Keith W. Ward

Comparative evaluation of oral systemic exposure of 56 xenobiotics in rat, dog, monkey and human.

The prediction of human pharmacokinetics is often based on in vivo preclinical pharmacokinetic data. However, to date, no clear guidance has been available about the relative ability of the major preclinical species to estimate human oral exposure. The study was conducted to survey the literature on oral pharmacokinetic parameters in rat, dog, monkey and human, and to compare various methods for prediction of oral exposure in humans. Fifty–six non–peptide xenobiotics were identified with oral pharmacokinetic data in rat, dog, monkey and human, and comparison of the data from each species to humans was conducted along with an evaluation of the molecular features of these compounds. Monkey liver blood flow–based oral exposure was qualitatively and quantitatively more predictive of human oral exposure than rat or dog. Furthermore, generation of data in three versus two preclinical species did not always improve human predictivity. The use of molecular properties did not substantially improve the prediction of human oral exposure compared with the prediction from monkey alone. These observations confirm the continued importance of non–human primates in preclinical pharmacokinetics, and also have implications for pharmacokinetic lead optimization and for prediction of human pharmacokinetic parameters from in vivo preclinical data.

Preclinical pharmacokinetics of SB-203580, a potent inhibitor of p38 mitogen-activated protein kinase

1. SB-203580 (4-(4-fluorophenyl)-2-(4-methylsulphinylphenyl)-5-(4-pyridyl)imidazole) is a potent, selective inhibitor of p38 MAP kinase used extensively as a tool inhibitor in various pharmacological and toxicological models. This study was designed to evaluate the pharmacokinetics of SB-203580 in several preclinical species, both to assist with the interpretation of existing studies and to aid in the design of future studies with this inhibitor. 2. In vitro, SB-203580 was stable in mouse, rat, dog, monkey and human plasma over 24 h. However, species differences in plasma protein binding were observed; SB-203580 was 96-97% bound in human plasma and 78-92% bound in other species. These data suggest that protein binding may influence the results of in vitro studies using SB-203580, particularly when comparing results from different in vitro systems that incorporate plasma components. In vivo, SB-203580 demonstrated moderate to high clearance in all species tested, with non-linear elimination observed in the rat at plasma concentrations > 1000ng ml -1. Although good solution bioavailability was observed in non-rodents (78% in dog, 32% in monkey), lower and more variable bioavailability was observed in the rat and mouse (3-48%). 3. These interspecies differences in bioavailability, and the non-linear pharmacokinetics observed in rat, highlight the importance of monitoring SB-203580 systemic exposure in parallel with the pharmacological endpoint during in vivo pharmacology studies.

Phenylbutyrates as potent, orally bioavailable vitronectin receptor (integrin αvβ3) antagonists

In our continuing efforts to identify small molecule vitronectin receptor antagonists, we have discovered a series of phenylbutyrate derivatives, exemplified by 16, which have good potency and excellent oral bioavailability (approximately 100% in rats). This new series is derived conceptually from opening of the seven-membered ring of SB-265123.

SB-242235, a selective inhibitor of p38 mitogen-activated protein kinase. II: In vitro and in vivo metabolism studies and pharmacokinetic extrapolation to man

1. Inhibition of p38 MAP kinase has been investigated extensively as a potential therapy for cytokine-mediated diseases such as autoimmune and inflammatory diseases. SB-242235 (1-(4-piperidinyl)-4-(4-fluorophenyl)-5-(2-methoxy-4-pyrimidinyl) imidazole) is a potent and selective p38 MAP kinase inhibitor; the preclinical pharmacokinetics of SB-242235 have been described previously. The present studies were conducted to describe the in vitro metabolic rates and routes of SB-242235 metabolism, to characterize its in vivo preclinical metabolism, and to use these data to aid in the prediction of the pharmacokinetic behaviour of SB-242235 in man. 2. SB-242235 was metabolically stable in rat, dog, monkey and human hepatic microsomes, isolated hepatocytes and liver slices in vitro. The in vivo preclinical metabolism studies were consistent with the in vitro findings; SB-242235 was minimally metabolized, and was primarily excreted unchanged in the urine (45 and 67% of the administered dose in the rat and monkey, respectively). 3. Allometric scaling using various correction factors predicted that SB-242235 would have low clearance in man with a predicted half-life ranging from 11.5 to 18.7h. This prediction was consistent with the observed mean half-life of 16.4 h in the first-in-man study for SB-242235. An allometric scaling method with a correction for interspecies differences in glomerular filtration rate provided the most accurate prediction of the pharmacokinetic behaviour of SB-242235 in humans, although the clinical data also highlight potential difficulties in conducting prospective allometry.

Apparent absolute oral bioavailability in excess of 100% for a vitronectin receptor antagonist (SB-265123) in rat. II. Studies implicating transporter-mediated intestinal secretion.

Transporters have been increasingly identified as a factor in limiting the oral bioavailability of certain drugs. Previously, the present authors investigated a compound (SB-265123) with an apparent absolute oral bioavailability (Fapp) consistently >100%, and excluded likely artefactual causes for this observation, as well as standard considerations of non-stationary or non-linear pharmacokinetics. The data led the authors to believe that SB-265123 might be a transporter substrate in the rat, and it was hypothesized that transporter interactions might be responsible for the observed Fapp>100%. In the present study, a model was proposed incorporating rapid and complete absorption and elimination by a saturable intestinal secretory pathway. Intestinal secretion was demonstrated for SB-265123 using a rat single-pass intestinal perfusion technique. In addition, in a study employing both independent and simultaneous intravenous and oral administration of SB-265123, exposure to SB-265123 was greater than additive on joint intravenous and oral administration, lending further support to the hypothesis of a saturable transporter. Furthermore, in a study with co-administration of GF120918A, a transporter inhibitor, the observed Fapp for SB-265123 was only 84±17%, providing additional evidence for transporter involvement in the >100% Fapp phenomenon. Experience with SB-265123 illustrates a counterintuitive impact of transporters on oral bioavailability and highlights the importance of considering transporter interactions in the systemic disposition of xenobiotics, even those not demonstrating low oral bioavailability.

A Highly Convergent Synthesis of 2‐Phenyl Quinoline as Dual Antagonists for NK2 and NK3 Receptors

Abstract A novel and highly convergent synthesis leading to 2‐phenyl‐quinolines has been developed. As demonstrated in the preparation of 6‐fluoro‐3‐(3‐oxo‐piperazin‐1‐ylmethyl)‐2‐phenyl‐quinoline‐4‐carboxylic acid [(S)‐1‐cyclohexyl‐ethyl]‐amide (8), the method provides fascile access to this class of analogues via the common intermediate 7.

Apparent absolute oral bioavailability in excess of 100% for a vitronectin receptor antagonist (SB-265123) in rat. I. Investigation of potential experimental and mechanistic explanations

SB-265123 is a novel αvβ3 (the vitronectin receptor) antagonist. Previous rat studies with it revealed an apparent absolute oral bioavailability (Fapp) of greater than 100%. The present studies were conducted to investigate the potential causes for this observation. Of 49 SB-265123 analogues evaluated in rat using an identical experimental design, Fapp>100% was observed for 22 of them, suggesting that the observed Fapp>100% with SB-265123 was not anomalous. All 22 compounds had clearances<15 ml min−1 kg−1. However, Fapp>100% were not recorded for all low-clearance analogues. Using SB-265123 as a model to investigate potential artefacts, it was demonstrated that using a chiral assay did not decrease Fapp. Additionally, qualitative sample analysis demonstrated that no metabolites were present in the plasma that could interfere with the liquid chromatography coupled with tandem mass spectrometry detection assay. The high Fapp was also dose-order-, delivery system- and vehicle-independent, and was not affected by the feeding status of the animals. Furthermore, a linearity experiment and an absorption study indicated that oral administration of SB-265123 does not result in hepatic portal vein concentrations that exceed the pharmacokinetic linearity of SB-265123. These observations suggest that the observed Fapp>100% for SB-265123 is not due to an experimental artefact or an obvious pharmacokinetic non-linearity. The mechanism(s) for this phenomenon is explored further in the second part of the present paper.