Advancing nucleic acid delivery through cationic polymer design: non-cationic building blocks from the toolbox

Abstract

Polymers used for the delivery of nucleic acids (NAs) typically possess ionizable, cationic moieties enabling their electrostatic interaction with negatively charged NAs and form stable polyplexes. However, non-cationic building blocks have been harnessed to design cationic polymers with enhanced delivery of DNA/RNA to tissues, cells, and subcellular compartments while remaining stable in biological fluids. By customizing the chemistry of these functional groups, we can improve cell targeting behavior, uptake, endosomal escape, non-toxicity, and transfection efficiency. Additionally, the physicochemical properties such as the loading capacity, complexation ability, size and morphology, biodegradability, pH sensitivity, and amphiphilicity can be adjusted based on the specific application. This review summarizes the role of non-cationic moieties in various biomedical contexts, from therapeutic interventions to gene editing. By unpacking and critically summarizing the existing literature, this review provides valuable insights into the rational integration of these building blocks for designing more effective nanovectors to deliver NAs.