RESUMEN
Two imaged capillary isoelectric focusing methods were developed to provide insight into the quality and stability of messenger ribonucleic acid (mRNA) vaccines, specifically, mRNA encapsulated in lipid nanoparticles (LNPs). A variety of stressed and lipid composition-modified samples were measured and detected by their UV absorption. The results were supported by the data of an encapsulation assay and particle sizing. One method, using 9 M urea as an additive, shows two broad and jagged peaks in which the peak shape offers detailed information. The summed peak area of both peaks showed RSDs from 2% to 8% when one batch was measured in triplicate and apparently depends on the size of the LNPs. In the second method, a combination of 5.5 M urea and 2 M N-ethylurea was used. This method is characterized by a high repeatability of the isoelectric point (pI, <0.5%). The repeatable peak area (RSD of 2%-7%) correlates linearly with the mRNA content, which also applies to the first method, and added stress is evident by the change in pI and peak area. Furthermore, experiments with the addition of a fluorescent dye were performed (fluorescence detection), which tremendously increased the sensitivity of the methods. Both methods can be used to characterize the stability of mRNA-loaded LNPs, for example, when investigating various storage times at different temperatures and freeze-thaw cycles, as well as the ability of the methods to distinguish lipid compositions and measure batch-to-batch variability.
