Prolongation of drug half-life due to obesity: studies of desmethyldiazepam (clorazepate)

Desmethyldiazepam pharmacokinetics were determined after oral administration of its precursor, clorazepate, to 12 obese subjects (mean weight: 105.4 kg; mean percent ideal body weight: 170%) who were matched for age, sex, and smoking habits with 12 normal controls (66.5 kg; percent ideal body weight: 103.3%). After an overnight fast, a single 15-mg clorazepate capsule, equivalent to 10.3 mg of desmethyldiazepam, was administered. Multiple plasma samples drawn 10-42 days postdose were analyzed for desmethyldiazepam by electron-capture GLC. Obese subjects compared to controls had a prolonged desmethyldiazepam elimination half-life (t1/2) (154.1 hr versus 57.1 hr; p less than 0.005). Assuming quantitative conversion of clorazepate to desmethyldiazepam and 100% systemic availability, volume of distribution (Vd) was greatly increased in the obese (158.8 liters versus 63.3 liters; p less than 0.001). The value of Vd remained greater even after correction for body weight (1.52 liter/kg versus 0.94 liter/kg; p less than 0.005). However, clearance of desmethyldiazepam was not different between groups (13.2 ml/min in obese versus 13.4 ml/min in controls). The percent ideal body weight was highly correlated with Vd (r = 0.82), as was total body weight (r = 0.86). The value of t1/2 was correlated highly with Vd (r = 0.89) but only weakly with clearance (r = -0.38). Therefore, the large increase in the desmethyldiazepam t1/2 value seen in obese subjects is predominantly due to the disproportionate distribution of this lipid-soluble drug into body fat as opposed to lean tissue. The contribution of clearance to desmethyldiazepam t1/2 was of much less importance than was Vd in this obese study population.     

Pharmacokinetics of coumarin and 7-hydroxycoumarin in the rhesus monkey after intravenous and peroral administration

Coumarin (C, Venalot) and 7-hydroxycoumarin (7-OHC) were administered in a dose of 1 mg/kg to rhesus monkeys intravenously and perorally. The concentrations of C, 7-OHC and their metabolite, 7-hydroxycoumarin glucuronide (7-OHCG) were measured in whole blood. The terminal half-life, t1/2, the apparent distribution volume, Vd, and the total clearance, CL, of C and 7-OHC after i.v. administration are 1.64 +/- 0.41 h and 0.8 +/- 0.29 h, 2.55 +/- 0.95 l/kg and 6.96 +/- 3.44 l/kg, and 19.05 +/- 5.41 ml/min/kg and 103.7 +/- 34.4 ml/min/kg (mean +/- SEM), respectively. The rates of absorption of C and 7-OHC are 12.8 +/- 2.38 and 4.62 +/- 1.08 h-1, respectively. The rate of metabolism of C via 7-OHC to 7-OHCG is 7.96 +/- 2.16 h-1 and that of 7-OHC to 7-OHCG is 27.99 +/- 11.73. The p.o. absolute bioavailability is 45 +/- 14% for C and 17.0 +/- 5% for 7-OHC. The pharmacokinetics of C in the rhesus monkey are similar to that in the dog. In man the p.o. absolute bioavailability is only 3.4%.     

Interspecies pharmacokinetic comparisons and allometric scaling of napsagatran, a low molecular weight thrombin inhibitor

The objective of this work was to assess the pharmacokinetics of napsagatran, a low molecular weight thrombin inhibitor, after intravenous administration in a variety of laboratory animals, and prospectively to help design the first pharmacokinetic studies in man. Napsagatran is actively excreted into the bile and urine of various species and pronounced species-differences in its pharmacokinetics are observed. It is, therefore, an interesting compound to use in tests of the limitations of presently available inter-species scaling methods. The present data suggest that allometric exponent values which are consistent with the values expected for physiological processes and small organic molecules are not necessarily associated with successful predictions in man when active transport processes are involved in the disposition of the compounds. For example, compared with the values observed in man, the clearance (CL), non-renal clearance (CL(nr)) and the volume of distribution at steady state (Vd(ss)) were over-predicted by 3-, 7- and 2-fold, respectively, by use of allometry. Of the species tested, the cynomolgus monkey seemed to be the most useful for predicting kinetics in man when the approach based on concentration-time transformations was used. Thus, for half-life (t(1/2)), CL and Vd(ss), the observed mean values of 1.7 h, 459 mL min(-1) and 24 L kg(-1) in man were very close to the values predicted from the cynomolgus monkey (1.7 h, 652 mL min(-1) and 22 L kg(-1), respectively). The results show that there are large inter-species differences for kidney and liver excretion of napsagatran. This is probably because of the involvement of active transport processes, which compromised the kinetic extrapolation from animal to man, although a more thorough investigation of the transporters involved in the disposition of napsagatran is necessary to enable better understanding of the species differences observed.     

Interspecies comparison of acivicin pharmacokinetics

Pharmacokinetic studies with the amino acid antineoplastic agent, acivicin, were carried out in the Sprague-Dawley rat, cynomolgus monkey, and beagle dog. Data were analyzed together with previously published studies in the mouse and rhesus monkey. Log-log plots of body weight (B, kg) versus total body clearance (ClB, ml/min), elimination half-life (t1/2, hr), and volume of distribution (V, ml) in the five species were linear with high correlation coefficients (r greater than or equal to 0.98) despite large differences in the extent of nonrenal clearance in the various species (ranging from approximately 30% of the dose in the mouse to 90% in the dog). Linear regression on the plots yielded allometric expressions (ClB = 4.0 x B0.62; t1/2 = 1.8 x B0.31; V = 620 x B0.95) which were extrapolated mathematically to predict acivicin pharmacokinetic parameters in humans prior to the first clinical trials. Predicted versus measured (mean +/- SD, N = 21 patients) pharmacokinetic values in humans were: ClB (ml/min), 50 vs. 49 +/- 13; t1/2 (hr), 6.4 vs. 9.5 +/- 3.5; VB (ml/kg), 500 vs. 580 +/- 110. Thus, the animal data were successfully extrapolated to yield reasonable predictions of human pharmacokinetic parameters, despite varying extents of renal and nonrenal clearance in the species examined. With one exception, plasma concentration-time data in six species spanning a 3000-fold body weight range and a 120-fold dose range were plotted on a single curve after plasma concentrations were normalized for the dose administered and chronological times were adjusted for body weight to yield "physiological times."(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative in vitro metabolism of indinavir in primates--a unique stereoselective hydroxylation in monkey

1. The in vitro metabolism of indinavir (CRIXIVAN, MK-0639, L-735,524), an HIV protease inhibitor, was evaluated using liver microsomes from cynomolgus monkey, rhesus monkey, chimpanzee and human. Indinavir exhibited marked species differences in metabolism. The overall rate of indinavir metabolism varied > 4-fold among primates (84 pmol/min/mg protein in cynomolgus monkey versus 20.4 pmol/min/mg protein in human) and followed the rank order: cynomolgus monkey > rhesus monkey > chimpanzee > human. 2. The cis-(indan)hydroxylated metabolite of indinavir was formed only in cynomolgus and rhesus monkey livers, whereas trans-(indan)hydroxylation and N-dealkylation were observed as the major metabolites in all primates tested. Inhibition studies with P450-selective inhibitors (ketoconazole, quinine, quinidine) and monoclonal antibodies (against CYP2D6 or CYP3A4) indicated that a cytochrome P450 isoform of the CYP2D subfamily is involved in the formation of the unique cis-(indan) hydroxylated metabolite in monkey, whereas all other oxidative metabolites, including the trans-(indan)hydroxylated metabolite, are formed by CYP3A isoform(s). 3. The present study has demonstrated that monkeys were unique in their abilities to form the stereoselective metabolite and were not appropriate surrogates for the qualitative prediction of indinavir metabolism in human.     

Pharmacokinetics of the novel, high-affinity and selective dopamine D3 receptor antagonist SB-277011 in rat, dog and monkey: in vitro/in vivo correlation and the role of aldehyde oxidase

1. In vitro studies with the selective dopamine D3 receptor antagonist SB-277011 were conducted in liver microsomes and homogenates from rat, dog, cynomolgus monkey and human to correlate the rate of metabolism with the in vivo pharmacokinetics of the compound in rat, dog and cynomolgus monkey. 2. In the presence of NADPH, SB-277011 was relatively stable in the presence of liver microsomes from rat, dog, cynomolgus monkey and human with an intrinsic clearance (CLi) of < 2 ml min(-1) g(-1) liver for all species. In total liver homogenates, SB-277011 was metabolized at a similar rate in rat and dog (CLi < 2 ml min(-1) g(-1) liver) to that in liver microsomes but in cynomolgus monkey and human (CLi = 9.9 and 45 ml min(-1) g(-1) liver, respectively) the intrinsic clearance was approximately 6- and 35-fold higher, respectively, than that in liver microsomes. 3. In the absence of NADPH, SR-277011 was rapidly cleared in liver homogenates from cynomolgus monkey and human (CLi = 7.4 and 27 ml min(-1) g(-1) liver, respectively) demonstrating that a significant pathway of metabolism of this compound was via an NADPH-independent non-microsomal oxidative route. This pathway was sensitive to inhibition with isovanillin suggesting that the enzyme responsible was aldehyde oxidase. 4. The in vivo pharmacokinetics showed that the plasma clearance of SB-277011 was low in rat (20 ml min(-1) kg(-1)), moderate in dog (14 ml min(-1) kg(-1)) and high in cynomolgus monkey (58 ml min(-1)kg(-1)), which is consistent with the in vitro findings and demonstrated a greater capacity for the monkey to metabolize this compound. The oral bioavailability of SB-277011 in rat, dog and cynomolgus monkey was 35, 43 and 2%, respectively. Given the high clearance of this compound in cynomolgus monkey, the low oral bioavailability is probably as a result of high first-pass elimination, specifically by aldehyde oxidase, rather than poor absorption. 5. The high in vitro clearance of SB-277011 in human liver homogenates and the involvement of aldehyde oxidase in the metabolism of SB-277011 indicates that the bioavailability of the compound is likely to be low in human.     

Disposition of RS-26306, a potent luteinizing hormone-releasing hormone antagonist, in monkeys and rats after single intravenous and subcutaneous administration.

The metabolic disposition of RS-26306, a new potent luteinizing hormone-releasing hormone antagonist, was studied in rats and monkeys after single i.v. and sc administration with the 3H-labeled compound. Plasma pharmacokinetics after iv administration were: CLs = 2.5 ml/min/kg, Vd beta = 0.29 liter/kg, t1/2 = 1.4 hr (rats), and CLs = 0.8 ml/min/kg, Vd beta = 0.32 liter/kg, t1/2 = 5.1 hr (monkeys). Cmax and Tmax in rats were 0.53 micrograms/ml and 4 hr after the 1 mg/kg sc dose, and were 1.07 micrograms/ml and 12 hr after the 10 mg/kg sc dose. AUC0-infinity after the 10 mg/kg sc dose in rats was seven times that after the 1 mg/kg sc dose. Apparent plasma disappearance t1/2 in rats were 3.6 and 15.2 hr, respectively, after the 1 and 10 mg/kg sc doses. An average of 12 and 4% of dose radioactivity remained at the injection site in rats 3 and 10 days, respectively, after a 10 mg/kg sc dose. In monkeys, Tmax after a 1 mg/kg sc dose was 0.5 hr for three animals but was 24 hr for the fourth animal, although plasma of this monkey contained substantial levels of RS-26306 between 15 min and 24 hr. Apparent plasma t1/2 in monkeys after a 1 mg/kg sc dose was at least 19 hr. Our data suggest depot formation after sc doses. In vitro plasma binding amounted to 82-84%. Excretion was mainly biliary: 12-25 and 55-84% of dose radioactivity was recovered in urine and feces, respectively, in both species. The biological samples contained only traces of 3H2O. Three metabolites, which were truncated peptides of the parent decapeptide, were identified in the rat bile. One of these was also present in the monkey plasma. The restricted enzymatic degradation of RS-26306, extensive plasma binding, and long circulating t1/2 of RS-26306 contribute to its prolonged activity in animal models and in humans.     

Intravenous pharmacokinetics and metabolism of the reactive oxygen scavenger alpha-phenyl-N-tert-butyl nitrone (PBN) in the cynomolgus monkey

The pharmacokinetics and metabolism of the antioxidant and reactive oxygen scavenger alpha-phenyl-N-tert-butyl nitrone (PBN) was examined in the male cynomolgus monkey after intravenous administration. Following an i.v. bolus dose of 5 mg/kg, plasma concentrations of PBN declined in a bi-exponential fashion. PBN demonstrated a moderate plasma clearance (CL(p) = 27.02 +/- 6.46 ml/min/kg) and a moderate volume of distribution at steady state (Vd(ss) = 1.70 +/- 0.23 l/kg), resulting in a terminal elimination half-life of 0.76 +/- 0.25 h. The corresponding area under the curve (AUC(0-infinity)) was 3.20 +/- 0.77 microg-h/ml. Scale-up of the in vitro microsomal intrinsic clearance data for PBN afforded a blood clearance (CLb) value of 22 ml/min/kg, which was in reasonable agreement with the observed in vivo CLb. Monkey liver microsomes catalyzed the NADPH-dependent monohydroxylation of PBN to the corresponding alpha-4-hydroxyphenyl-N-tert-butylnitrone (4-HOPBN) metabolite. The formation of 4-HOPBN and its corresponding O-glucuronide was also discernible upon qualitative analysis of pooled (0-24 h) monkey plasma and urine samples. Less than 5% of the administered dose was excreted as unchanged PBN in the urine, suggesting that P450-catalyzed metabolism constituted the major route of PBN clearance in the primate. In conclusion, the pharmacokinetic attributes and the clearance mechanism of PBN in the cynomolgus monkey is similar to that observed in the Sprague-Dawley rat.     

Pharmacokinetics of parenteral dezocine in rhesus monkeys and dogs

Pharmacokinetic parameters of the analgesic, dezocine, were determined after intravenous and intramuscular injection (1 mg/kg) to rhesus monkeys and dogs. In both species, the drug was rapidly distributed after intravenous administration and then eliminated with a mean half-life of 2.4 hr. Systemic clearance was 54.8 +/- 8.6(SD) and 65.8 +/- 14.0(SD) ml/min/kg in the rhesus monkey and dog, respectively. Glucuronidation was recognized as a major metabolic pathway in both species, and sulfate conjugation was indicated in the dog. Renal elimination of dezocine was minimal. Less than 4% of the dose was eliminated as unchanged dezocine in urine of rhesus monkeys and 1% of the dose in dog urine. After im administration, release from the injection site was rapid and no metabolism at the injection site was indicated. Multiple-dose experiments in dogs did not reveal accumulation. The acquisition of data was made possible by the development of a sensitive, specific assay, which depends on gas-liquid (electron capture) chromatography of a pentafluorobenzoylated derivative of dezocine.     

Metabolism and excretion of a chromone carboxylic acid (FPL 52757) in various animal species

1. The disposition of the chromone carboxylic acid (FPL 52757) in several species has been investigated. The compound is extensively metabolized by hydroxylation in rat, mouse, ferret, squirrel monkey, cynomolgus monkey, rabbit, hamster, stumped-tailed macaque and baboon (e.g. 50–100° in rat, cynomolgus monkey and squirrel monkey).

2. The plasma clearance of the chromone in rat, rabbit and squirrel monkey was 138, 44 and 59 ml/kg per?h respectively. Plasma clearance by the dog was slower (13 ml/kg per?h) and due mainly to elimination of unchanged compound.

3. As the dog is particularly susceptible to FPL 52757-induced hepatotoxicity the parent compound may be responsible. Species which clear the compound rapidly compared with the dog did not show a hepatotoxic response.

4. Although metabolism occurs in man the clearance is still slow (15 ml/kg per?h) and may be one reason for human susceptibility to a mild hepatotoxic effect with the compound.     

Comparative in vitro metabolism of indinavir in primates - a unique stereoselective hydroxylation in monkey

1. The in vitro metabolism of indinavir (CRIXIVAN, MK-0639, L-735,524), an HIV protease inhibitor, was evaluated using liver microsomes from cynomolgus monkey, rhesus monkey, chimpanzee and human. Indinavir exhibited marked species differences in metabolism. The overall rate of indinavir metabolism varied 4-fold among primates (84 pmol/min/mg protein in cynomolgus monkey versus 20.4 pmol/min/mg protein in human) and followed the rank order: cynomolgus monkey &gt; rhesus monkey &gt; chimpanzee &gt; human. 2. The cis-(indan) hydroxylated metabolite of indinavir was formed only in cynomolgus and rhesus monkey livers, whereas trans-(indan) hydroxylation and N-dealkylation were observed as the major metabolites in all primates tested. Inhibition studies with P450-selective inhibitors (ketoconazole, quinine, quinidine) and monoclonal antibodies (against CYP2D6 or CYP3A4) indicated that a cytochrome P450 isoform of the CYP2D subfamily is involved in the formation of the unique cis-(indan) hydroxylated metabolite in monkey, whereas all other oxidative metabolites, including the trans-(indan) hydroxylated metabolite, are formed by CYP3A isoform(s). 3. The present study has demonstrated that monkeys were unique in their abilities to form the stereoselective metabolite and were not appropriate surrogates for the qualitative prediction of indinavir metabolism in human.     

Unusual metabolism of caffeine in the squirrel monkey

The chronic toxicity of caffeine observed with the squirrel monkey appears to be related to the long plasma half-life of caffeine in this species. A half-life of 11 hr was found following the administration of 5 mg/kg compared to 2.4 hr in the rhesus monkey (5 hr or less have previously been reported for the mouse, dog and man). The methylxanthines found in the tissues and urine of the squirrel monkey following caffeine administration were the same as those reported for other species. No difference in the metabolism of caffeine by a squirrel monkey showing a toxic response to 25 mg/kg/day and a monkey tolerating this dose could be determined. The squirrel monkey appears to have a unique deficit in its ability to catabolize caffeine to metabolites which can be effectively excreted.     

Pharmacokinetics, metabolism, and disposition of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) in rats and dogs

The pharmacokinetics and metabolism of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) have been studied in rats and dogs. Using radiolabeled SK&F 86466, it was shown that the compound was completely absorbed from the gastrointestinal tract following oral administration. Most of the administered radioactivity (approximately 80%) was excreted in urine with the remainder excreted in feces via the bile. Very little of the parent compound was excreted unchanged in the urine. The major urinary metabolite, accounting for about 55% of the dose in rat and 35% in dog, was the N-oxide. N-Demethylation also occurs in both species, and in the rat approximately 20% of the dose is metabolized by this route. The plasma concentration vs. time curves following iv administration were analyzed using a two-compartment open model. The distribution phase half-life was 0.24 hr in the rat and 0.37 hr in the dog. In both species the terminal half-life was approximately 2 hr. The volume of distribution at steady state in the rat was 12.1 liters/kg and in the dog was 8.2 liters/kg. About 55% of the drug in plasma was bound to protein in both species so that the volume of distribution of the free drug was 27 liters/kg in the rat and 19 liters/kg in the dog. The clearance of SK&F 86466 from blood was very high in both the dog (56 ml/min/kg) and the rat (191 ml/min/kg). Since less than 1% of the compound was excreted unchanged in urine, the clearance was almost entirely metabolic.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preclinical Assessment of the Absorption and Disposition of the Phosphatidylinositol 3-Kinase/Mammalian Target of Rapamycin Inhibitor GDC-0980 and Prediction of Its Pharmacokinetics and Efficacy in Human

(S)-1-{4-[2-(2-Amino-pyrimidin-5-yl)-7-methyl-4-morpholin-4-yl-thieno[3,2-d]pyrimidin-6-ylmethyl]-piperazin-1-yl}-2-hydroxy-propan-1-one (GDC-0980) is a potent and selective inhibitor of phosphatidylinositol 3-kinase (PI3K) and mammalian target of rapamycin, two key components of the PI3K pathway, the deregulation of which is associated with the development of many cancers. The objectives of these studies were to characterize the absorption and disposition of GDC-0980 and assess its efficacy in an MCF7-neo/HER2 human breast cancer xenograft model in immunocompromised mice. Studies in parental Madin-Darby canine kidney cells indicated that GDC-0980 had high permeability (P(app) = 18 × 10(-6) cm/s), suggesting good absorption potential. However, it was found to be a P-glycoprotein and breast cancer resistance protein substrate in transfected cells and in knockout mice studies. Plasma protein binding was low, with the fraction unbound ranging from 29 to 52% across species. GDC-0980 hepatic clearance (CL) was predicted to be low in all of the species tested from hepatocyte incubations. The plasma CL of GDC-0980 was low in mouse (6.30 ml · min(-1) · kg(-1)), rat (15.4 ml · min(-1) · kg(-1)), and dog (6.37 ml · min(-1) · kg(-1)) and moderate in cynomolgus monkey (18.9 ml · min(-1) · kg(-1)). Oral bioavailability ranged from 14.4% in monkey to 125% in dog. Predicted human plasma CL and volume of distribution using allometry were 5.1 ml · min(-1) · kg(-1) and 1.8 l/kg, respectively. Parameters estimated from the pharmacokinetic/pharmacodynamic modeling of the MCF7-neo/HER2 xenograft data indicated that the GDC-0980 plasma concentration required for tumor stasis was approximately 0.5 μM. These parameters, combined with the predicted human pharmacokinetic profile, suggested that 55 mg once daily may be a clinically efficacious dose. GDC-0980 preclinical characterization and the predictions of its human properties supported its clinical development; it is currently in Phase II clinical trials.     

Disposition of flavodilol in laboratory animals

The disposition of flavodilol, a novel antihypertensive agent, was investigated in rats, rabbits, and dogs following iv or oral administration of 14C-flavodilol or unlabeled drug. Peak, plasma levels occurred within 6 hours of an oral dose in all three species. Following an iv dose, plasma elimination half-lives of flavodilol in rats, rabbits, and dogs were 3.0, 3.0, and 4.0 hr, respectively. Total body clearances were 0.71 liter/hr/kg for the rat, 1.89 liters/hr/kg for the rabbit, and 3.07 liters/hr/kg for the dog. Renal clearances were a small fraction of total clearance at 0.042, and 0.114 liter/hr/kg for the rat and dog, respectively, suggesting extensive nonrenal clearance. The volumes of distribution of 3.04 for the rat, 8.10 for rabbit, and 18.13 liters/kg for dog are large, suggesting significant extravascular distribution of flavodilol. Following 10 and 50 mg/kg po doses of 14C-flavodilol in rats, recovery of total radioactivity after 79 hr was 100.7% and 88.4% of the dose, respectively, most of which was recovered in the feces (77.5% and 66.6%, respectively). Tissue distribution studies of 14C in rats at 1.5, 5, 24, and 48 hr after a single po dose of 10 mg/kg 14C-flavodilol showed that the majority of the radioactivity was in the gastrointestinal tract and organs of elimination at all time points. Less than 1% of the dose remained in the body at 48 hr. 14C-Flavodilol was administered to rats iv at 1 mg/kg and orally at 10 mg/kg to assess comparative (label vs. nonlabel) absorption and distribution characteristics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Animal Pharmacokinetics and Interspecies Scaling from Animals to Man of Lamifiban,a New Platelet Aggregation Inhibitor

Relating pharmacokinetic information obtained in animal species to man (interspecies scaling) can play an important role in enabling understanding of the differences and similarities between species, and helping to predict the kinetic profile of a new compound in man. Interspecies scaling techniques have been applied to lamifiban (Ro 44–9883), a new selective and potent nonpeptidic inhibitor of human glycoprotein IIb-IIIa intended for use in clinical treatment of, for example, acute coronary syndrome. The pharmacokinetic profile of lamifiban in man was predicted from animal data (in rats, dogs and cynomolgus monkeys) by using allometric scaling and concentration-time transformations. These extrapolations for lamifiban were performed prospectively, to help design the first pharmacokinetic studies in man. The approach based on equivalent time was preferred for our prospective predictions, in view of the high values found for the allometric exponents. Using allometric scaling, clearance (CL), half-life(t1/2) and volume of distribution (Vd) were overestimated by approximately two-to fourfold. Compared with allometric scaling, the transformation based on equivalent time improved the prediction for all human pharmacokinetic parameters. For t1/2 and CL, the observed values for man were within the range predicted from the various animal species. Of the individual animal species, the cynomolgus monkey gave the most reliable predictions of these two parameters, as well as accurately predicting the Vd value.     

Comparative pharmacokinetics of antipyrine (phenazone) in the baboon,cynomolgus monkey and rhesus monkey

The pharmacokinetics of antipyrine (phenazone) in 3 species of non-human primate have been evaluated following its intravenous administration at a dose level of 92 mg/kg.Mean peak plasma concentrations of antipyrine of 132, 137 and 155 μg/ ml in the rhesus monkey, the cynomolgus monkey and the baboon respectively were not observed until 5 min after intravenous injection. Thereafter, concentrations declined with an apparent half-life of elimination of 1.5–2 h. The time-course of plasma antipyrine concentrations was adequately described by a one-compartment open model and no notable differences in pharmacokinetic parameters utilising a 2-compartment open model were observed.Antipyrine was mainly distributed in total body water. The mean volume of distribution was equivalent to 88, 73 and 66% of body weight in the rhesus monkey, the cynomolgus monkey and the baboon, respectively.An analysis of variance of volumes of distribution, apparent half-lives of elimination and systemic clearances showed that there was a statistically significant species-related difference in systemic clearance (P < 0.05) and volumes of distribution (P < 0.01) which were lower in the cynomolgus monkey than in the other 2 species.The pharmacokinetics of antipyrine in the non-human primate are more similar to those of other laboratory animal species than to those of humans.     

Pharmacokinetics of the acetylcholinesterase oxime reactivator, HI-6, in rhesus monkeys (Macaca mulatta): effect of atropine, diazepam, and methoxyflurane anesthesia

The pharmacokinetics of the bispyridinium oxime HI-6 (CAS reg. no. 34433-31-3; 1-(((4-aminocarbonyl)pyridinio)methoxy)methyl)-2-[hydroxy i mino)methyl)- pyridinium dichloride) was investigated in rhesus monkeys (Macaca mulatta). The effects of methoxyflurane anesthesia, administration of atropine with and without diazepam were determined on the serum half-life (t1/2), clearance rate (CL), and the volume of distribution (Vd) following intramuscular (IM) administration of HI-6 (30 mg kg-1). The control t1/2, CL and Vd of HI-offere 27 min, 8.6 ml min-1 kg-1 and 0.34 l kg-1, respectively. These parameters were unaffected by the co-administration of either atropine (0.5 mg kg-1, IM) or atropine and diazepam (0.5 mg kg-1, IM + 0.2 mg kg-1 IV, respectively). Methoxyflurane anesthesia resulted in a significant increase in the HI-6 t1/2 to 61 min concomitant with a decrease in the CL to 4.1 ml min-1 kg-1 with no change in the Vd. The increase in the t1/2 of HI-6 in methoxyflurane anesthetized monkeys is probably the result of a decrease in the clearance rate and, thus, excretion of HI-6 by the kidneys.     

Preclinical pharmacokinetics and metabolism of 6-(4-(2,5-difluorophenyl)oxazol-5-yl)-3-isopropyl-[1,2,4]-triazolo[4,3-a]pyridine, a novel and selective p38alpha inhibitor: identification of an active metabolite in preclinical species and human liver microsomes

The disposition of 6-(4-(2,5-difluorophenyl)oxazol-5-yl)-3-isopropyl-[1,2,4]-triazolo[4,3-a]pyridine (1), a potent and selective inhibitor of mitogen activated protein (MAP) kinase p38alpha, was characterized in several animal species in support of its selection for preclinical safety studies and potential clinical development. 1 demonstrated generally favorable pharmacokinetic properties in all species examined. Following intravenous (i.v.) administration, 1 exhibited low volumes of distribution at steady state (Vd(ss)) ranging from 0.4-1.3 l/kg (2.4-26 l/m(2)) in the rat, dog and monkey. Systemic plasma clearance was low in cynomolgus monkeys (6.00 ml/min/kg, 72.0 ml/min/m(2)) and Sprague-Dawley rats (7.65+/-1.08 ml/min/kg, 45.9+/-6.48 ml/min/m(2) in male rats and 3.15+/-0.27 ml/min/kg, 18.9+/-1.62 ml/min/m(2) in female rats) and moderate in beagle dogs (12.3+/-5.1 ml/min/kg, 246+/-102 ml/min/m(2)) resulting in plasma half-lives ranging from 1 to 5 h in preclinical species. Moderate to high bioavailability of 1 was observed in rats (30-65%), dogs (87%) and monkeys (40%) after oral (p.o.) dosing consistent with the in vitro absorption profile of 1 in the Caco-2 permeability assay. In rats, the oral pharmacokinetics were dose dependent over the dose range studied (5, 50 and 100 mg/kg). The principal route of clearance of 1 in rat, dog, monkey and human liver microsomes and in vivo in preclinical species involved oxidative metabolism mediated by cytochrome P450 enzymes. The major metabolic fate of 1 in preclinical species and humans involved hydroxylation on the isopropyl group to yield the tertiary alcohol metabolite 2. In human liver microsomes, this transformation was catalysed by CYP3A4 as judged from reaction phenotyping analysis using isozyme-specific inhibitors and recombinant CYP enzymes. Metabolite 2 was also shown to possess inhibitory potency against p38alpha in a variety of in vitro assays. 1 as well as the active metabolite 2 were moderately to highly bound to plasma proteins (f(u) approximately 0.1-0.33) in rat, mouse, dog, monkey and human. 1 as well as the active metabolite 2 did not exhibit competitive inhibition of the five major cytochrome P450 enzymes namely CYP1A2, 2C9, 2C19, 2D6 and 3A4 (IC(50)>50 microM). Overall, these results indicate that the absorption, distribution, metabolism and excretion (ADME) profile of 1 is relatively consistent across preclinical species and predict potentially favorable pharmacokinetic properties in humans, supporting its selection for toxicity/safety assessment studies and possible investigations in humans as an anti-inflammatory agent.     

Pharmacokinetics of iododoxorubicin in the rat, dog, and monkey.

The pharmacokinetics of iododoxorubicin (I-DOX) have been studied after single dose administration in the rat (iv and po), dog (iv and po), and monkey (iv). Plasma levels and amounts in urine were monitored by HPLC for both I-DOX and its biologically active metabolite, iododoxorubicinol (I-DOXOL). Plasma levels of I-DOX after iv administration could be described by a three-exponential curve with extremely fast initial phase. Terminal elimination half-lives of I-DOX were similar, 6-7 hr, in all three species. Body weight-normalized clearance (CL) and distribution volumes (Vd) of I-DOX were lower in the dog, but were similar in rat and monkey. The pharmacokinetic parameters also implied metabolic differences between species. Mean I-DOXOL/I-DOX AUC ratios were 0.02, 0.47, and 0.58, respectively, in rat, dog, and monkey, values considerably lower than reported in human studies. I-DOXOL remained slightly longer in the body than I-DOX, as seen both from terminal half-lives (9-11 hr) and mean residence times. In all species, renal excretion was virtually negligible: the amount of I-DOX + I-DOXOL in urine was less than 2% of dose. Mean bioavailabilities of I-DOX were 0.23 and 0.46 in rat and dog, respectively, and, in the latter, about half of I-DOXOL formation occurred during or before the first pass.