Multivalent Peptide-Functionalized Bioreducible Polymers for Cellular Delivery of Various RNAs.

RNA-based therapeutics have garnered tremendous attention due to their potential to revolutionize protein replacement therapies, immunotherapy, and treatment of genetic disorders. The lack of safe and efficient RNA delivery methods has significantly hindered the clinical translation and widespread application of RNA-based therapeutics. With differing sizes and structures of therapeutic RNA molecules, a critical challenge of the field is to develop RNA delivery systems that accommodate these variations while retaining high biocompatibility and efficacy. In this study, we developed a series of multivalent peptide-functionalized bioreducible polymers (MPBP) as a safe and efficient delivery vehicle derived from a core polymer backbone for various RNA species. The facile synthesis of MPBPs from a single polymer backbone provides access to numerous polymers with diverse architectures that enable cellular delivery of different RNA cargos. Postfunctionalization with multifunctional peptides enables strong RNA complexation, enhanced cellular uptake, and facilitates endosomal escape of cargo. The high delivery efficiency and low cytotoxicity for various RNA-MPBP nanoparticles in multiple cell lines demonstrates that the MPBP approach is a novel promising vector strategy for future RNA delivery systems.

Silyl Ether as a Robust and Thermally Stable Dynamic Covalent Motif for Malleable Polymer Design.

Here we introduce silyl ether linkage as a novel dynamic covalent motif for dynamic material design. Through introduction of a neighboring amino moiety, we show that the silyl ether exchange rate can be accelerated by almost three orders of magnitude. By incorporating such silyl ether linkages into covalently cross-linked polymer networks, we demonstrate dynamic covalent network polymers displaying both malleability and reprocessability. The malleability of the networks is studied by monitoring stress relaxation at varying temperature, and their topology freezing temperatures are determined. The tunable dynamic properties coupled with the high thermal stability and reprocessability of silyl ether-based networks open doors to many potential applications for this family of materials.