Litcius/Paper detail

Not so cold! Improving the thermostability of mRNA vaccines

Jean Haensler, Luc Even, Pierre Wils, Fethi Bensaid, Anusha Dias, Hongfeng Deng, Shrirang Karve, Frank DeRosa

2025Expert Review of Vaccines10 citationsDOIOpen Access PDF

Abstract

INTRODUCTION: One of the biggest challenges in the mRNA-LNP vaccine field is product stabilization to overcome the logistical hurdles linked to the ultra-cold distribution chain associated with first-generation mRNA SARS-CoV-2 vaccines. Despite recent progress in the field, many R&D efforts remain focused on the development of mRNA-LNP vaccines that would be as stable as liquid formulations for storage at refrigerated or room temperatures. AREAS COVERED: After an overview of the underlying mechanisms of mRNA-LNP instability, this review provides an update on the different approaches that are currently explored to improve mRNA-LNP thermostability, encompassing mRNA sequence optimization, nucleotide modification and mRNA-LNP design strategies as well as formulation process optimization. Alternative approaches for mRNA-LNP stabilization such as lyophilization, dual-vial formulations and the replacement of water with deep eutectic solvents in the mRNA-LNP process and products are also discussed. EXPERT OPINION: Achieving robust thermostability of mRNA vaccines will require a multifactorial optimization strategy, integrating advances in sequence engineering, novel formulation designs, buffer composition, excipient selection and manufacturing processes.

Topics & Concepts

ThermostabilityMessenger RNAExcipientChemistryRecombinant DNASelection (genetic algorithm)PeptideBiochemistrySequence (biology)BiologyEnzymeComputational biologyIn vivoMolecular biologyGood manufacturing practiceBuffer (optical fiber)VirologyRNA Interference and Gene DeliveryProtein purification and stabilityRNA and protein synthesis mechanisms