Carbopol-mediated paracellular transport enhancement in Calu-3 cell layers.

The interaction of Carbopol polymers with mucus producing Calu-3 human bronchial epithelial cells was evaluated to test for potential paracellular transport enhancement. Using desmopressin (1-deamino-8-arginine-vasopressin, DDAVP) as the model peptide, apical treatment with Carbopol polymer gel formulations resulted in molecular size-dependent permeability enhancement with a concomitant drop in the transepithelial electrical resistance (TEER). Permeability enhancement of DDAVP was dependent on the formulation vehicle composition and polymer concentration, was noncytotoxic, and completely reversible. Carbopol 971P displayed the greatest permeability enhancement across Calu-3 cells compared to other more viscous Carbopol polymers 934P and 974P, and other mucoadhesive cellulosic polymers. The greatest enhancement was observed when C971P formulation was prepared in water at a concentration of 0.25% w/v. Enhancement was confirmed in rabbit dosed with intranasal fluorescent dextran 4400. The C(max) and absorption rate each increased by 48% in C971P formulations compared to control, while the relative exposure increased 30%. In conclusion, Carbopol polymers are potentially useful excipients to enhance intranasal peptide absorption. We hypothesize that the permeation enhancement is related to the chelation of extracellular or tight-junctional Ca(2+) by charged polymer carboxylate groups that leads to temporary disruption of tight-junctions, thereby facilitating paracellular transport.

A rabbit model for sublingual drug delivery: comparison with human pharmacokinetic studies of propranolol, verapamil and captopril.

A rabbit model for investigating sublingual drug absorption was established yielding results consistent with clinical data reported in the literature. Using propranolol as a model compound the effect of formulation and dosing variables was explored as a means to characterize the limiting parameters of this model. In addition, verapamil and captopril were selected as reference compounds to compare this model to sublingual absorption in humans. Rabbits were dosed sublingually and systemic absorption was measured over time. Sublingual absorption of propranolol was dependent on dosing solution pH and volume. Intra-oral spray device did not affect the overall exposure compared to instillation using a syringe. Despite species and dosing regimen differences the relative bioavailabilities of propranolol and verapamil were very similar in rabbits and humans. In contrast, captopril absorption from the sublingual cavity of rabbits was low and did not agree with that observed in man. Here we report a sublingual rabbit model of drug delivery and its potential utility in preclinical development of intra-oral dosage forms.

Optimization of the beta-aminoester class of factor Xa inhibitors. Part 2: Identification of FXV673 as a potent and selective inhibitor with excellent In vivo anticoagulant activity.

Further optimization of the beta-aminoester class of factor Xa (fXa) inhibitors is described culminating in the identification of 9c (FXV673), a potent and selective factor Xa inhibitor with excellent in vivo anticoagulant activity. An X-ray structure of FXV673 bound to human fXa is also presented. Based on its selectivity, potent in vivo activity and favorable pre-clinical safety profile, FXV673 was selected for further development and is currently undergoing clinical trials.