Cryopreservation effects on intermediary metabolism in a pancreatic substitute: a (13)C nuclear magnetic resonance study.

Cryopreservation is important for clinical translation of tissue-engineered constructs. With respect to a pancreatic substitute, encapsulated islets or beta cells have been widely studied for the treatment of insulin-dependent diabetes mellitus. Besides cell viability loss, cryopreservation may affect the function of the remaining viable cells in a pancreatic substitute by altering fundamental processes in glucose-stimulated insulin secretion, such as pathways associated with intermediary metabolism, potentially leading to insulin-secretion defects. In this study, we used (13)C nuclear magnetic resonance (NMR) spectroscopy and isotopomer analysis to determine the effects of conventional freezing and ice-free cryopreservation (vitrification) on carbon flow through tricarboxylic acid (TCA) cycle-associated pathways in encapsulated murine insulinoma ßTC-tet cells; the secretory function of the encapsulated cells postpreservation was also evaluated. Specifically, calcium alginate-encapsulated ßTC-tet cells were frozen or vitrified with a cryoprotectant cocktail. Beads were warmed and (13)C labeling and extraction were performed. Insulin secretion rates were determined during basal and labeling periods and during small-scale glucose stimulation and K(+)-induced depolarization. Relative metabolic fluxes were determined from (13)C NMR spectra using a modified single pyruvate pool model with the tcaCALC modeling program. Treatments were compared with nonpreserved controls. Results showed that relative carbon flow through TCA-cycle-associated pathways was not affected by conventional freezing or vitrification. However, vitrification, but not freezing, led to impaired insulin secretion on a per viable cell basis. The reduced secretion from the Vitrified group occurred irrespective of scale and was present whether secretion was stimulated by glucose or K(+)-induced depolarization, indicating that it might be due to a defect in late-stage secretion events.

Mathematical modeling of cryoprotectant addition and removal for the cryopreservation of engineered or natural tissues.

Long-term storage of natural tissues or tissue-engineered constructs is critical to allow off-the-shelf availability. Vitrification is a method of cryopreservation that eliminates ice formation, as ice may be detrimental to the function of natural or bioartificial tissues. In order to achieve the vitreous state, high concentrations of CPAs must be added and later removed. The high concentrations may be deleterious to cells as the CPAs are cytotoxic and single-step addition or removal will result in excessive osmotic excursions and cell death. A previously described mathematical model accounting for the mass transfer of CPAs through the sample matrix and cell membrane was expanded to incorporate heat transfer and CPA cytotoxicity. Simulations were performed for two systems, an encapsulated system of insulin-secreting cells and articular cartilage, each with different transport properties, geometry and size. Cytotoxicity and mass transfer are dependent on temperature, with a higher temperature allowing more rapid mass transfer but also causing increased cytotoxicity. The effects of temperature are exacerbated for articular cartilage, which has larger dimensions and slower mass transport through the matrix. Simulations indicate that addition and removal at 4°C is preferable to 25°C, as cell death is higher at 25°C due to increased cytotoxicity in spite of the faster mass transport. Additionally, the model indicates that less cytotoxic CPAs, especially at high temperature, would significantly improve the cryopreservation outcome. Overall, the mathematical model allows the design of addition and removal protocols that insure CPA equilibration throughout the sample while still minimizing CPA exposure and maximizing cell survival.

Cytotoxicity effects of cryoprotectants as single-component and cocktail vitrification solutions.

Cryoprotectant (CPA) cytotoxicity constitutes a challenge in developing cryopreservation protocols, specifically in vitrification where high CPA concentrations are necessary to achieve the ice-free, vitreous state. Few cytotoxicity studies have investigated vitrification-relevant concentrations of CPAs, and the benefits and disadvantages of cocktail solutions and of incorporating non-permeating solutes have not been fully evaluated. In this study, we address these issues by determining the cytotoxicity kinetics for dimethylsulfoxide (Me(2)SO) and 1,2-propanediol (PD) on alginate-encapsulated ßTC-tet mouse insulinomas for a range of concentrations and temperatures. Cytotoxicity kinetics were also determined for two cocktails, DPS (3M Me(2)SO+3M PD+0.5M sucrose) and PEG400 (1M Me(2)SO+5M PD+0.34M poly(ethylene)glycol with M.W. of 400). PD was found to be more cytotoxic than Me(2)SO at higher concentrations and temperatures. This was reflected in PEG400 being more cytotoxic at room temperature than PEG400 at 4°C or DPS at either temperature. Addition of non-permeating solutes increased the cytotoxicity of cocktails. Furthermore, results indicate that CPA cytotoxicity may not be additive and that combining CPAs may increase cytotoxicity synergistically. Finally, when comparing cytotoxic effects towards encapsulated HepG2 and ßTC-tet cells, and towards ßTC-tet cells in capsules and in monolayers, CPAs appear more cytotoxic towards cells with higher metabolic activity. The incorporation of these results in the rational design of CPA addition/removal processes in vitrification is discussed.