Confined crystallization of fenofibrate in nanoporous silica.

Producing stable nanocrystals confined to porous excipient media is a desirable way to increase the dissolution rate and improve the bioavailability of poorly water soluble pharmaceuticals. The poorly soluble pharmaceutical fenofibrate was crystallized in controlled pore glass (CPG) of 10 different pore sizes between 12 nm and 300 nm. High drug loadings of greater than 20 wt% were achieved across all pore sizes greater than 20 nm. Nanocrystalline fenofibrate was formed in pore sizes greater than 20 nm and showed characteristic melting point depressions following a Gibbs-Thomson relationship as well as enhanced dissolution rates. Solid-state Nuclear Magnetic Resonance (NMR) was employed to characterize the crystallinity of the confined molecules. These results help to advance the fundamental understanding of nanocrystallization in confined pores.

(+)-bufuralol 1'-hydroxylation activity in human and rhesus monkey intestine and liver.

(+)-Bufuralol 1'-hydroxylation, a commonly used marker of hepatic CYP2D6 activity, was investigated in human and rhesus monkey intestinal microsomes and compared with that in hepatic microsomes. The cumene hydroperoxide (CuOOH)-mediated metabolism of (+)-bufuralol suggested that at least two enzymes were responsible for bufuralol 1'-hydroxylation in both human and monkey intestinal microsomes. In contrast, the kinetics of the CuOOH-mediated metabolism in human and monkey livers were monophasic. The Km values for the higher affinity component of the intestinal enzyme(s) of both species were similar to, while the corresponding Vmax values were much lower than, those obtained with the livers. Bufuralol metabolism mediated by NADPH exhibited biphasic kinetics and was less efficient than that observed in the presence of CuOOH in both human and monkey intestines, in agreement with the observations in the livers. Inhibition of bufuralol hydroxylase activity in the intestine and liver preparations from the same species by known CYP2D6 inhibitors/substrates was qualitatively similar. Quinidine was the most potent inhibitor of (+)-bufuralol 1'-hydroxylation in all tissues studied. Western immunoblots using anti-CYP2D6 peptide antibody revealed a protein band in human and monkey intestinal microsomes of the same molecular weight as that observed in the liver preparations. The intestinal CYP2D protein content appeared to be much less than that of liver, and correlated with the (+)-bufuralol hydroxylase activity. Immunoinhibition studies indicated significant (up to 50%) inhibition of the CuOOH-mediated (+)-bufuralol metabolism in human and monkey intestines only by anti-CYP2D6, and not by anti-CYP2A6, or anti-CYP2E1. Inhibition of the bufuralol 1'-hydroxylase activity by anti-rat CYP3A1 was only slight (20%) in human, but marked (60-65%) in monkey intestinal microsomes. The hepatic metabolism of (+)-bufuralol in humans and monkeys was only inhibited (75%) by anti-CYP2D6, but not by anti-CYP3A1. Overall, the results suggest that (1) tissue and species differences exist in the catalysis of (+)-bufuralol 1'-hydroxylation, and (2) CYP2D6-related enzymes are partially or primarily responsible for the bufuralol hydroxylase activity in human and monkey intestines or monkey liver.

Species differences in the metabolism of a potent HIV-1 reverse transcriptase inhibitor L-738,372. In vivo and in vitro studies in rats, dogs, monkeys, and human.

In vivo and in vitro metabolism of 6-chloro-4(S)-cyclopropyl-3,4-dihydro-4-((2-pyridyl) ethynyl)quinazolin-2(1H)-one (L-738,372), a potent human immunodeficiency virus-type 1 reverse transcriptase inhibitor, has been investigated in rats, dogs, and monkeys. Following 0.9 mg/kg iv and 9 mg/kg po doses, systemic blood clearance (CLB) and bioavailability (F) of L-738,372 were species-dependent and inversely related (CLB = 48, 15, and 3 ml/min/kg; F = 6, 62 and 94%, in dogs, rats, and monkeys, respectively). Incubation of L-738,372 with rat liver slices and liver microsomes from all species studied led to the formation of two hydroxylated metabolites, M1 and M2. Kinetic studies of the microsomal metabolism of L-738,372 indicated that M1 was formed by a much higher affinity, but lower capacity enzyme(s) than that which catalyzed M2 formation in rats, dogs, and monkeys. The total intrinsic clearance of metabolite formation (CL(int) total = CL(int) M1 + CL(int) M2) was highest in dogs, followed by rats and monkeys. In dogs, CL(int) total was caused almost exclusively by CL(int) M1. Extrapolation of the CL(int) total values to the hepatic clearances (19, 8.4, and 0.9ml/min/kg in dogs, rats, and monkeys, respectively) showed a similar rank order to the CLB observed in vivo. Good agreement between these in vivo and in vitro results suggests that the species differences in hepatic first-pass metabolism, and not the intrinsic absorption, contributed significantly to the observed differences in F.(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro metabolism of L-696,229, an HIV-1 reverse transcriptase inhibitor in rats and humans. Hepatic and extrahepatic metabolism and identification of enzymes involved in the hepatic metabolism.

The metabolism of L-696,229, 3-[2-(benzoxazol-2-yl)ethyl]-5-ethyl-6-methylpyridin-2(1H)-o ne, a potent human immunodeficiency virus-type 1 reverse transcriptase inhibitor, by rat liver, lung, gut, and kidney microsomes has been studied. L-696,229 was metabolized by rat liver microsomes to several products: the 5 alpha-hydroxyethyl (M1); 5,6-dihydrodiol (M2); 6'-hydroxy (M3); 6-hydroxymethyl (M4); and 5-vinyl (M5) metabolites. For these pathways, liver was the most active metabolizing organ, whereas lung was the major extrahepatic organ in the drug metabolism. In all tissues tested, M1 was the major metabolite. With the exception of M3, gender differences in the hepatic formation of all metabolites were observed. Enzymes responsible for the hepatic metabolism of L-696,229 in rats were also investigated using various enzyme inducers and polyclonal antibodies to rat P-450. Treatment of male rats with dexamethasone (DX) or phenobarbital (PB) caused significant increases in the hepatic formation of the gender-dependent metabolites. Methylcholanthrene (3-MC) greatly enhanced the hepatic formation of M1, M3, and M4. Immunoinhibition studies suggested that CYP2B1/2 and 2E1 were not involved in L-696,229 metabolism, whereas CYP1A was partly responsible for the formation of M1 in untreated rats. CYP3A played an important role in the formation of M1, M2, M4, and M5 in untreated and DX-treated rats. In PB-treated rats, CYP2B1/2 was involved in the increased formation of M1 and M4, whereas CYP3A was partly involved in the enhanced M2 and M4 formation, and primarily responsible for the increased M5 formation.(ABSTRACT TRUNCATED AT 250 WORDS)