Gene delivery in the cornea: in vitro & ex vivo evaluation of solid lipid nanoparticle-based vectors.

AIM: Inflammation is a process that underlies sight-threatening ocular surface diseases, and gene supplementation with the plasmid that encodes for p-IL10 will allow the sustained de novo synthesis of the cytokine to occur in corneal cells, and provide a long-term anti-inflammatory effect. This work describes the development of solid lipid nanoparticle systems for the delivery of p-IL10 to transfect the cornea. RESULTS: In vitro, vectors showed suitable features as nonviral vectors (size, Î¶-potential, DNA binding, protection and release), and they were able to enter and transfect human corneal epithelial cells. Ex vivo, the vectors were found to transfect the epithelium, the stroma and the endothelium in rabbit corneal explants. Distribution of gene expression within the cell layers of the cornea depended on the composition of the four vectors evaluated. CONCLUSION: Solid lipid nanoparticle-based vectors are promising gene delivery systems for corneal diseases, including inflammation.

Lipid nanoparticles as vehicles for macromolecules: nucleic acids and peptides.

Traditional drug delivery systems are not efficient for peptide, protein and nucleic acid (plasmid DNA, oligonucleotides or short interfering RNA) delivery, thereby LNP have been exploited as potential delivery and targeting systems of these molecules. Since their discovery in the early 90's several research groups have focused their efforts on the improvement of this kind of nanocarriers in terms of effectiveness and safety. This review features the recent and most relevant patents related to these topics, with particular attention to targeting and protection from environmental agents. Moreover, in the case of nucleic acids strategies to improve transfection mediated by lipid nanoparticles (entrance to the cells, intracellular distribution or going through nuclear envelope) will be assessed. Regarding peptides and proteins, enhancement of encapsulation efficiency and absorption through mucoses are the main studied drawbacks. Finally, this work also includes a summary of the existing patents about the use of LNP as immune response adjuvants by using either plasmid DNA or proteins.