ABSTRACT:Several human immunodeficiency virus (HIV) protease inhibitors, including atazanavir, indinavir, lopinavir, nelfinavir, ritonavir, and saquinavir, were tested for their potential to inhibit uridine 5-diphospho-glucuronosyltransferase (UGT) activity. Experiments were performed with human cDNA-expressed enzymes (UGT1A1, 1A3, 1A4, 1A6, 1A9, and 2B7) as well as human liver microsomes.All of the protease inhibitors tested were inhibitors of UGT1A1, UGT1A3, and UGT1A4 with IC 50 values that ranged from 2 to 87 M. The IC 50 values found for all compounds for UGT1A6, 1A9, and 2B7 were >100 M. The inhibition (IC 50 ) of UGT1A1 was similar when tested against the human cDNA-expressed enzyme or human liver microsomes for atazanavir, indinavir, and saquinavir (2.4, 87, and 7.3 M versus 2.5, 68, and 5.0 M, respectively). By analysis of the double-reciprocal plots of bilirubin glucuronidation activities at different bilirubin concentrations in the presence of fixed concentrations of inhibitors, the UGT1A1 inhibition by atazanavir and indinavir was demonstrated to follow a linear mixed-type inhibition mechanism (K i ؍ 1.9 and 47.9 M, respectively). These results suggest that a direct inhibition of UGT1A1-mediated bilirubin glucuronidation may provide a mechanism for the reversible hyperbilirubinemia associated with administration of atazanavir as well as indinavir. In vitro-in vivo scaling with [I]/K i predicts that atazanavir and indinavir are more likely to induce hyperbilirubinemia than other HIV protease inhibitors studied when a free C max drug concentration was used. Our current study provides a unique example of in vitro-in vivo correlation for an endogenous UGT-mediated metabolic pathway.The HIV protease is an essential enzyme that cuts the viral gag-pol polyprotein into its functional subunits. Atazanavir, indinavir, saquinavir, lopinavir, ritonavir, and nelfinavir are HIV protease inhibitors. The structures of these HIV protease inhibitors are shown in Fig. 1. As opposed to atazanavir, which is an azapeptide protease inhibitor (Goldsmith and Perry, 2003), other listed HIV protease inhibitors are peptidomimetics sharing the same structural determinant, i.e., a hydroxyethylene or a hydroxyethylamine moiety, which makes them nonscissile HIV protease substrate analogs. These HIV protease inhibitors are metabolized primarily by hepatic CYP3A enzymes, and they are also inhibitors of CYP3A enzymes (Flexner, 2000;de Maat et al., 2003;Goldsmith and Perry, 2003;Ernest et al., 2005). All of these HIV protease inhibitors have a high protein binding (Ͼ98%), except indinavir and atazanavir, which have a protein binding of 60 and 86%, respectively. Most of the HIV protease inhibitors are bound to ␣1-acid glycoprotein instead of albumin (de Maat et al., 2003). There are no literature reports indicating that HIV protease inhibitors are good substrates for human UGT enzymes, although there is evidence to support indinavir as a substrate of UGTs (Balani et al., 1996).Glucuronidation represents a major pathway for the elimin...
Plasma-free homovanillic acid, a major metabolite of dopamine, was measured in chronically ill schizophrenic patients both before and during treatment with the antipsychotic phenothiazine, fluphenazine. Neuroleptic treatment was associated with a significant time-dependent decrease in plasma homovanillic acid from pretreatment values, which were significantly elevated when compared with those of age- and sex-matched healthy control subjects. Further, both the absolute concentrations as well as the neuroleptic-induced reductions in plasma homovanillic acid determined over 5 weeks of neuroleptic treatment were statistically significantly correlated with ratings of psychosis and improvement in psychosis, respectively. These findings suggest that the delayed effects of neuroleptic agents on presynaptic dopamine activity may more closely parallel their therapeutic actions than do their immediate effects in blocking postsynaptic dopamine receptors and that a decrease in dopamine "turnover" may be responsible for their antipsychotic effects.
ABSTRACT:The metabolism and disposition of 14 C-labeled muraglitazar (Pargluva), a novel dual ␣/␥ peroxisome proliferator-activated receptor activator, was investigated in eight healthy male subjects with and without bile collection (groups 1 and 2) after a single 20-mg oral dose. Bile samples were collected for 3 to 8 h after dosing from group 2 subjects in addition to the urine and feces collection. In plasma, the parent compound was the major component, and circulating metabolites, including several glucuronide conjugates, were minor components at all time points. The exposure to parent drug (C max and area under the plasma concentration versus time curve) in subjects with bile collection was generally lower than that in subjects without bile collection. The major portion of the radioactive dose was recovered in feces (91% for group 1 and 51% for group 2). In addition, 40% of the dose was recovered in the bile from group 2 subjects. In this 3-to 8-h bile, the glucuronide of muraglitazar (M13, 15% of dose) and the glucuronides of its oxidative metabolites (M17a,b,c, M18a,b,c, and M20, together, 16% of dose) accounted for approximately 80% of the biliary radioactivity; muraglitazar and its O-demethylated metabolite (M15) each accounted for approximately 4% of the dose. In contrast, fecal samples only contained muraglitazar and its oxidative metabolites, suggesting hydrolysis of biliary glucuronides in the intestine before fecal excretion. Thus, the subjects with and without bile collection showed different metabolic profiles of muraglitazar after oral administration, and glucuronidation was not observed as a major pathway of metabolic clearance from subjects with the conventional urine and fecal collection, but was found as a major elimination pathway from subjects with bile collection.Peroxisome proliferator-activated receptors (PPARs) are a set of nuclear hormone receptors (comprising the ␣, ␥, and ␦ subtypes) which act as transcription factors in the regulation of multiple genes involved in such diverse disease areas as type 2 diabetes, dyslipidemia, obesity, inflammation, cancer, and osteoporosis (Torra et al., 2001;Taskinen, 2003;Yajima et al., 2004). The two most intensively investigated subtypes have been PPAR␣ (primarily expressed in the liver and which plays a critical role in lipid metabolism) and PPAR␥ (predominantly expressed in adipose tissue and implicated in insulin sensitization as well as glucose and fatty acid utilization). PPAR␣ is the target of the fibrate class of hypolipidemic drugs such as fenofibrate (Balfour et al., 1990;Despres, 2001;Packard et al., 2002) and gemfibrozil (Spencer and Barradell, 1996), whereas PPAR␥ is the target of the thiazolidinedione (Mudaliar and Henry, 2001) class of antidiabetic drugs such as rosiglitazone (Balfour and Plosker, 1999;Cheng-Lai and Levine, 2000;Goldstein, 2000) and pioglitazone (Gillies and Dunn, 2000).glycine, is a novel dual ␣/␥ PPAR activator, and the structure of muraglitazar is shown in Fig. 1. It has been shown that muraglitazar has both gluc...
Absolute oral bioavailability and disposition characteristics of irbesartan, an angiotensin II receptor antagonist, were investigated in 18 healthy young male volunteers. Subjects received [14C] irbesartan as a 30-minute intravenous infusion (50 mg), [14C] irbesartan orally as a solution (50 mg or 150 mg), or irbesartan capsule (50 mg). Irbesartan was rapidly and almost completely absorbed after oral administration, and exhibited a mean absolute oral bioavailability of 60% to 80%. Mean total body clearance was approximately 157 mL/min, and renal clearance was 3.0 mL/min. Volume of distribution at steady state was 53 L to 93 L, and terminal elimination half-life was approximately 13 to 16 hours. Hepatic extraction ratio was low (0.2). There were no major circulating metabolites, and approximately 80% of total plasma radioactivity was attributable to unchanged irbesartan. Regardless of route of administration, approximately 20% of dose was recovered in urine and the remainder in feces.
3-tert-Butyl-3-N-tert-butyloxycarbonyl-4-deacetyl-3-dephenyl-3-N-debenzoyl-4-O-methoxy-paclitaxel (BMS-275183
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