Osmotic properties of the rabbit corneal endothelium and their relevance to cryopreservation

The process of cryopreservation subjects cells to gross changes in the composition of the solution that surrounds them, changes that cause the cells first to shrink and then to swell by an osmotic mechanism. Empirical methods have been developed that permit many cells to survive freezing and thawing, but the cornea, which is crucially dependent upon the function of its endothelial monolayer, has proved quite refractory. In this paper we explore the osmotic response of the corneal endothelium of the rabbit to solutions ranging in osmolality from 0.25 to 8.6 X isotonic. Boyle van't Hoff behavior was observed between 0.43 and 8.6 X isotonic, and there was an apparent nonosmotic volume of 33.6%. However, ultrastructural damage was observed at the limits of this range, and it appeared that the tolerated range was 0.64-4.4 X isotonic. We show the extent to which dimethyl sulfoxide (Me2SO) would be expected to moderate changes in volume during freezing and suggest that its initial concentration should be at least 2M to prevent excessive shrinkage. We also show that cell swelling during removal of Me2SO is especially likely to be hazardous.     

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.     

Cryopreservation of adipose-derived stromal/stem cells using 1–2% Me2SO (DMSO) in combination with pentaisomaltose: An effective and less toxic alternative to comparable freezing media

Mesenchymal stromal/stem cells (MSCs) derived from bone marrow, umbilical cord and especially adipose tissue are increasingly being explored for their therapeutic potential to treat a wide variety of diseases. A prerequisite for most allogeneic off-the-shelf and some autologous MSC therapies is the ability to safely and efficiently cryopreserve cells during production or for storage prior to treatment. Dimethyl sulfoxide (Me₂SO) is still the commonly used gold standard cryoprotectant (CPA). However, undesirable cellular impacts and side effects of Me₂SO have led to an increasing demand for the development of safe and effective alternatives.This study investigated the effect of pentaisomaltose as a CPA for cryopreservation of adipose-derived stromal/stem cells (ASCs). We compared pentaisomaltose-based freezing media containing 1% Me₂SO (PIM1) or 2% Me₂SO (PIM2) to our in-house freezing media formulation containing 10% Me₂SO (STD10) and to CryoStor freezing media containing 2% or 10% Me₂SO (CS2 and CS10). We assessed the recovery of viable ASCs, their phenotype, differentiation potential, proliferation potential, and migratory potential. Further, their immunomodulatory potential was assessed by measuring their ability to suppress T cell proliferation and express immunomodulatory markers.The results showed that the post-thaw viability of ASCs cryopreserved with STD10, CS10 and PIM2 was improved compared to that of CS2. The recovery of ASCs with PIM1 and PIM2 was also improved compared to that of CS2. Proliferation and migration were comparable among the tested freezing media. The results showed no difference in the induction of PDL1, PDL2 or IDO1 expression. Nevertheless, the potential of cryopreserved ASCs to suppress T cell proliferation was reduced when the Me₂SO concentration was reduced (CS10>STD10>CS2 and PIM2>PIM1).Altogether, the migratory and immunomodulatory potential combined with improved recovery indicate that the addition of pentaisomaltose in the freezing media may allow for the reduction of the Me₂SO concentration to 2% while retaining a more potent cell product that what is recovered using comparable freezing media. With the desire to reduce the amount of Me₂SO, these results suggest that 2% and potentially even 1% Me₂SO in combination with 10% pentaisomaltose could be an effective and less toxic alternative to comparable freezing media.     

Effect of trehalose as an additive to dimethyl sulfoxide solutions on ice formation,cellular viability,and metabolism

Cryopreservation is the only established method for long-term preservation of cells and cellular material. This technique involves preservation of cells and cellular components in the presence of cryoprotective agents (CPAs) at liquid nitrogen temperatures (−196 °C). The organic solvent dimethyl sulfoxide (Me₂SO) is one of the most commonly utilized CPAs and has been used with various levels of success depending on the type of cells. In recent years, to improve cryogenic outcomes, the non-reducing disaccharide trehalose has been used as an additive to Me₂SO-based freezing solutions. Trehalose is a naturally occurring non-toxic compound found in bacteria, fungi, plants, and invertebrates which has been shown to provide cellular protection during water-limited states. The mechanism by which trehalose improves cryopreservation outcomes remains not fully understood. Raman microspectroscopy is a powerful tool to provide valuable insight into the nature of interactions among water, trehalose, and Me₂SO during cryopreservation. We found that the addition of trehalose to Me₂SO based CPA solutions dramatically reduces the area per ice crystals while increasing the number of ice crystals formed when cooled to −40 or −80 °C. Differences in ice-formation patterns were found to have a direct impact on cellular viability. Despite the osmotic stress caused by addition of 100 mM trehalose, improvement in cellular viability was observed. However, the substantial increase in osmotic pressure caused by trehalose concentrations above 100 mM may offset the beneficial effects of changing the morphology of the ice crystals achieved by addition of this sugar.     

Volatile Flavor Components of ZINGIBERIS RHIZOMA (Zingiber officinale Roscoe)

The toxicity of dimethyl sulfoxide (Me₂SO) was examined in HeLa cells cultured at 37°C for up to 72 hr. The growth of the cells was measured by a colorimetric method with the use of 3-(4, 5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), which gave good correlation between the cell number and the color development from the reduction of MTT under suitable conditions. When the initial number of cells was 3 × 10⁴/ml, Me₂SO at 1% or less had no apparent effect on prolifiration for up to 48 hr of incubation, but in longer incubations, cell growth was repressed. When the initial number of cells was 3 × 10⁵/ml, the effect of Me₂SO was similar.     

Cryopreservation of some useful microalgae species for biotechnological exploitation

Culture collections of microalgae represent a biological resource for scientific research and biotechnological applications. When compared to the current methods of maintenance and sub-culturing, cryopreservation minimizes labor costs and is an effective method for maintaining a large range of species over long periods with high stability. In order to determine the best cryopreservation method for microalgae species with great biotechnological potential, three freezing protocols were employed using different cryoprotectants (dimethyl sulfoxide—Me₂SO; methanol—MeOH). Three marine microalgae species (Thalassiosira weissflogii; Nannochloropsis oculata, and Skeletonema sp.) were cooled by directly plunging into liquid nitrogen (?196°C) and with two-step controlled cooling protocols (?18°C and ?80°C pre-treatments). After storage periods ranging from 10 to 120 days, viability was determined by the ability of cells to actively grow again. Results obtained for T. weissflogii showed that this species could be preserved at ultra-low temperature (?196°C) for 10 and 30 days with 10?% Me₂SO and 5?% MeOH when employed a controlled cooling protocol (?80°C). N. oculata was successfully cryopreserved either by direct freezing or with controlled cooling protocols. N. oculata samples presented good responses when treated with 5?% Me₂SO, 10?% Me₂SO, 5?% MeOH and even without any cryoprotectant. Skeletonema sp. did not survive cryopreservation in any of the tested conditions. The results indicate the difficulty in establishing common protocols for different microalgae species, being necessary further studies for a better understanding of cell damages during freezing and thawing conditions for each species.     

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.     

Osmotic response of mammalian cells: Effects of permeating cryoprotectants on nonsolvent volume

The nonsolvent volume, b, of a cell permits calculation of cell water volume from measurements of total cell volume, and, consequently, it is used extensively in the determination of membrane permeability coefficients for water and solutes and also in simulations of water and solute fluxes during freezing of cells. The nonsolvent volume is most commonly determined from the ordinate intercept of plots of cell volume as a function of the reciprocal of extracellular nonpermeating solute concentration (so-called Boyle-van't Hoff plots). Once derived, b is often assumed to be constant even under conditions that may differ markedly from those under which it was determined. Our aim was to investigate whether this assumption was valid when cells were exposed to the cryoprotectants glycerol, dimethyl sulphoxide (Me₂SO), or propane-1,2-diol. Rabbit corneal keratocytes, a fibroblastic cell type, were exposed to 10% (v/v) cryoprotectant for 30 min at 22°C in solutions containing a range of nonpermeating solute concentrations. Cell volumes were determined by an electronic particle sizer and mode volume plotted as an inverse function of the concentration of nonpermeating solute. The cells behaved as osmometers under all conditions studied, but we found no evidence to suggest that the nonsolvent volume of cells was altered by Me₂SO or propane-1,2-diol. Glycerol, however, reduced the slope of the Boyle-van't Hoff plot, but this could be ascribed to the failure of the cells to equilibrate fully with the glycerol over the 30 min exposure time; thus, b was unaffected by glycerol. It may be assumed, therefore, that the nonsolvent volume was not influenced by the presence inside cells of any of these nonelectrolyte cryoprotectants. © 1996 Wiley-Liss, Inc.     

Investigating cryoinjury using simulations and experiments. 1: TF-1 cells during two-step freezing (rapid cooling interrupted with a hold time)

There is significant interest in designing a cryopreservation protocol for hematopoietic stem cells (HSC) which does not rely on dimethyl sulfoxide (Me₂SO) as a cryoprotectant. Computer simulations that describe cellular osmotic responses during cooling and warming can be used to optimize the viability of cryopreserved HSC; however, a better understanding of cellular osmotic parameters is required for these simulations. As a model for HSC, the erythroleukemic human cell line TF-1 was used in this study. Simulations, based on the osmotic properties of TF-1 cells and on the solution properties of the intra- and extracellular compartments, were used to interpret cryoinjury associated with a two-step cryopreservation protocol. Calculated intracellular supercooling was used as an indicator of cryoinjury related to intracellular ice formation. Simulations were applied to the two-step cooling protocol (rapid cooling interrupted with a hold time) for TF-1 cells in the absence of Me₂SO or other cryoprotectants and optimized by minimizing the indicator of cryoinjury. A comparison of simulations and experimental measurements of membrane integrity supports the concept that, for two-step cooling, increasing intracellular supercooling is the primary contributor to potential freezing injury due to the increase in the likelihood of intracellular ice formation. By calculating intracellular supercooling for each step separately and comparing these calculations with cell recovery data, it was demonstrated that it is not optimal simply to limit overall supercooling during two-step freezing procedures. More aptly, appropriate limitations of supercooling differ from the first step to the second step. This study also demonstrates why high cell recovery after cryopreservation could be achieved in the absence of traditional cryoprotectants.     

Effects of cryoprotective agents and freezing on abdominal ganglia of aplysia.

Isolated Aplysia depilans abdominal ganglia were exposed to 10 and 20% dimethylsulphoxide (Me₂SO) or glycerol at room temperature. Results indicate that Me₂SO induced an irreversible depression of extracellularly recorded ganglionic spontaneous spike generation while glycerol proved to be non-toxic. Intracellular recordings of individual nerve cell spontaneous activity during exposure to the cryoprotective agents were obtained in a few preliminary experiments. Both Me₂SO and glycerol induced a decrement in the nerve cell membrane potential. The main difference between the action of the two cryoprotectants was in the rate and the amount of depolarization, both being higher in the case of Me₂SO exposure.The Aplysia abdominal ganglia were frozen to ?20 °C and to ?196 °C. In all but one ganglia frozen to ?20 °C, including the preparations frozen in the absence of any cryoprotective agent, functional recovery was obtained after thawing. However, only the application of 20% glycerol improved the recovery of the preparations to a significant extent. In ganglia protected with 20% glycerol a full recovery of the action potential amplitude and frequency was obtained. In ganglia protected with 20% glycerol intracellular recordings of individual nerve cells demonstrated spontaneous spike activities before freezing and after thawing.No functional recovery was observed in ganglia frozen to ?196 °C in the absence of a cryoprotective agent. While in most preparations frozen with a cryoprotectant spontaneously generated spikes were recorded after thawing. However, the action potential frequency and amplitude were significantly depressed. It is concluded that further investigation is required to improve the freezing technique so that Aplysia ganglia may be preserved at low temperatures. It is suggested that intracellular exploration of the effects of cryoprotectants and freezing on identified nerve cell membrane may prove to be useful in future investigations.     

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 amniotic fluid-derived stem cells using natural cryoprotectants and low concentrations of dimethylsulfoxide

Amniotic fluid-derived stem cells (AFSCs) are a potential cell source for therapeutic applications. They can be easily mass produced, cryopreserved and shipped to clinics for immediate use. However, one major obstacle to the manufacturing of clinical grade stem cells is the need for current good manufacturing practices for cryopreservation, storage, and distribution of these cells. Most current cryopreservation methods used for stem cells include the potentially toxic cryoprotectant (CPA) dimethylsulfoxide (Me₂SO) in the presence of animal serum proteins that prevent direct use of these cells in human therapeutic applications. To avoid any potential cryoprotectant related complications, it will be essential to develop non-toxic CPAs or reduce CPA concentration in the freezing media used. In this study, we assessed the use of disaccharides, antioxidants and caspase inhibitors for cryopreservation of AFSCs in combination with a reduced concentration of Me₂SO. The thawed cells were tested for viability with MTT assays and a growth curve was created to measure population doubling time. In addition, we performed flow cytometry analysis for cell surface antigens, RT-PCR for mRNA expression of stem cell markers, and assays to determine the myogenic differentiation potential of the cells. A statistically significant (p < 0.05) increase in post-thawed cell viability in solutions containing trehalose, catalase and _ZVAD-fmk with 5% Me₂SO was observed. The solutions containing trehalose and catalase with 5% or 2.5% (v/v) Me₂SO produced results similar to those for the control (10% (v/v) Me₂SO and 30% FBS) in terms of culture growth, expression of cell surface antigens and mRNA expression of stem cell markers in AFSCs cryopreserved for a minimum of 3 weeks. Thus, AFSCs can be cryopreserved with 1/4 the standard Me₂SO concentration with the addition of disaccharides, antioxidants and caspase inhibitors. The use of Me₂SO at low concentrations in cell freezing solutions may support the development of clinical trials of AFSCs.     

Cryopreservation of granulocytes for transfusion: Studies on human granulocyte isolation,the effect of glycerol on lysosomes,kinetics of glycerol uptake and cryopreservation with dimethyl sulfoxide and glycerol

Existing methods for the cryopreservation of granulocytes employ primarily dimethyl sulfoxide (Me₂SO) rather than glycerol as the cryoprotective additive of choice. Although Me₂SO has been demonstrated to be an effective cryoprotective additive for granulocyte preservation to yield viable cells (dye exclusion, phagocytosis, etc.), the inherent toxicity and clinical objections of Me₂SO as a cryoprotective additive for granulocyte preservation preclude its extensive and routine use in patients. Therefore, glycerol, with its important advantage of nontoxicity, has been investigated for its potential usefulness as a cryoprotective additive for preserving human granulocytes for transfusion.Granulocyte preparations were isolated from impure leukocyte concentrates obtained from the buffy coats of human whole blood. Studies on the isolation and purification of the granulocytes involved separation by sedimentation with dextran, removal of red cells by hypotonic shock with water, resuspension with Plasmatein and further purification by centrifugation. Intact viable granulocytes were obtained with a purity in excess of 90%.Lysosomes were studied as indicators of cryoinjury in granulocytes using β-glucuronidase as the key marker enzyme. This enzyme has been characterized as a sensitive indicator of damage to lysosomes and a direct linear relationship has been established between damage to granulocytes by freezing and amount of lysosomal enzyme released. Addition or presence of the cryoprotectant, glycerol, did not appear to have any adverse effect on lysosomes of intact granulocytes.Studies on the permeation kinetics of glycerol in granulocytes indicated that the additive was freely permeable and did not cause any potentially damaging osmotic changes in cell volume. Granulocytes in various concentrations of glycerol were then frozen at slow, moderate, and rapid cooling rates. Based on the small amount of β-glucuronidase released, good preservation of granulocyte lysosomes has been obtained with a slow cooling rate of 5 °C/min and a concentration of 15% glycerol. Further studies now are necessary to define those conditions of cooling rate and glycerol concentration required to develop a simple method for optimal preservation of granulocytes based on additional functional criteria of viability.     

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.     

Algae Permeability to Me2SO from −3 to 23°C

Biphasic transport of water and dimethyl sulfoxide (Me₂SO), a common cryoprotective agent (CPA), in algal cells was induced and measured on a cryoperfusion stage. A two-step experimental protocol provided data for the volumetric response of Chlorococcum (C.) texanum to impermeable and permeable solutes. First, the cells were exposed to a 500-mOsm sucrose solution, causing immediate shrinkage of the cell to a minimum equilibrium volume. Then an isoosmotic 200-mOsm/300-mOsm CPA/sucrose solution was introduced to the cells, resulting in increased cell volume to a new equilibrium state. Experiments were conducted at temperatures between −3 and 23°C. Cell volumes were measured off-line by computer analysis of video images. A network thermodynamic model was fit to the transient volume data to determine permeabilities of C. texanum to water and Me₂SO over the full temperature range, and results were calculated with two numeric methods. Biphasic transport was found to be slower at colder temperatures, with water entering the cell faster than Me₂SO. Experimental results were also compared with data from similar experiments using methanol (MeOH) as the CPA. MeOH influx was calculated to be a magnitude larger than that of water. Additionally, MeOH permeability was at least three orders of magnitude greater than Me₂SO permeability, and the difference in these solute permeabilities increased as temperature decreased.     

Development of a microfluidic device for determination of cell osmotic behavior and membrane transport properties

An understanding of cell osmotic behavior and membrane transport properties is indispensable for cryobiology research and development of cell-type-specific, optimal cryopreservation conditions. A microfluidic perfusion system is developed here to measure the kinetic changes of cell volume under various extracellular conditions, in order to determine cell osmotic behavior and membrane transport properties. The system is fabricated using soft lithography and is comprised of microfluidic channels and a perfusion chamber for trapping cells. During experiments, rat basophilic leukemia (RBL-1 line) cells were injected into the inlet of the device, allowed to flow downstream, and were trapped within a perfusion chamber. The fluid continues to flow to the outlet due to suction produced by a Hamilton Syringe. Two sets of experiments have been performed: the cells were perfused by (1) hypertonic solutions with different concentrations of non-permeating solutes and (2) solutions containing a permeating cryoprotective agent (CPA), dimethylsulfoxide (Me₂SO), plus non-permeating solute (sodium chloride (NaCl)), respectively. From experiment (1), cell osmotically inactive volume (V_b) and the permeability coefficient of water (L_p) for RBL cells are determined to be 41% [n = 18, correlation coefficient (r²) of 0.903] of original/isotonic volume, and 0.32 ± 0.05 μm/min/atm (n = 8, r² > 0.963), respectively, for room temperature (22 °C). From experiment (2), the permeability coefficient of water (L_p) and of Me₂SO (P_s) for RBL cells are 0.38 ± 0.09 μm/min/atm and (0.49 ± 0.13) × 10⁻³ cm/min (n = 5, r² > 0.86), respectively. We conclude that this device enables us to: (1) readily monitor the changes of extracellular conditions by perfusing single or a group of cells with prepared media; (2) confine cells (or a cell) within a monolayer chamber, which prevents imaging ambiguity, such as cells overlapping or moving out of the focus plane; (3) study individual cell osmotic response and determine cell membrane transport properties; and (4) reduce labor requirements for its disposability and ensure low manufacturing costs.     

Permeability of the 17-day fetal rat pancreas to glycerol and dimethylsulfoxide

Experimentally induced diabetes in rats can be reversed by the transplantation of several fresh or frozen-thawed fetal pancreases. An important question to both the mechanistic and practical aspects of cryobiology is the role played by the permeation of protective additives during freezing, thawing, and subsequent dilution. Answers require knowledge of the kinetics of permeation of the specific additive into the cell or tissue. In this paper, we report isotopic measurements of the rate of permeation of 2 M glycerol and 1 and 2 M dimethylsulfoxide (Me₂SO) into 17-day fetal pancreases at 0 and 22 °C. In Me₂SO, equilibrium was achieved in about 10–15 min at 0 °C and in less than 10 min at 22 °C. In glycerol, equilibrium was attained in about 60 min at 22 °C; but at 0 °C permeation was only 65% complete after 180 min. In general, Me₂SO permeated 10–30 times more rapidly than glycerol at 0 °C, and glycerol permeated about 10 times more rapidly at 22 than at 0 °C.The kinetics of permeation were more characteristic of a two-compartment than a single-compartment system. In all probability, the two compartments are the intercellular space and the intracellular space. The permeability data suggest that each compartment occupies about half the total volume.     

Heart valve cryopreservation: protocol for addition of dimethyl sulphoxide and amelioration of putative amphotericin B toxicity

Aim

To investigate the need for stepwise addition of dimethyl sulphoxide to heart valves and amelioration of putative amphotericin B toxicity.

Methods

There were four groups: an untreated control (Group 1) and three experimental groups. For the latter, porcine heart valves were exposed to the antibiotic/antimycotic mixture used for disinfecting heart valves in the Bristol Heart Valve Bank, for 24 h at 22 °C. Dimethyl sulphoxide (Me₂SO, 10% v/v) was added either in two steps (5% then 10%) (Group 2) or in a single step. For single-step addition, valves were either first placed in Hanks’ balanced salt solution for 10 min before transfer to the cryoprotectant solution (Group 3) or immersed directly in the 10% cryoprotectant solution (Group 4). The valve leaflets were dissected from the valves and frozen in 10% Me₂SO in multi-well tissue culture plates at 1 °C/min to −80 °C. After storage overnight, the valve leaflets were warmed at approximately 11 °C/min and the cryoprotectant was removed by single-step dilution in excess Hartmann’s solution. Each leaflet was then divided into four pieces, which were placed in separate wells of a culture plate. Outgrowth of cells from the explants was monitored daily and graded according to the extent of cell growth.

Results

After freezing and thawing, only 77% of the explants from valves placed directly into 10% Me₂SO (Group 4) showed outgrowth of cells after freezing compared with 89% with two-step addition of Me₂SO (Group 2) and 95% with one-step addition after the extra rinse in Hanks’ solution (Group 3) (χ², p = 0.001). 92% of unfrozen control explants showed outgrowth of cells (Group 1). Only 37% of Group 4 explants reached confluence compared with 63 and 56%, respectively, of Groups 2 and 3 explants (χ², p = 0.007). The rates of cell growth in Group 2 (two-step addition of Me₂SO) and Group 3 (one-step addition of Me₂SO with additional Hanks’ solution rinse) were similar and faster than the Group 4 (one-step addition of Me₂SO without the additional Hanks’ rinse).

Conclusion

Single-step addition of Me₂SO before freezing gave similar results to two-step addition provided an additional rinse in Hanks’ solution was introduced after exposure to the antibiotic/antimycotic mixture. This suggests that antibiotic/antimycotic carryover may have been harmful during freezing and that the additional rinse in Hanks before one-step addition of Me₂SO, and the 5% Me₂SO step in the two-step protocol, merely served to reduce this carryover.     

Cell volume changes in relation to the cell cycle of differentiating erythroleukemic cells

Murine erythroleukemic cells (MELC) were synchronized by sequential exposure to thymidine and hydroxyurea. Upon removal from hydroxyurea, cells cultured with or without agents that induce erythroid differentiation, such as hexamethylene bisacetamide (HMBA) or dimethylsulfoxide (Me₂SO), proceed through S, G2 and mitosis with the same kinetics: S phase averages 5 h and G2 plus mitosis, 2 h. Cells cultured with HMBA and Me₂SO remain in the subsequent G1 for 5–7 h, compared with an average of only 3 h for cells cultured without inducer. Modal cell volume doubles as the cells proceed from G1 to G2. During the inducer-mediated prolonged G1, MELC retain a small cell volume. In cultures of non-synchronous MELC, inducers also increase the G1 fraction, as well as the proportion of small cells. An Me₂SO-resistant MELC variant (DR10), cultured with Me₂SO, shows little prolongation of G1 and little difference in the modal cell volume compared with cells without inducer. However, HMBA, which induces differentiation of DR10 cells, prolongs G1 and increases the proportion of small cells. These studies indicate that early changes in cell volume associated with induction of MELC to differentiate, in large part reflect alterations in the cell cycle. Evidence is presented which suggests that only one round of DNA synthesis in the presence of inducer may be necessary to initiate differentiation.     

Optimization of cryoprotectant loading into murine and human oocytes

Loading of cryoprotectants into oocytes is an important step of the cryopreservation process, in which the cells are exposed to potentially damaging osmotic stresses and chemical toxicity. Thus, we investigated the use of physics-based mathematical optimization to guide design of cryoprotectant loading methods for mouse and human oocytes. We first examined loading of 1.5 M dimethyl sulfoxide (Me₂SO) into mouse oocytes at 23 °C. Conventional one-step loading resulted in rates of fertilization (34%) and embryonic development (60%) that were significantly lower than those of untreated controls (95% and 94%, respectively). In contrast, the mathematically optimized two-step method yielded much higher rates of fertilization (85%) and development (87%). To examine the causes for oocyte damage, we performed experiments to separate the effects of cell shrinkage and Me₂SO exposure time, revealing that neither shrinkage nor Me₂SO exposure single-handedly impairs the fertilization and development rates. Thus, damage during one-step Me₂SO addition appears to result from interactions between the effects of Me₂SO toxicity and osmotic stress. We also investigated Me₂SO loading into mouse oocytes at 30 °C. At this temperature, fertilization rates were again lower after one-step loading (8%) in comparison to mathematically optimized two-step loading (86%) and untreated controls (96%). Furthermore, our computer algorithm generated an effective strategy for reducing Me₂SO exposure time, using hypotonic diluents for cryoprotectant solutions. With this technique, 1.5 M Me₂SO was successfully loaded in only 2.5 min, with 92% fertilizability. Based on these promising results, we propose new methods to load cryoprotectants into human oocytes, designed using our mathematical optimization approach.