Stephen A. Bai

The chimpanzee (Pan troglodytes) as a pharmacokinetic model for selection of drug candidates: Model characterization and application

The chimpanzee (CHP) was evaluated as a pharmacokinetic model for humans (HUMs) using propranolol, verapamil, theophylline, and 12 proprietary compounds. Species differences were observed in the systemic clearance of theophylline (∼5-fold higher in CHPs), a low clearance compound, and the bioavailability of propranolol and verapamil (lower in CHPs), both high clearance compounds. The systemic clearance of propranolol (∼1.53 l/h/kg) suggested that the hepatic blood flow in CHPs is comparable to that in humans. No substantial differences were observed in the in vitro protein binding. A preliminary attempt was made to characterize cytochrome P450 (P450) activities in CHP and HUM liver microsomes. Testosterone 6β-hydroxylation and tolbutamide methylhydroxylation activities were comparable in CHP and HUM liver microsomes. In contrast, dextromethorphan O-demethylation and phenacetin O-deethylation activities were ∼10-fold higher (per mg protein) in CHP liver microsomes. Intrinsic clearance estimates in CHP liver microsomes were higher for propranolol (∼10-fold) and theophylline (∼5-fold) and similar for verapamil. Of the 12 proprietary compounds, 3 had oral clearances that differed in the two species by more than 3-fold, an acceptable range for biological variability. Most of the observed differences are consistent with species differences in P450 enzyme activity. Oral clearances of proprietary compounds in HUMs were significantly correlated to those from CHPs (r = 0.68; p = 0.015), but not to estimates from rat, dog, and monkey. In summary, the chimpanzee serves as a valuable surrogate model for human pharmacokinetics, especially when species differences in P450 enzyme activity are considered.

Determination of the stereochemical composition of the major metabolites of verapamil in dog urine with enantioselective liquid chromatographic techniques

The stereochemical composition of verapamil and seven of its basic-extractable metabolites, isolated from the urine of dogs administered oral racemic verapamil, was determined by HPLC, using an Ultron OVM (ovomucoid) column. One dog was given oral (R)-verapamil alone in order to discriminate the (R)- and (S)-enantiomers of the metabolites. Structure identification of the isolated verapamil metabolites was accomplished using a combination of HPLC-MS and FAB-MS-MS techniques. Six of the urinary verapamil metabolites, including verapamil, were predominantly of the (R)-configuration, whereas one of the metabolites was predominantly in the (S)-form. The remaining isolated metabolite was comprised of approximately equal amounts of the two forms.

Pharmacokinetic-pharmacodynamic Relations of Losartan and Exp3174 in a Porcine Animal Model

The pharmacokinetics of losartan and EXP3174, an active metabolite of losartan, were evaluated in the anesthetized pig after both a single intravenous dose (3 mg/kg) and during constant intravenous infusion. The pharmacodynamic activities of losartan and EXP3174 were determined during constant intravenous infusion as the degree of inhibition of angiotensin II-induced increase in the diastolic pressure. The systemic plasma clearance of losartan was 22.1 +/- 4.4 ml/min/kg (mean +/- SEM) and had an apparent volume of distribution at steady state of 0.56 +/- 0.16 L/kg after a 3-mg/kg intravenous dose. The elimination half-life of losartan was 40 +/- 6 min. Less than 2% of the intravenous losartan doses was estimated to be present as unconjugated EXP3174. The plasma clearance of EXP3174 was approximately 50% that of losartan, 11.8 +/- 1.5 ml/min/kg, and had a smaller steady-state apparent volume of distribution, 0.18 +/- 0.04 L/kg. The elimination half-life for EXP3174 was slightly longer than that of losartan (52 min). The time course of the pharmacodynamic effects of losartan and EXP3174 closely followed their respective plasma concentrations. The apparent dissociation constant of EXP3174 to the angiotensin II receptor was estimated, based on the total plasma concentrations, to be approximately 5 times lower than that for losartan.

Effects of chlorpromazine on the disposition and beta-adrenergic blocking activity of propranolol in the dog

The effects of chlorpromazine (100mg p.o., 2hr before propranolol) on the disposition and beta-adrenergic blocking actions of both intravenous (6 mg) and oral (40 mg) propranolol were studied in the dog. Chlorpromazine pretreatment significantly reduced (69%) the oral clearance of propranolol, resulting in significant increases in propranolol bioavailability (159%), and in the total beta-adrenergic blocking activity (111%) after the oral dose. “The increase in the total beta-adrenergic blocking activity of oral propranolol after chlorpromazine pretreatment was mostly due to an increased contribution from the parent compound; the apparent activity from active propranolol metabolites was not affected by chlorpromazine. Chlorpromazine pretreatment had no significant influence on the systemic clearance, elimination half-life, apparent volume of distribution, and plasma binding of propranolol, or on the apparent hepatic blood flow. After intravenous propranolol, chlorpromazine pretreatment had no effect on either the total amount of beta-adrenergic blocking activity or the amount of activity attributable to active metabolites. The decreased oral propranolol clearance by chlorpromazine was seen as a shift to the left in the propranolol dose vs. AUCrelationship, eliminating the apparent nonlinear kinetic behavior of oral propranolol, and reducing the apparent oral threshold dose. Chlorpromazines major, if not only, effect on propranolol disposition was to reduce the presystemic elimination of propranolol, possibly through inhibition of its metabolism via a pathway other than ring oxidation.