Selective inhibition of eosinophil influx into the lung by small molecule CC chemokine receptor 3 antagonists in mouse models of allergic inflammation.

CC chemokine receptor (CCR) 3 is a chemokine receptor implicated in recruiting cells, particularly eosinophils (EPhi), to the lung in episodes of allergic asthma. To investigate the efficacy of selective, small molecule antagonists of CCR3, we developed a murine model of EPhi recruitment to the lung. Murine eotaxin was delivered intranasally to mice that had previously received i.p. injections of ovalbumin (OVA), and the effects were monitored by bronchoalveolar lavage. A selective eosinophilic influx was produced in animals receiving eotaxin but not saline. Furthermore, the number of EPhi was concentration- and time-dependent. Although anti-CCR3 antibody reduced the number of EPhi, the effect of eotaxin in OVA-sensitized mice was not a direct chemotactic stimulus because mast cell deficiency (in WBB6F1-Kitw/Kitw-v mice) significantly reduced the response. Two representative small molecule CCR3 antagonists from our program were characterized as being active at mouse CCR3. They were administered p.o. to wild-type mice and found to reduce eotaxin-elicited EPhi selectively in a dose-dependent manner. Pump infusion of one of the inhibitors to achieve steady-state levels showed that efficacy was not achieved at plasma concentrations equivalent to the in vitro chemotaxis IC90 but only at much higher concentrations. To extend the results from our recruitment model, we tested one of the inhibitors in an allergenic model of airway inflammation, generated by adoptive transfer of OVA-sensitive murine T helper 2 cells and aerosolized OVA challenge of recipient mice, and found that it inhibited EPhi recruitment. We conclude that small molecule CCR3 antagonists reduce pulmonary eosinophilic inflammation elicited by chemokine or allergenic challenge.

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 (approximately 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 (approximately 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 6beta-hydroxylation and tolbutamide methylhydroxylation activities were comparable in CHP and HUM liver microsomes. In contrast, dextromethorphan O-demethylation and phenacetin O-deethylation activities were approximately 10-fold higher (per mg protein) in CHP liver microsomes. Intrinsic clearance estimates in CHP liver microsomes were higher for propranolol (approximately 10-fold) and theophylline (approximately 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.

Heterocyclic aminopyrrolidine derivatives as melatoninergic agents.

A series of chiral heterocyclic aminopyrrolidine derivatives was synthesized as novel melatoninergic ligands. Binding affinity assays were performed on cloned human MT(1) and MT(2) receptors, stably expressed in NIH3T3 cells. Compound 16 was identified as an orally bioavailable agonist at MT(1) and MT(2) melatonin receptors with low vasoconstrictive activity.

Preclinical pharmacokinetics and metabolism of BMS-214778, a novel melatonin receptor agonist.

BMS-214778 is a novel melatonin receptor agonist that may be a useful treatment for sleep disorders that result from disruption of circadian rhythms. Pharmacokinetic studies following intravenous and oral administration and 1 month oral steady-state studies were carried out in rats and monkeys. Rat brain was analyzed for BMS-214778 to determine the extent of its penetration from plasma. Equilibrium dialysis was employed to determine the extent of binding of [(14)C]-BMS-214778 to rat, monkey, and human sera proteins. In vitro metabolism studies with BMS-214778 in rat, monkey, and human liver homogenate preparations (S-9), with monkey and human liver slice preparations, and with pooled human liver microsomes were performed and the incubates analyzed for potential metabolites. Recombinant microsomes expressing specific human cytochrome P(450) (CYP) enzymes were employed to identify possible human metabolic pathways. BMS-214778 showed a high hepatic extraction and high degree of tissue distribution. BMS-214778 also displayed non-linear oral pharmacokinetics. Systemic exposures following oral doses in rats and monkeys increased more than proportionally to the increment in dose. Loss of systemic exposure to BMS-214778 upon chronic oral dosing was observed in male rats where exposure was one-half to two-thirds compared to a single dose, while modest decreases in exposure were observed upon chronic dosing in both sexes of monkey. This was suggestive of induction of BMS-214778 clearance and/or excretion mechanisms. BMS-214778 distributed from the plasma to brain in the rat (mean +/- SD brain:plasma ratio of 0.9 +/- 0.1, N = 3). [(14)C]-BMS-214778 was moderately bound to serum proteins (<91% bound) in all species examined. In vitro metabolism of BMS-214778 was mostly by hydroxylation and dehydrogenation, with CYP1A1, 1A2, 2D6, and 2C9 being the most likely isoforms to be involved in its metabolism in humans.

The synthesis and characterization of BMS-204352 (MaxiPost) and related 3-fluorooxindoles as openers of maxi-K potassium channels.

3-Aryl-3-fluorooxindoles can be efficiently synthesized in two steps by the addition of an aryl Grignard to an isatin, followed by treatment with DAST. Oxindole 1 (BMS-204352; MaxiPost) can be isolated using chiral HPLC or prepared by employing chiral resolution. Cloned maxi-K channels are opened by 1, which demonstrates a brain/plasma ratio >9 in rats.