On the assessment of the stability of vitrified cryo-media by differential scanning calorimetry: A new tool for biobanks to derive standard operating procedures for storage, access and transport.

When a vitrified sample is heated over the glass transition temperature it may start to devitrify endangering the sample. The ability to estimate the stability of the vitrified state can help in the development of new vitrification media as well as handling procedures. By employing differential scanning calorimetry, we can measure the ice crystallization rate in a vitrified sample and thus study the devitrification kinetics. Using this technique, we have studied samples comprised of PBS with cryoprotective additives (CPA) as dimethylsulfoxide (Me2SO), ethylene glycol (EG) and mixtures thereof, regarding the dependence of the devitrification kinetics on the CPA concentration. We found that already small concentration changes lead to significant changes in the devitrification times. Changing the CPA concentration by 4 wt% changed the devitrification time with a factor of 342 and 271 for Me2SO and EG, respectively. Concentration changes in EG/Me2SO mixtures was found to have a smaller impact on the devitrification kinetics compared to the pure CPA samples. Our data suggest that these significant increases in the devitrification times are primarily due to a relation between nucleation rates and the CPA concentration. Finally, we investigated an established vitrification medium used to preserve human embryonic stem cells. This medium was found to have the poorest glass stability in this study and reflects the tradeoff between stability and biocompatibility. The present work finally provides a tool to evaluate handling and storage procedures when employing vitrification as a cryopreservation method and underlines the importance of these.

Poly(amidoamine)-alginate hydrogels: directing the behavior of mesenchymal stem cells with charged hydrogel surfaces.

The surface charge of a biomaterial represents a promising tool to direct cellular behavior, which is crucial for therapeutic approaches in regenerative medicine. To expand the understanding of how the material surface charge affects protein adsorption and mesenchymal stem cell behavior, differently charged surfaces with zeta potentials spanning from -25 mV to +15 mV were fabricated by the conjugation of poly(amidoamine) to alginate-based hydrogels. We showed that the increase of the biomaterials surface charge resulted in enhanced quantities of biologically available, surface-attached proteins. Since different surface charges were equalized after protein adsorption, mesenchymal stem cells interacted rather with diverse protein compositions instead of different surface features. Besides an enhanced cell attachment to increasingly positively charged surfaces, the cell spreading area and the expression of adhesion-related genes integrin α5 and tensin 1 were found to be increased after adhesion. Moreover, first results indicate a potential impact of the surface charge on mesenchymal stem cell differentiation towards bone and fat cells. The improved understanding of surface charge-related cell behavior has significant impact on the design of biomedical devices and artificial organs.