Active modulation of Hydrogen bonding by sericin enhances cryopreservation outcomes

Abstract

AbstractCryopreservation of cells without any toxicity concerns is a critical step in ensuring successful clinical translation of cell-based technologies. Mitigating the toxicity concerns related to most of the commonly used cryoprotectants including dimethyl sulfoxide (DMSO) is an active area of research in cryobiology. In recent years use of additives including polymeric proteins such has sericin have been explored as an additive to cryoprotectant formulations. In this study the thermophysical effect of addition of sericin was investigated. The effect of presence of sericin on the H-bonding strength was investigated using Raman microspectroscopy and other thermophysical effects were quantified using differential scanning calorimetry (DSC) techniques. Finally, the prospect of using sericin as an additive to cryoprotectant formulation was investigated by monitoring cellular viability and growth following exposure to cryogenic temperatures in hepatocellular carcinoma cells. Results indicate significant improvement in post-thaw viability when sericin is used as an additive to DMSO based formulations. While use of trehalose as an additive has beneficial effects by itself, combined usage of sericin and trehalose as additives did result in an improved overall long-term growth potential of the cells.Statement of SignificanceThis study provides for powerful biophysical understanding of how sericin can be used as an additive for cryoprotectant solutions, which allows storage of biologics at low temperatures. It is desirable to replace current components of cryoprotectant formulation (such as DMSO) due to innate toxicity and metabolic derangements to cells. The ability of sericin to improve cryoprotective solutions was mechanistically characterized by Raman microspectroscopy, which allows for molecular level characterization of the nature of H-bonding in aqueous environments in presence of solution components. Thermodynamic analysis of the cryoprotectant solutions containing sericin was undertaken to quantify the relation between solution composition and cryopreservation outcome. This analytical study provides a basis for designing better cryoprotectants with lower thermophysical injury and higher cellular yields.