Development of efficient delivery vehicles for in vitro transcribed mRNA (IVT mRNA) is currently a major challenge in nanomedicines. For systemic mRNA delivery, we developed a series of cationic amphiphilic polyaspartamide derivatives (PAsp(DET/R)s) carrying various alicyclic (R) moieties with diethylenetriamine (DET) in the side chains to form mRNA-loaded polyplexes bearing stability under physiological conditions and possessing endosomal escape functionality. While the size and ζ-potential of polyplexes were comparable among various PAsp(DET/R)s, the transfection efficiencies of polyplexes were considerably varied due to difference in the R moieties of PAsp(DET/R)s and were described by an octanol-water (or buffer at pH 7.3) distribution coefficient (logD7.3). The critical logD7.3 for the efficient in vitro transfection of mRNA was indicated at -2.7 to -1.8. The polyplexes with logD7.3 > -1.8 elicited the much higher in vitro transfection efficiencies. After systemic administration, the polyplexes with logD7.3 from -1.8 to -1.3 elicited the significant mRNA expression specifically in the lungs. The highest mRNA expression in the lungs was achieved by a polyaspartamide derivative having a cyclohexylethyl group (PAsp(DET/CHE)), which induced more than 10-fold increase in mRNA transfection efficiency compared to commercially available lipid nanoparticles. The higher mRNA expression by polyplexes in the lungs was explained well by the preferential lung accumulation of intact mRNA, as determined by quantitative real-time PCR. Our results demonstrate that PAsp(DET/R)s are a promising synthetic material for the enhanced systemic IVT mRNA delivery.
Keywords: Intravenous administration; Poly(amino acid); Polyplex; mRNA delivery.
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