Thioamides Adjacent to the Ionizable Amine Headgroup in Ionizable Lipids Reduce the pK of Lipid Nanoparticles and Enhance mRNA Transfection Efficiency in Vitro and in Vivo.

Lipid nanoparticles (LNPs) are currently the most clinically advanced mRNA delivery vectors. However, optimizing LNPs for in vivo applications remains largely empirical. The apparent pKa of LNPs is a predictive factor for in vivo performance, with pK values between 6 and 7 showing the highest efficacy. Despite this critical role of ionizable lipids in LNPs, the relationship between lipid structure and its influence on LNP pK remains poorly studied. In this study, we report the design and the synthesis of a novel class of ionizable lipids featuring a thioamide moiety, enabling direct comparison between thioamide-containing (SAM) LNPs and amide-containing (OAM) LNPs. We find that substituting oxygen with sulfur in the amide group significantly decreases the apparent pK of LNPs, increasing the likelihood of identifying lipids in combinatorial libraries that yield LNPs with a pK in the desired 6-7 range. The reduction in pK in LNPs containing SAM lipids, compared with OAM lipids, is attributed to the increased hydrophobicity of the thioamide group. Furthermore, by synthesizing multiple libraries of SAM lipids and varying the ionizable head group, alkyl chains, and linker length, we discovered thioamide lipids with distinct tissue tropism, including lipids that mediate splenic targeting by LNPs.