification of [14C]fluasterone metabolites in urine and feces collected from dogs after subcutaneous and oral administration of [14C]fluasterone.

The objective of this research was the identification of the metabolic profile of fluasterone, a synthetic derivative of dehydroepiandrosterone, in dogs treated orally or subcutaneously with [4-(14)C]fluasterone. Separation and characterization techniques used to identify the principal metabolites of fluasterone in urine and feces included high-performance liquid chromatography (HPLC), liquid scintillation spectrometry, HPLC/tandem mass spectrometry, and NMR. In urine, the majority of the radioactivity was present as two components that had apparent molecular weights consistent with their tentative identification as monoglucuronide conjugates of 4alpha-hydroxy-16alpha-fluoro-5-androsten-17beta-ol and X(alpha or beta)-4alpha-dihydroxy-16alpha-fluoro-5-androsten-17beta-ol. The identification of the monoglucuronide conjugate of 4alpha-hydroxy-16alpha-fluoro-5-androsten-17beta-ol was also supported by NMR data. In support of this identification, these metabolites were cleaved with glucuronidase enzyme treatment, which gave rise to components with molecular weights again consistent with the aglycones of a monohydroxylated, 17-keto reduced (dihydroxy) fluasterone metabolite and a dihydroxylated, 17-keto reduced (trihydroxy) fluasterone metabolite. In feces, nonconjugated material predominated. The primary metabolites eliminated in feces were the two hydroxy fluasterone metabolites arising from 17-reduction (16alpha-fluoro-5-androsten-17beta-ol and 16alpha-fluoro-5-androsten-17alpha-ol) and 4alpha-hydroxy-16alpha-fluoro-5-androsten-17beta-ol that was present in urine in glucuronide form.