A novel strategy for conservation of European eel (Anguilla anguilla) genetic resources: Cryopreservation of ovarian stem cells

The aim of this study was to develop short- and long-term preservation protocols for European eel ovarian stem cells (OSCs) through hypothermic storage and cryopreservation of ovarian fragments that will assist in current conservation programs of this critically endangered species. Firstly, a freezing procedure was developed by testing different cryomedia and technical aspects of freezing. Utilization of 1.5 M of dimethyl sulfoxide (Me₂SO), 0.1 M glucose and 1.5% BSA yielded optimal OSCs survival. Additionally, equilibration of 50-mg ovarian fragments for 30 min and plunging into lN₂ at −80 °C displayed the highest OSC viability. Different cooling rates ranging from −1 to −40 °C/min did not significantly affect OSC viability when thawing in a 10 °C water bath. In addition, application of needle-immersed vitrification (NIV), combining ES3 (1.5 M PG and 1.5 M Me₂SO) with VS3 (3 M PG and 3 M Me₂SO) yielded the highest viability rates. Finally, hypothermic storage (4 °C) of ovarian fragments and ovarian cell suspensions displayed favorable viability of ~90% after 48 h of storage and ~65% after 72 h of storage. The development of OSC preservation methods presents an onset of further development of germline stem cell (GSC) manipulation techniques in this species. Cryopreservation of OSCs can enable a continuous supply of cells for either transplantation or in vitro cell culture thus enabling new and improved management and conservation strategies for this endangered species.     

Microalgal cryo-preservation using dimethyl sulfoxide (Me2SO) coupled with two freezing protocols: Influence on the fatty acid profile

Procedures for determining the optimal pre-freezing protocol for cryo-preservation of microalgae are discussed. Three algal species were used (Chlorella vulgaris, Isochrysis galbana and Dunaliella salina) and cryo-stored using two different methods: the slow cooling and the fast freezing. In the slow cooling, each algae batch was treated with or without cryo-protectant (dimethyl sulfoxide: Me₂SO 5% v/v). After 20 min at 4 °C, the midi-straws were filled and cooled slowly (1.5 °C min⁻¹) to −140 °C, by a programmable freezer (Digitcool—IMV), before putting them directly into liquid nitrogen. Fast freezing was performed with 10% or 15% Me₂SO prior to plunging into liquid nitrogen. The three algal species followed the same re-growth pattern as that of the controls. The post-thawed viability with Me₂SO was good for all the selected algae (C. vulgaris >95%, I. galbana and D. salina >70% of the control), applying the slow cooling. The post-thawed viability without Me₂SO was 60% for I. galbana, 52% for D. salina and 33% for C. vulgaris. Fast freezing was not suitable for cryo-storage of I. galbana but gave good post-thawing viability for D. salina (70%). The decrease in fatty acid content of the cryo-stored algae was influenced by the temperature. The rapid decrease in temperature induced by fast freezing can explain the low level of fatty acid content of the three cryo-stored algae. Fatty acid profiles show that the nutritional values of the three cryo-stored micro-algae were not significantly affected especially when treated with slow cooling protocols.     

Characterizing the ability of an ice recrystallization inhibitor to improve platelet cryopreservation

Improving aspects of platelet cryopreservation would help ease logistical challenges and potentially expand the utility of frozen platelets. Current cryopreservation procedures damage platelets, which may be caused by ice recrystallization. We hypothesized that the addition of a small molecule ice recrystallization inhibitor (IRI) to platelets prior to freezing may reduce cryopreservation-induced damage and/or improve the logistics of freezing and storage. Platelets were frozen using standard conditions of 5–6% dimethyl sulfoxide (Me₂SO) or with supplementation of an IRI, N-(2-fluorophenyl)-d-gluconamide (2FA), prior to storage at −80 °C. Alternatively, platelets were frozen with 5–6% Me₂SO at −30 °C or with 3% Me₂SO at −80 °C with or without 2FA supplementation. Supplementation of platelets with 2FA improved platelet recovery following storage under standard conditions (p = 0.0017) and with 3% Me₂SO (p = 0.0461) but not at −30 °C (p = 0.0835). 2FA supplementation was protective for GPVI expression under standard conditions (p = 0.0011) and with 3% Me₂SO (p = 0.0042). Markers of platelet activation, such as phosphatidylserine externalization and microparticle release, were increased following storage at −30 °C or with 3% Me₂SO, and 2FA showed no protective effect. Platelet function remained similar regardless of 2FA, although functionality was reduced following storage at −30 °C or with 3% Me₂SO compared to standard cryopreserved platelets. While the addition of 2FA to platelets provided a small level of protection for some quality parameters, it was unable to prevent alterations to the majority of in vitro parameters. Therefore, it is unlikely that ice recrystallization is the major cause of cryopreservation-induced damage.     

Cryopreservation of swine colostrum-derived cells

Mesenchymal stromal cells (MSCs) have been demonstrated to possess anti-inflammatory and antimicrobial properties and are of interest in biotechnologies that will require cryopreservation. Recently, MSC-like cells were isolated from colostrum and milk. We used an interrupted slow freezing procedure to examine cryoinjury incurred during slow cooling and rapid cooling of MSC-like cells from swine colostrum. Cells were loaded with either dimethyl sulfoxide (Me₂SO) or glycerol, cooled to a nucleation temperature, ice-nucleated, and further cooled at 1 °C/min. At several temperatures along the cooling path, cells were either thawed directly, or plunged into liquid nitrogen for storage and later thawed. The pattern of direct-thaw and plunge-thaw responses was used to guide optimization of cryopreservation protocol parameters. We found that both 5% Me₂SO (0.65 M, loaded for 15 min on ice) or 5% glycerol (0.55 M, loaded for 1 h at room temperature) yielded cells with high post-thaw membrane integrity when cells were cooled to at least −30 °C before being plunged into, and stored in, liquid nitrogen. Cells cultured post-thaw exhibited osteogenic differentiation similar to fresh unfrozen control. Fresh and cryopreserved MSC-like cells demonstrated antimicrobial activity against S. aureus. Also, the antimicrobial activity of cell-conditioned media was higher when both fresh and cryopreserved MSC-like cells were pre-exposed to S. aureus. Thus, we were able to demonstrate cryopreservation of colostrum-derived MSC-like cells using Me₂SO or glycerol, and show that both cryoprotectants yield highly viable cells with osteogenic potential, but that cells cryopreserved with glycerol retain higher antimicrobial activity post-thaw.     

Skin cryopreservation: I. Incorporation of radioactive sulfate as a criterion of pigskin graft viability after freezing to −196 °C in the presence of cryoprotectants

The incorporation of radioactive sulfate into glycosaminoglycans was used as a criterion of pigskin graft viability after surface treatment of the pig hide and after cooling and freezing of the graft. Complete surface treatment of the hide (soap, ethanolic iodine, antibiotics, and saline) diminished the incorporation of sulfate by about 40% compared with the control graft. During cooling and freezing the pigskin graft was submitted to 30-min exposures at 20, 4, ?18, ?50, ?150, and ?196 °C sequentially in a medium containing 0.65% NaCl, 3% sorbitol, and either 15% glycerol or 15% Me₂SO. Cooling to ?18 °C reduced the incorporation of sulfate only in the grafts protected by glycerol. A considerable decrease of incorporation was observed after freezing the graft to ?150 and ?196 °C in both cryoprotective solutions. The inclusion of a hold at ?50 °C was important, especially in the case of the Me₂SO medium when about 30% of ³⁵S radioactivity was recovered in the cryopreserved graft compared with the control sample.     

Cryopreservation of sperm from seven-band grouper,Epinephelus septemfasciatus

In the present study, we examined methods for the cryopreservation of Epinephelus septemfasciatus spermatozoa. The percent motility, average path velocity, and linearity of movement (LIN) of fresh and corresponding post-thaw sperm were evaluated. Sperm motility was investigated using computer-assisted sperm analysis. Five percent dimethyl sulphoxide (Me₂SO) with 95% fetal bovine serum (FBS) was the most successful cryoprotectant diluent with a comparative post-thaw motility of 77.6 ± 8.5%; 5% dimethyl formamide was also effective. Fetal bovine serum was significantly better as an extender when compared with artificial seminal plasma, glucose, and trehalose solution. Sperm tolerated a wide range of cooling rates (from 27.1 to 94.3 °C min^?1); however, the post-thaw motility of sperm cooled to ?30 °C was significantly lower than that of other cooled temperatures (?40 to ?70 °C). The velocity of post-thaw sperm was significantly lower than that of fresh sperm, although LIN remained the same. For effective cryopreservation of seven-band grouper sperm, samples should be diluted in 5% Me₂SO with 95% FBS and cooled to at least ?40 °C before immersion in liquid nitrogen.     

Is axenicity crucial to cryopreserve microalgae?

Large culture collections of microalgae and cyanobacteria such as the Coimbra Collection of Algae (ACOI) hold unialgal cultures consisting of a population of cells/colonies of a certain species. These cultures are usually non-axenic, as other organisms such as bacteria and microfungi are also present in culture due to co-isolation. Attention has been recently given to partner organisms since studies indicate that some bacteria are important for nutrient uptake of the algal cells, acting as simbionts. Despite this benign effect in the actively growing cultures, when cryopreservation is applied for inactive-stage storage, these organisms may recover faster than the algae, thus affecting their recovery and the viability assessments. In this study, a set of mucilaginous ACOI microalgae were selected, cell features known for their relevance in cryopreservation success were recorded and simple two-step cryopreservation tests were applied. Thawed samples were transferred to fresh culture medium for recovery. Viability was assessed and partner organism proliferation (pop) was recorded. Results were analyzed by t-tests. Statistical models allowed us to support the known tendency for small, unicellular algae with no outer structures to be successfully cryopreserved and the negative effect of vacuoles in the cell prior to cryopreservation. On average cryopreservation with MeOH or Me₂SO led to the recovery of nearly half the cells. It was found that the cryoprotection step with MeOH is when pop is triggered and that the use of Me₂SO can prevent this effect. Progress on understanding the cultured consortia will assist the improvement of cryopreservation and research using microalgal cultures.     

Comparison of cryopreservation methods for the long term storage of the marine diatom Haslea ostrearia (simonsen)

Long term maintenance of microalgal strains by serial subculturing is often expensive and time-consuming. Alternative methods, such as cryopreservation, present several benefits and thus seem more relevant. Our study aimed at comparing two cryopreservation procedures applied to the marine diatom Haslea ostrearia (Simonsen): (1) a two-step freezing method in liquid media using 5%, 10% and 20% MeOH, Me₂SO or Glycerol, and (2) an immobilization-dehydration method consisting in an algal cell entrapped in 0.7 M sucrose dehydrated and air-flow desiccated calcium alginate beads before “direct” or “two-step” freezing. Our results showed that the cryopreservation of H. ostrearia was feasible. With the two-step freezing protocol only Me₂SO maintained cell viability without contamination but the low percentage of viability (<10%) prevents its use. Conversely, the immobilization-dehydration methods tested in this study were effective. Average viability of 57% and 77% were obtained with the “direct” and the “two step” cooling assays respectively, ensuring preservation of the genetic traits of H. ostrearia.     

Structure and function of human fetal endocrine pancreas before and after cryopreservation

Human fetal pancreatic glands obtained from 31 consecutive prostaglandin-induced abortions were examined with respect to light microscopic structure and insulin content and release before and after cryopreservation. The crown-heel lengths of the fetuses ranged from 12 to 34 cm. Minced pancreatic fragments about 2 mm³ in size were cultured overnight in RPMI 1640 medium plus 10% fetal calf serum. The explants were incubated at 0 °C for 20 min in Hanks' solution containing 1 M Me₂SO and subsequently cooled at 0.3 °C/min to ?70 °C before rapid quenching in liquid nitrogen. After storage for 4–150 days at ?196 °C the pancreatic fragments were rapidly thawed and suspended in RPMI 1640 (10% calf serum) for another overnight culture.After cryopreservation there was some morphological deterioration of the fetal pancreas. Before cryopreservation 13 of the fetal glands responded with a significant insulin release to an acute glucose plus theophylline challenge, while after cryopreservation 16 glands responded.Although cryopreservation lowered the insulin response there was a strong statistical correlation between the response obtained before and after freezing (P < 0.001). No correlation could be demonstrated between the insulin response and crown-heel length either before or after freezing. There was no obvious effect of cryopreservation on the pancreatic insulin content which showed a significant correlation with the crown—heel length both before and after freezing.It is concluded that cryopreservation of human fetal endocrine pancreas preserves the viability of the B cells. These observations provide a basis for further exploration of the suitability of human fetal pancreas for clinical transplantation.     

Viscosities encountered during the cryopreservation of dimethyl sulphoxide systems

This study determined the viscous conditions experienced by cells in the unfrozen freeze concentrated channels between ice crystals in slow cooling protocols. This was examined for both the binary Me₂SO-water and the ternary Me₂SO-NaCl-water systems.Viscosity increases from 6.9 ± 0.1 mPa s at −14.4 ± 0.3 °C to 958 ± 27 mPa s at −64.3 ± 0.4 °C in the binary system, and up to 55387 ± 1068 mPa s at −75 ± 0.5 °C in the ternary (10% Me₂SO, 0.9% NaCl by weight) solution were seen. This increase in viscosity limits molecular diffusion, reducing adsorption onto the crystal plane. These viscosities are significantly lower than observed in glycerol based systems and so cells in freeze concentrated channels cooled to between −60 °C and −75 °C will reside in a thick fluid not a near-solid state as is often assumed.In addition, the viscosities experienced during cooling of various Me₂SO based vitrification solutions is determined to below −70 °C, as is the impact which additional solutes exert on viscosity. These data show that additional solutes in a cryopreservation system cause disproportionate increases in viscosity. This in turn impacts diffusion rates and mixing abilities of high concentrations of cryoprotectants, and have applications to understanding the fundamental cooling responses of cells to Me₂SO based cryopreservation solutions.     

Ovarian tissue cryopreservation by stepped vitrification and monitored by X-ray computed tomography

Ovarian tissue cryopreservation is, in most cases, the only fertility preservation option available for female patients soon to undergo gonadotoxic treatment. To date, cryopreservation of ovarian tissue has been carried out by both traditional slow freezing method and vitrification, but even with the best techniques, there is still a considerable loss of follicle viability. In this report, we investigated a stepped cryopreservation procedure which combines features of slow cooling and vitrification (hereafter called stepped vitrification). Bovine ovarian tissue was used as a tissue model. Stepwise increments of the Me₂SO concentration coupled with stepwise drops-in temperature in a device specifically designed for this purpose and X-ray computed tomography were combined to investigate loading times at each step, by monitoring the attenuation of the radiation proportional to Me₂SO permeation. Viability analysis was performed in warmed tissues by immunohistochemistry. Although further viability tests should be conducted after transplantation, preliminary results are very promising. Four protocols were explored. Two of them showed a poor permeation of the vitrification solution (P1 and P2). The other two (P3 and P4), with higher permeation, were studied in deeper detail. Out of these two protocols, P4, with a longer permeation time at −40 °C, showed the same histological integrity after warming as fresh controls.     

The influence of ultra-low temperatures on marine microalgal cells

The development of cryopreservation methods for microalgae opens great prospects for marine biotechnology and aims to establish a bank of cryopreserved cultures. Eight of ten marine microalgae species used in this study (the diatoms, green, red, and golden algae), including five previously untested species, were successfully recovered after freezing to ultra-low temperatures (?196 °C) using penetrating (dimethyl sulfoxide, glycerol, and ethylene glycol) and non-penetrating (trehalose and polyvinylpyrrolidone) cryoprotectants. We found that ethylene glycol in combination with trehalose possessed the most effective cryoprotective activity among the algae cryoprotectants tested. However, the chief factor for the successful preservation of microalgal cells during freeze–thawing was shown to be the cooling rate. Cooling was performed in two ways: step or fast droplet freezing. The droplet freezing described here was effective only for cryopreserving green algae, whereas step freezing was optimal for all other algal species. Three diatoms of the genus Attheya were successfully cryopreserved for the first time, but none of the tested protocols had a positive result for the diatoms belonging to Pseudo-nitzschia. The failure may be explained rather by peculiarities in the cell wall composition (higher content of silica and fewer organic components) than by the specific (long and thin) shape of these cells. The pigment content in all of the studied species tended to decrease after thawing as compared with unfrozen cells and increase significantly during cell recovery. Cryosensitivity of marine algae depended on the differences in natural intrinsic characteristics rather than their taxonomic position.     

Preservation of polymorphonuclear neutrophils at cryogenic temperatures (−80 °C)

The effects of cryoprotectant alone and cryoprotectant plus additives on the preservation of polymorphonuclear neutrophils (PMNs) at cryogenic temperatures (?80 °C) were studied.A considerable difference among cryoprotective agents was observed in their protective effect against freeze injury of neutrophils. Based upon degree of chemotactic inhibition and impairment of trypan blue exclusion, Me₂SO proved to be superior to ethylene glycol and glycerol as a cryoprotectant and to exhibit the best protective effect at a concentration of 4.2%. When PMNs were frozen in Me₂SO alone, the ability of PMNs to exclude dye was retained after 3 days of cryopreservation, while chemotaxis was inhibited markedly. One-week preservation produced the death of 50% of the cells. To improve the protective effect of Me₂SO against chemotactic inhibition by cryopreservation, additives such as glucose, ATP, and albumin were included in the freezing medium. Addition of albumin displayed the most distinct improvement in the recovery of chemotaxis, although ATP also exhibited a protective effect, especially during short-term storage. Studies on the combined effect of these additives with ethylene glycol or glycerol showed that only albumin had a considerably better protective effect against dye exclusion injury but not against chemotactic inhibition. Phagocytosis and adhesion were less inhibited by freezing than was chemotaxis. A combination of Me₂SO and ATP markedly protected phagocytosis and adhesion from freeze injury. However, cyanide-insensitive oxygen uptake during phagocytosis, as well as chemotaxis, were considerably inhibited.     

In situ cryopreservation of human embryonic stem cells in gas-permeable membrane culture cassettes for high post-thaw yield and good manufacturing practice

Current strategies for marine pollution monitoring are based on the integration of chemical and biological techniques. The sea urchin embryo-larval bioassays are among the biological methods most widely used worldwide. Cryopreservation of early embryos of sea urchins could provide a useful tool to overcome one of the main limitations of such bioassays, the availability of high quality biological material all year round. The present study aimed to determine the suitability of several permeant (dimethyl sulfoxide, Me₂SO; propylene glycol, PG; and ethylene glycol, EG) and non-permeant (trehalose, TRE; polyvinylpyrrolidone, PVP) cryoprotectant agents (CPAs) and their combination, for the cryopreservation of eggs and embryos of the sea urchin Paracentrotus lividus. On the basis of the CPAs toxicity, PG and EG, in combination with PVP, seem to be most suitable for the cryopreservation of P. lividus eggs and embryos. Several freezing procedures were also assayed. The most successful freezing regime consisted on cooling from 4 to −12 °C at 1 °C/min, holding for 2 min for seeding, cooling to −20 °C at 0.5 °C/min, and then cooling to −35 °C at 1 °C/min. Maximum normal larvae percentages of 41.5% and 68.5%, and maximum larval growth values of 42.9% and 60.5%, were obtained for frozen fertilized eggs and frozen blastulae, respectively.     

First successful vitrification of salmonid ovarian tissue

Due to a lack of cryopreservation protocols for fish eggs and embryos, alternative techniques which will enable storage of female genetic resources are crucial for future development of reproduction management in conservation biology and aquaculture. Experiments were conducted to develop an optimal vitrification protocol for cryopreservation of brown trout Salmo trutta juvenile ovarian tissue. Needle immersed vitrification (NIV) method was used where ovaries were pinned on an acupuncture needle, passaged through equilibration and vitrification solutions containing different combinations and concentrations of methanol (MeOH), propylene glycol (PG) and dimethyl sulfoxide (Me₂SO) and subsequently plunged into liquid nitrogen. Vitrification solutions containing equal cryoprotectant concentrations (3M Me₂SO and 3M PG) yielded the highest oogonia survival rates (up to 40%) and qualitatively and quantitatively unaltered perinucleolar follicles. The method developed for brown trout could be applied to the conservation of female genetic resources of other salmonid species, including endangered and endemic species or populations.     

Cryopreservation of sperm from farmed Pacific abalone,Haliotis discus hannai

This study aimed to improve a sperm cryopreservation protocol for farmed Pacific abalone, Haliotis discus hannai. Dimethyl sulfoxide (Me₂SO), glycerol, ethylene glycol (EG), propylene glycol (PG), and methanol were chosen as cryoprotectants (CPAs). Four different equilibration time (5, 10, 30, and 60 min), and two types of equilibration temperature (4 °C and 20 °C) were selected at the present experiment. Most equilibration temperatures with each CPA showed significant differences among different equilibration time. Post-thaw sperm motility of five CPAs showed no significant difference at two equilibration temperature. Based on these results, 8% Me₂SO, 8% EG, 6% PG, 2% glycerol, and 2% methanol were chosen to determine optimal conditions for sperm cryopreservation of H. discus hannai. The highest post-thaw sperm motility (8% Me₂SO: 50.6%, 8% EG: 45.6%, 2% glycerol: 44.5%, 6% PG: 28.7%, 2% methanol: 25.4%) was achieved after exposing sperm to liquid nitrogen (LN₂) vapor for 10 min at 5 cm above the LN₂ surface and then submerging them in LN₂ for at least 2 h followed by thawing at 60 °C with seawater and recovering them at 20 °C with seawater. In this study, 8% Me₂SO and 2% glycerol were chosen to check post-thaw sperm quality to estimate percentages of plasma membrane integrity (PMI), mitochondrial potential analysis (MP), and acrosome integrity (AI) using fluorescent techniques. No significant difference in PMI, MP, and AI was found between sperm cryopreserved with 8% Me₂SO and those cryopreserved with 2% glycerol. The current study has demonstrated that 8% Me₂SO was optimal for sperm cryopreservation for H. discus hannai with 5 min of equilibration time, 5 cm of rack height and 60 °C of thawing temperature. The present research provides more effective cryopreservation methods for H. discus hannai sperm than previous studies.     

Characterization of cryobiological responses in TF-1 cells using interrupted freezing procedures

Cryopreservation currently is the only method for long-term preservation of cellular viability and function for uses in cellular therapies. Characterizing the cryobiological response of a cell type is essential in the approach to designing and optimizing cryopreservation protocols. For cells used in therapies, there is significant interest in designing cryopreservation protocols that do not rely on dimethyl sulfoxide (Me₂SO) as a cryoprotectant, since this cryoprotectant has been shown to have adverse effects on hematopoietic stem cell (HSC) transplant patients. This study characterized the cryobiological responses of the human erythroleukemic stem cell line TF-1, as a model for HSC. We measured the osmotic parameters of TF-1 cells, including the osmotically-inactive fraction, temperature-dependent membrane hydraulic conductivity and the membrane permeability to 1 M Me₂SO. A two-step freezing procedure (interrupted rapid cooling with hold time) and a graded freezing procedure (interrupted slow cooling without hold time) were used to characterize TF-1 cell recovery during various phases of the cooling process. One outcome of these experiments was high recovery of TF-1 cells cryopreserved in the absence of traditional cryoprotectants. The results of this study of the cryobiology of TF-1 cells will be critical for future understanding of the cryobiology of HSC, and to the design of cryopreservation protocols with specific design criteria for applications in cellular therapies.     

The effect of ice formation on the function of smooth muscle tissue stored at −21 or −60 °C

The mechanisms by which single cells are injured during freezing are relatively well understood, but it is likely that additional factors apply to tissues and organs, factors that may be responsible for the poor suecess of attempts to cryopreserve complex multicellular systems. One such factor may be the formation of extracellular ice.

This study was designed to discover whether ice formation as such is detrimental to the contractile recovery of pieces of mammalian smooth muscle after storage at subzero temperatures. Strips of taenia coli muscle were equilibrated with 2.56 M Me₂SO in a buffered solution, cooled at either 0.3 or 2 °C/min to ?21 °C and then held at this temperature in the frozen state. Other muscle strips were bathed in a solution the composition of which mimicked that of the unfrozen phase of the previous solution at ?21 °C; it contained 4.49 M Me₂SO and 1.75 times the normal concentration of salts, and muscles equilibrated with this solution were also cooled at either 0.3 or 2 °C/min to ?21 °C, and then held unfrozen for the same length of time.It was shown that exposure to ?21 °C and the increased concentration of solutes had little effect on the contractile recovery of the muscles, whereas ice formation was damaging. Furthermore, the rate of cooling had a marked effect upon functional recovery in the frozen muscles, and this could be correlated with the known effect of these cooling rates on the pattern of ice formation in the tissue. The effect was also seen in muscles frozen at ?60 °C. Improved buffering increased the functional recovery of all groups, but the effect of ice, and of cooling rate in the presence of ice, was confirmed. These findings may have significant implications for attempts to cryopreserve complex tissues and organs.     

Cell membrane permeability coefficients determined by single-step osmotic shift are not applicable for optimization of multi-step addition of cryoprotective agents: As revealed by HepG2 cells

HepG2 cells have a number of research applications and cryopreservation of these cells would improve supply and thus facilitate the study. Development of effective cryopreservation protocols relies on knowledges of the fundamental mass transport characteristics of HepG2 cell membrane. Currently, the permeability parameters estimated from single-step addition are routinely used to predict the osmotic responses of the cells in multistep protocols, as well as used for prediction of optimal cooling rates. However, the reasonability of this approach has not been rigorously studied. Here we measured the hydraulic conductivity (L_p) and the permeability coefficient (P_s) of HepG2 cells in the absence/presence of dimethyl sulfoxide (Me₂SO) at various temperatures with single and multistep addition of Me₂SO. We found that the permeability yielded via one-step addition of the Me₂SO cannot exactly predict the volume change of the cells when the CPA was added in multiple steps.     

Analysis of “solution effects” injury: Rabbit renal cortex frozen in the presence of dimethyl sulfoxide

Slices of rabbit renal cortex were frozen in 0.64 or 1.92 M dimethyl sulfoxide (Me₂SO) to various subzero temperatures, thawed, and assayed for viability. Salt and Me₂SO concentrations were calculated and correlated with the injury taking place during freezing. In separate experiments, slices were treated with NaCl or Me₂SO in concentrations sufficient to simulate the exposure brought about as a result of freezing. The effects of these treatments on cortical viability were compared with the results of freezing to equivalent concentrations of either NaCl or Me₂SO. The results show that whereas slices will tolerate exposure to at least six times the isotonic concentration of NaCl at 0 °C, they are unable to tolerate even three times the isotonic salt concentration when frozen in 1.92 M Me₂SO. They can, however, tolerate 3 × NaCl when frozen in 0.64 M Me₂SO. Freezing damage did not depend upon the amount of ice formed per se, since slices frozen in the low concentration of Me₂SO tolerated removal of about 75% of the initial fluid content of the system, whereas slices frozen in 1.92 M Me₂SO did not tolerate an identical removal of unfrozen solution. It was found that treatment of slices with high concentrations of Me₂SO at subzero temperatures in accordance with Elford's application (14) of Farrant's method (20) produced damage which correlated approximately with the damage observed when the same concentrations of Me₂SO were produced by freezing. It is concluded that most of the damage caused by freezing in 1.92 M Me₂SO is produced either directly or indirectly by Me₂SO. Possible mechanisms for this injury are discussed.