Identification of film-based formulations that move mRNA lipid nanoparticles out of the freezer

Abstract

COVID-19 vaccines consisting of mRNA lipid nanoparticles (LNPs) encoding the SARS-CoV-2 spike protein antigen protected millions of people from severe disease, however, they must be stored frozen prior to use. The objective of this study was to evaluate the compatibility and stability of mRNA LNPs within a polymer-based film matrix. An optimized formulation of polymer base, glycerol, surfactants and PEGylated lipid that prevents damage to the LNP due to physical changes during the film forming process (osmotic stress, surface tension, spatial stress and water loss) was identified. Surfactants added to LNP stock prior to mixing with other film components contributed to this effect. Formulations prepared at pH ≥ 8.5 extended transfection efficiency beyond 4 weeks at 4oC when combined with known nucleic acid stabilizers. mRNA LNPs were most stable in films when manufactured in an environment of ∼50% relative humidity. The optimized formulation offers 16 week stability at 4oC.