Advances in the rational design of ionizable lipids for mRNA therapeutics
Yeji Lee, Kaiyuan Guo, Mi-Young Oh, Eunbin Kim, Yujeong Jeong, Y. C. Yoon, Yelim Choi, Yelim Choi, Yongjoo Byeon, Yizhou Dong, Hyukjin Lee, Hyukjin Lee
Abstract
Ionizable lipids are key components in lipid nanoparticles (LNPs) for nucleic acid therapeutics, primarily facilitating endosomal escape. Beyond this function, recent advances have demonstrated their broader roles, including immunogenicity modulation, toxicity reduction, and tissue-specific targeting. This review categorizes current approaches in ionizable lipid design, including functionalized lipid modifications, high-throughput combinatorial libraries, and machine learning-driven discovery methods. We explore how these strategies expand the chemical diversity of ionizable lipids, enabling the identification of novel structures with enhanced delivery properties and specialized biological functions. By integrating computational and experimental methodologies, this review provides a comprehensive framework for guiding the next generation of ionizable lipids in nanoparticle-based drug delivery systems.