Development and characterization of topical siRNA drug delivery systems for corneal gene therapy: thermoreversible gel and liquid crystalline nanodispersions

The understanding of human genome and the evolvement of molecular biology led to discovery of important cellular mechanisms. Gene therapy has emerged as an approach to interfere with cell physiology, whenever it has a dysfunction that causes a disease, bringing new possibility of treatment to countless illnesses. In RNA interference mechanism, small double-stranded RNAs (small interference RNA, siRNA) inhibit specific gene expression. The eye has been one of the targeted organs for the use of such technology and, moreover, the corneal membrane is an attractive tissue due to the easy access and the existence of several diseases that can impair vision. To enhance bioavailability and facilitate the delivery of siRNA using a cationic polymer, a thermoreversible formulation containing chitosan and a liquid crystalline formulation functionalized hyaluronic acid were studied as potential delivery systems for ocular delivery of siRNA and both this systems are inedited as topical and ocular delivery of siRNA. A poloxamer 407 thermoreversible gel of was associated with two different types of chitosan (LMW with 92.2% deacetylation and MMW with 77.0% deacetylation). Both formulations showed desirable characteristics not only as gene delivery systems due to positive residual charge and capacity for complexing the siRNA, but also as a compatible ocular delivery system, due to pseudoplastic rheological behavior. The LMW chitosan and addition of NaCl to the formulation influenced the Tsol/gel of poloxamer gel; only the association with MMW chitosan showed desirable Tsol/gel. The systems containing poloxamer in combination with two different types of chitosan did not promote in vitro penetration of siRNA using bovine cornea under the used experimental conditions. The liquid crystalline system was developed with monoolein (MO), polyethylenimine (PEI), hyaluronic acid (HA) and aqueous phase. The formation of crystalline phases was observed by polarized light microscopy and the mesophases structures were confirmed by small angle X-ray diffraction. The liquid crystalline system composed of a mixture of hexagonal and cubic phases was dispersed into nanoparticles of suitable size, of approximately 166 nm. The formulations showed desirable characteristics as gene delivery systems, such as suitable zeta potential, ability to complex without degrading the siRNA and were not cytotoxic to fibroblasts L929, moreover, were compatible with the ocular administration due to isotonicity. The dispersion of crystals of MO/PEI was able to transfect L929 cells, however the incorporation of the HA decreased cellular uptake, probably due to high molecular weight hyaluronic acid employed. This study provides an outline for the future development of topical formulations to deliver siRNA to the cornea. (AU)