Lilia L. Kuleshova

Cryopreservation of mouse testicular tissue: prospect for harvesting spermatogonial stem cells for fertility preservation

OBJECTIVE To investigate the efficacy of vitrification, rapid freezing, and slow freezing in preserving testicular tissue for subsequent isolation of spermatogonial stem cells. DESIGN Experimental study. SETTING University-based laboratory. ANIMALS Immature mouse testicular tissue. INTERVENTION(S) The tunica of the testis was manipulated before cryopreservation. The tunica was either breached with a fine needle or completely removed, or the testis was sectioned longitudinally into halves. MAIN OUTCOME MEASURE(S) Cell viability by Trypan blue exclusion test and flow cytometry analysis of live-dead cytotoxicity test, measurement of hormonal production, enrichment of spermatogonial stem cells with use of magnetic-activated cell sorting technology. RESULT(S) Samples with tunica minimally penetrated with a needle point gave the highest cell viability after freezing and thawing. Vitrification protocol with use of an ethylene glycol-sucrose-based vitrification solution (40% vol/vol ethylene glycol-0.6 mol/L sucrose) was able to maintain postwarming cell viability and functions similar to those of noncryopreserved controls and significantly better than both conventional slow and rapid freezing protocols. Primitive spermatogonial stem cells were enriched successfully from vitrified tissue via magnetic-activated cell sorting. CONCLUSION(S) Vitrification of testicular tissue is a time- and cost-efficient strategy to preserve spermatogonial stem cells for potential transplantation procedure.

Vitreous cryopreservation of nanofibrous tissue-engineered constructs generated using mesenchymal stromal cells

Development of an effective preservation strategy to fulfill off-the-shelf availability of tissue-engineered constructs (TECs) is demanded for realizing their clinical potential. In this study, the feasibility of vitrification, ice-free cryopreservation, for precultured ready-to-use TECs was evaluated. To prepare the TECs, bone marrow-derived porcine mesenchymal stromal cells (MSCs) were seeded in polycaprolactone-gelatin nanofibrous scaffolds and cultured for 3 weeks before vitrification treatment. The vitrification strategy developed, which involved exposure of the TECs to low concentrations of cryoprotectants followed by a vitrification solution and sterile packaging in a pouch with its subsequent immersion directly into liquid nitrogen, was accomplished within 11min. Stepwise removal of cryoprotectants, after warming in a 38 degrees C water bath, enabled rapid restoration of the TECs. Vitrification did not impair microstructure of the scaffold or cell viability. No significant differences were found between the vitrified and control TECs in cellular metabolic activity and proliferation on matched days and in the trends during 5 weeks of continuous culture postvitrification. Osteogenic differentiation ability in vitrified and control groups was similar. In conclusion, we have developed a time- and cost-efficient cryopreservation method that maintains integrity of the TECs while preserving MSCs viability and metabolic activity, and their ability to differentiate.

Effective cryopreservation of neural stem or progenitor cells without serum or proteins by vitrification.

Development of effective cryopreservation protocols will be essential to realizing the potential for clinical application of neural stem and progenitor cells. Current cryopreservation protocols have been largely employed in research, which does not require as stringent consideration of viability and sterility. Therefore, these protocols involve the use of serum and protein additives, which can potentially introduce contaminants, and slow cooling with DMSO/glycerol-based cryopreservation solutions, which impairs cell survival. We investigated whether serum- and protein-free vitrification is effective for functional cryopreservation of neurosphere cultures of neural stem or progenitor cells. To protect the samples from introduction of other contaminants during handling and cryostorage, an original “straw-in-straw” method (250 μl sterile straw placed in 500 μl straw) for direct immersion into liquid nitrogen and storing the samples was also introduced. The protocol employed brief step-wise exposure to vitrification solution composed of ethylene glycol (EG) and sucrose (40% v/v EG, 0.6 M sucrose) and removal of vitrification solution at room temperature. Evaluation of the effects of vitrification revealed that there were no differences between control and vitrified neural stem or progenitor cells in expression of the neural stem or progenitor cell markers, proliferation, or multipotent differentiation. This sterile method for the xeno-free cryopreservation of murine neurospheres without animal or human proteins may have the potential to serve as a starting point for the development of cryopreservation protocols for human neural stem and progenitor cells for clinical use.

Influence of cell culture configuration on the post-cryopreservation viability of primary rat hepatocytes

Cryopreservation has been identified as a necessary barrier to overcome in the production of tissue engineered products for clinical application. Liver engineering and bioartificial liver assisting devices are on the forefront of tissue engineering research due to its high demand and clinical potential. In this study we propose that the cryopreservation of primary mammalian hepatocytes yields better results when these cells are in a tissue-like culture configuration since cell attachment is essential for cell survival in this cell type. We used two different tissue-engineered culture configurations: monolayers and spheroid culture; and two different concepts of cryopreservation, namely vitrification and freezing. Cell suspensions were also cryopreserved using both approaches and results were compared to the engineered cultures. Both engineered configurations and suspension were cryopreserved using both conventional freezing (cooling at 1 °C/minute using 10% DMSO in foetal calf serum) and vitrification (using 40% ethylene glycol 0.6 m sucrose supplemented with 9% Ficoll). These two approaches differ on the degree of mechanical stress they inflict on the material to be cryopreserved. The maintenance of cell-to-cell and the integrity of the actin cytoskeleton were assessed using scanning electron microscopy and immunohistochemistry respectively. Results showed that while there was no significant difference between the degree of integrity shown between vitrified and control engineered cultures, the same did not happen to the frozen engineered constructs. The disruption of the cytoskeletal structure correlated with increased levels of apoptotic markers. With cryopreserved suspensions there was evidence of disruption of the cytoskeletal structure. This study concluded that cell-to-cell contact is beneficial in the maintenance of viability post-cryopreservation and that the vitrification approach was far superior to those of conventional freezing when applied to 2D and 3D hepatocyte based engineered cultures.

Vitrification successfully preserves hepatocyte spheroids.

This is the first report on low-temperature preservation of self-assembled cell aggregates by vitrification, which is both a time- and cost-effective technology. We developed an effective protocol for vitrification (ice-free cryopreservation) of hepatocyte spheroids that employs rapid stepwise exposure to cryoprotectants (10.5 min) at room temperature and direct immersion into liquid nitrogen (-196°C). For this, three vitrification solutions (VS) were formulated and their effects on vitrified-warmed spheroids were examined. Cryopreservation using ethylene glycol (EG)-sucrose VS showed excellent preservation capability whereby highly preserved cell viability and integrity of vitrified spheroids were observed, through confocal and scanning electron microscopy imaging, when compared to untreated control. The metabolic functions of EG-sucrose VS-cryopreserved spheroids, as assessed by urea production and albumin secretion, were not significantly different from those of control within the same day of observation. In both the vitrification and control groups, albumin secretion was consistently high, ranging from 47.57 ± 14.39 to 70.38 ± 11.29 μg/106 cells and from 56.84 ± 14.48 to 71.79 ± 16.65 μg/106 cells, respectively, and urea production gradually increased through the culture period. The efficacy of vitrification procedure in preserving the functional ability of hepatocyte spheroids was not improved by introduction of a second penetrating cryoprotectant, 1,2-propanediol (PD). Spheroids cryopreserved with EG-PD-sucrose VS showed maintained cell viability; however, in continuous culture, levels of both metabolic functions were lower than those cryopreserved with EG-sucrose VS. EG-PD VS, in which nonpenetrating cryoprotectant (sucrose) was excluded, provided poor protection to spheroids during cryopreservation. This study demonstrated that sucrose plays an important role in the effective vitrification of self-assembled cell aggregates. In a broad view, the excellent results obtained suggest that the developed vitrification strategy, which is an alternative to freezing, may be effectively used as a platform technology in the field of cell transplantation.

The use of vitrification to preserve primary rat hepatocyte monolayer on collagen-coated poly(ethylene-terephthalate) surfaces for a hybrid liver support system

We developed a scaled-up procedure for vitrifying hepatocytes for hybrid liver support system applications. Hepatocyte monolayer cultured on collagen-coated polyethylene terephthalate (PET) discs constituted the basic module for a hybrid liver support system. Freshly isolated rat hepatocytes were seeded on collagen-coated PET discs with a diameter of 33 mm at a density of 5x10(6) cells per disc, and were cultured for 24 h before cryopreservation. The total duration of procedure starting from exposure to low concentrations of cryoprotectants up to cryostorage is 10 min. Vitrification of the modules was achieved by using two vitrification solutions sequentially with first vitrification solution containing two cryoprotectants, ethylene glycol (EG) and sucrose, while second vitrification solution contained additionally polymer, Ficoll. Direct exposure to liquid nitrogen vapours was followed by immersion into liquid nitrogen. Recovery procedure for vitrified modules included their warming in 1m sucrose at temperature of 38-39 degrees C followed by subsequently washing in sucrose-based solutions of decreased concentration within 15 min at room temperature. Viability, structural characteristics, and functions of cells were preserved by vitrification. Hepatocytes in the post-vitrified and warmed monolayer maintained differentiated hepatocyte characteristics both structurally and functionally. In average, protein synthesis measured as albumin production was 181.00+/-33.46 ng/million cells and 166.10+/-28.11 ng/million cells, for control and vitrified modules respectively. Urea production was, in average, 1.52+/-0.40 ng/million cells and 1.36+/-0.31 ng/million cells for a 7 day culture respectively, with no significant statistical difference between the control and vitrified modules.

Chapter 13 – Cryobiology

Publisher Summary This chapter deals with cryobiology, which is the study of effects of subfreezing temperatures on biological systems stands at the interface between physics and biology. Cryobiology covers three broad areas: the study of cold-adaptation of plants and animals, cryosurgery, and cryopreservation. Cryopreservation, which deals with the storage of biological materials at low temperature, is of particular interest for tissue engineering (TE). The most common concept underlying TE is to combine a scaffold (cellular solids) or matrix (hydrogels) with living cells to form a ‘tissue engineered construct ’ (TEC) to promote the repair and regeneration of tissues. Cryopreservation plays an important role in cell and tissue banking. It attains even greater importance in the future within the field of tissue engineering (TE) as off-the-shelf products are a prerequisite for routine clinical applications.

Development of a modified vitrification strategy suitable for subsequent scale-up for hepatocyte preservation.

This work explores the design of a vitrification solution (VS) for scaled-up cryopreservation of hepatocytes, by adapting VS(basic) (40% (v/v) ethylene glycol 0.6M sucrose, i.e. 7.17 M ethylene glycol 0.6M sucrose), previously proven effective in vitrifying bioengineered constructs and stem cells. The initial section of the scale-up study involved the selection of non-penetrating additives to supplement VS(basic) and increase the solutions total solute concentration. This involved a systematic approach with a step-by-step elimination of non-penetrating cryoprotectants, based on their effect on cells after long/short term exposures to high/low concentrations of the additives alone or in combinations, on the attachment ability of hepatocytes after exposure. At a second stage, hepatocyte suspension was vitrified and functions were assessed after continuous culture up to 5 days. Results indicated Ficoll as the least toxic additive. Within 60 min, the exposure of hepatocytes to a solution composed of 9% Ficoll+0.6M sucrose (10⁻³ M Ficoll+0.6 M sucrose) sustained attachment efficiency of 95%, similar to control. Furthermore, this additive did not cause any detriment to the attachment of these cells when supplementing the base vitrification solution VS(basic). The addition of 9% Ficoll, raised the total solute concentration to 74.06% (w/v) with a negligible 10⁻³ M increase in molarity of the solution. This suggests main factor in inducing detriment to cells was the molar contribution of the additive. Vitrification protocol for scale-up condition sustained hepatocyte suspension attachment efficiency and albumin production. We conclude that although established approach will permit scaling-up of vitrification of hepatocyte suspension, vitrification of hepatocytes which are attached prior to vitrification is more effective by comparison.