C. Ferris

Reduction-sensitive functionalized copolyurethanes for biomedical applications

In the present paper we combine functionalization and biodegradation in the rational design of polymers that can be used as carrier systems for drug delivery in the colon. Functionalization of new polyurethanes (PUs) was achieved by thiol–ene coupling reactions, a simple and straightforward procedure included among the so-called click reactions, which are currently accepted as one of the most powerful tools in organic chemistry. Enhancement of the degradability of the new materials by the introduction of disulfide linkages into the polymer backbone has led to a new group of stimulus-responsive sugar-based polyurethanes able to be degraded by tripeptide glutathione under physiological conditions. Atomic Force Microscopy (AFM) on solid-supported multilayered dry polymer films—prepared by spin-coating from dimethylsulfoxide solutions—was used to study the morphology of the polymers and the degradation process in reductive environments. Matrix systems containing polymers selected according to their rheological properties were also investigated as modulated methotrexate-release systems.

A new biodegradable polythiourethane as controlled release matrix polymer

The main aim of this paper is the synthesis and characterization of a new linear functional biodegradable polythiourethane-d,l-1,4-dithiothreitol-hexamethylene diisocyanate [PTU(DTT-HMDI)]. The SeDeM diagram has been obtained to investigate its suitability to be processed through a direct compression process. Furthermore, the ability of this polymer to act as controlled release matrix forming excipient has been studied. Four batches of matrices containing 10-40% of polymer and theophylline anhydrous as model drug have been manufactured. Release studies have been carried out using the paddle method and the polymer percolation threshold has been estimated. The principal parameters of the SeDeM Expert system, such as the parametric profile (mean radius) and the good compression index (IGC=4.59) for the polymer are very close to the values considered as adequate for direct compression even with no addition of flow agents. Furthermore, the results of the drug release studies show a high ability of the polymer to control the drug release. The excipient percolation threshold has been estimated between 20% and 30% w/w of polymer.

Study of the properties of the new biodegradable polyurethane PU (TEG-HMDI) as matrix forming excipient for controlled drug delivery

The purpose of this work is to study the ability of a new biodegradable polyurethane PU(TEG-HMDI) obtained by reaction of triethylene glycol (TEG) with 1,6-hexamethylene diisocyanate (HMDI) to act as matrix forming polymer for controlled release tablets and to estimate its percolation threshold in a matrix system. Matrix tablets weighing 250 mg were prepared by direct compression with 10–30% wt/wt of PU(TEG-HMDI) and anhydrous theophylline as model drug. Release studies were carried out using the paddle method. The results were analyzed using the kinetics models of Higuchi, Korsmeyer-Peppas, and Peppas and Sahlin. These studies confirm the existence of an excipient percolation threshold between 10 and 20 % wt/wt of PU(TEG-HMDI) for the different batches prepared. It has been observed that the new biodegradable polyurethane PU(TEG-HMDI) shows adequate compatibility as well as a high ability to control the drug release.

Novel aqueous chitosan-based dispersions as efficient drug delivery systems for topical use. Rheological, textural and release studies.

The use of a novel cross-linked thiolated chitosan (CTS) was investigated as the main component of aqueous dispersions (at 1% and 3% w/v) for topical drug delivery systems. The nonionic theophiline (Th) and the cationic diltiazem(.)HCl (Dt) (at 0.5% w/v concentration) were used as model drugs. All aqueous dispersions behaved as viscoelastic fluids. The CTS 1% dispersions showed predominance of viscous component and low viscosity. However, in the CTS 3% dispersions, both the elastic component and high viscosities prevailed. So, texture parameters improved from CTS 1% to 3% dispersions and CTS 3%-Dt showed greater cohesion and adhesion than CTS 3%-Th, but always below CTS alone. All dispersions showed a Fickian diffusion mechanism. Despite release profiles of both drugs almost fully overlapped at 1% CTS, diffusion coefficients confirmed Dt released faster than Th at 3% CTS. The rheological behavior and the chemical nature of the drugs explained these results.