Improved Cryopreservation of Induced Pluripotent Stem Cells Using N-aryl Glycosidic Small Molecule Ice Recrystallization Inhibitors

Abstract

Induced pluripotent stem cells (iPSCs) are an attractive cell source for various applications in regenerative medicine and cell-based therapies given their unique capability to differentiate into any cell type of the human body. However, human iPSCs are highly vulnerable to cryopreservation with post-thaw survival rates of 40-60%; this is due to cryoinjury resulting from ice recrystallization when using conventional slow cooling protocols. Ice recrystallization is a process where the growth of large ice crystals occurs at the expense of small ice crystals. Ice recrystallization inhibitors (IRIs) are designed to inhibit the growth of intracellular ice crystals, increasing post-thaw viability. In this study, we tested a panel of four IRIs to determine if the inhibition of ice recrystallization can decrease cellular damage during freezing and improve viability post-thaw of iPSC colonies. We supplemented commercially available and serum-free cryopreservation medium mFreSR, routinely used for the cryopreservation of iPSCs, with a class of N-aryl-D-ß-gluconamide IRIs. A 2-fold increase in post-thaw viability was observed, in a dose dependent response, for N-(4-methoxyphenyl)-D-gluconamide (PMA) at 15 mM, N-(2-fluorophenyl)-D-gluconamide (2FA) at 10 mM, and N-(4-chlorophenyl)-D-gluconamide (4ClA) at 0.5 mM over mFreSR controls. After testing the panel of four IRIs, 2FA frozen iPSCs showed an increase in cell viability, proliferation, and recovery. The addition of ROCK inhibitor (RI), commonly used to increase iPSC viability post thaw, further enhanced the survival of the iPSCs frozen in the presence of 2FA and is used routinely in research. This additive effect increased cell recovery and colony formation post thaw, resulting in increased proliferation with no adverse effects on iPSC pluripotency or differentiation capabilities. The development of improved cryopreservation strategies for iPSCs is key to establishing master clonal cell banks and limiting cell selection pressures, all while maintaining high post-thaw viability and function. This will help ensure sufficient supplies of high-quality iPSC required to meet the cell demands for cell and regenerative based therapies. Since iPSCs hold promise as a potentially unlimited cell source for a plethora of cell-based therapies, improving cryopreservation is essential to the successful deployment of iPSC-derived therapeutic cell products in the future.