Ophthalmic drug delivery systems--recent advances.

Eye-drops are the conventional dosage forms that account for 90% of currently accessible ophthalmic formulations. Despite the excellent acceptance by patients, one of the major problems encountered is rapid precorneal drug loss. To improve ocular drug bioavailability, there is a significant effort directed towards new drug delivery systems for ophthalmic administration. This chapter will focus on three representative areas of ophthalmic drug delivery systems: polymeric gels, colloidal systems, cyclodextrins and collagen shields. Hydrogels generally offer a moderate improvement of ocular drug bioavailability with the disadvantage of blurring of vision. In situ activated gel-forming systems are preferred as they can be delivered in drop form with sustained release properties. Colloidal systems including liposomes and nanoparticles have the convenience of a drop, which is able to maintain drug activity at its site of action and is suitable for poorly water-soluble drugs. Among the new therapeutic approaches in ophthalmology, cyclodextrins represent an alternative approach to increase the solubility of the drug in solution and to increase corneal permeability. Finally, collagen shields have been developed as a new continuous-delivery system for drugs that provide high and sustained levels of drugs to the cornea, despite a problem of tolerance. It seems that new tendency of research in ophthalmic drug delivery systems is directed towards a combination of several drug delivery technologies. There is a tendency to develop systems which not only prolong the contact time of the vehicle at the ocular surface, but which at the same time slow down the elimination of the drug. Combination of drug delivery systems could open a new directive for improving results and the therapeutic response of non-efficacious systems.

Effect of cyclosporine A formulations on bovine corneal absorption: ex-vivo study.

The purpose of this study was to evaluate, in an ex-vivo study, the absorption of cyclosporine A on bovine cornea after 24 h contact with various drug delivery systems containing 1% cyclosporine A and in comparison with an olive oil formulation as the reference vehicle for cyclosporine A. The different formulations studied were poly(acrylic acid) polymeric gels in aqueous/non-aqueous solvents, polyisobutylcyanoacrylate nanocapsules, and a combination of both formulations. The histological effects of these formulation on corneal cells after 24 h of contact were also studied. The lowest absorption rate of cyclosporine A was found using olive oil with a percent absorption of 2.52 +/- 1.52% (259 +/- 171 micrograms/g cornea). The three formulations developed for this study, nanocapsules, poly(acrylic acid) polymeric gel and nanocapsules gel showed significantly better absorption of CsA than olive oil, with a mean percent absorption of 5.81 +/- 2.04% (621 +/- 218 micrograms/g cornea), 6.09 +/- 2.93% (651 +/- 313 micrograms cornea) and 7.92 +/- 2.55% (847 +/- 273 micrograms/g cornea) respectively. As we studied the penetration of cyclosporine A into the different layers of the cornea, we observed that for all formulations, CsA remained at the corneal surface and did not penetrate the whole cornea. The histological study showed that olive oil, nanocapsules and poly(acrylic acid) gel in aqueous/non-aqueous solvents show some modifications on the cornea, contrary to the nonocapsules gel which did not indicate any toxic effect. The nanocapsule gel, with the highest percent absorption along with its margin of safety on the cornea, seems to present a new promising drug delivery system for ocular administration.

Release kinetics of liposome-encapsulated ganciclovir after intravitreal injection in rabbits.

This study was undertaken to establish experimentally whether the intravitreal application of liposomally-entrapped ganciclovir could prolong intraocular therapeutic levels when it is compared to the intravitreal injection of a simple solution of the drug. New Zealand white rabbits were given an intravitreal injection of the drug solution and of liposome-encapsulated ganciclovir. The intravitreal clearance of ganciclovir was determined after a single injection of either the drug solution (200 micrograms/0.1 mL) or the liposomally-entrapped (with 41% load; 82 micrograms drug load and 118 micrograms free) ganciclovir. The ganciclovir vitreal concentrations were measured at various time intervals for a period up to 43 days using an HPLC method. The results of this study clearly demonstrated that prolonged intravitreal drug levels (above the mean inhibitory dose of cytomegalovirus of 1 microgram/mL) after administration of the liposome-entrapped ganciclovir and estimated to continue beyond 30-43 days. The injection of the 200 micrograms/0.1 mL of drug solution showed a mean vitreous concentration which was higher than the ID50 only for 55 h. The disappearance rate constant for the liposome-encapsulated injections was approximately 22 x slower than simple drug solution injections (controls). No evidence of retinal toxicity was found by clinical or light microscopy examination of the treated eyes.