Development and characterization of topical delivery systems based on liquid crystals for siRNA in gene therapy

Gene therapy by RNA interference (RNAi) is a post-transcriptional silencing process that can suppress the expression of a particular gene. The RNAi is a promising therapeutic approach for the treatment of many severe diseases that have no cure or well-defined treatments. However, the development of clinically appropriate, safe and effective delivery systems is necessary to enable this new therapy, since obstacles in the in vivo administration and distribution committed the clinical use of siRNAs (small interfering RNA). In addition, the topical delivery of siRNAs appears as a promising alternative for the treatment of cutaneous pathologies. In this context, this research aimed to develop a delivery system based on Nanotechnology for the topical delivery of siRNAs, aiming to introduce gene therapy as a new approach for the treatment of skin disorders. As a delivery system, liquid-crystalline nanodispersions, composed by monoolein (MO), a polar biocompatible lipid, associated or not with oleic acid (OA) were developed. The cationic adjuvants polyethylenimine (PEI) and oleylamine (OAM) were incorporated into these systems to obtain the nanodispersions. Among the aqueous nanodispersions developed, preparations with lower concentration of cationic adjuvant were chosen, these consisting of: MO and OAM at 0.4%, MO and PEI at 0.4%, MO, OA and OAM at 2.5% and MO, OA and PEI at 1.0%. These formulations presented: reduced average particle size, low polydispersity, positive values of zeta potential (an interesting feature for interacting with the siRNA molecules that have a negative charge), low cytotoxicity in vitro and they were able to complex the siRNA at a final concentration of 2.5 ?M. The X-ray diffraction analysis characterized the liquid crystalline phase of these systems as hexagonal, except the nanodispersion MO and PEI at 0.4% which was characterized as a mixture of cubic and hexagonal phases. The nanodispersions obtained were able to increase the skin penetration of siRNA in vitro. With the results obtained, we can conclude that the formulations developed are delivery systems based on nanotechnology, promising for topical administration of siRNA for the treatment of cutaneous diseases in gene therapy. (AU)