Cooling of embryonic cells,isolated blastoderms,and intact embryos of the zebra fish Brachydanio rerio to −196 °c

Single cells from the developing embryo of the zebra fish survive freezing when protected with 1 M DMSO and cooled to ?196 °C in two steps. Cell survival drops from 85 to 26% when clumps of 5–10 cells are similarly frozen, and to 2% when isolated blastoderms are treated in the same way. This drastic decrease in survival is interpreted as an example of the “scale-up problem,” in which diffusional barriers prevent cryoprotectant equilibration and osmotic dehydration in large cell assemblanges.Isolated blastoderms develop considerably in culture, and retain some of this ability following cooling to ?25 °C after protection with DMSO or glycerol.Intact embryos protected with high concentrations of glycerol (2.8 M) tolerate slow cooling to ?196 °C surprisingly well, with most of the embryonic cells morphologically intact and actively extruding lobopodia. Glycerol could, however, only be removed from cells by disrupting the embryo so that diffusional barriers were removed. DMSO (2.8 M) was ineffective in preserving embryos or cells cooled to ?196 °C.     

Ultrastructure before freezing,while frozen,and after thawing in assessing cryoinjury of mouse epididymal spermatozoa

Tails of mouse epididymides were treated as follows: control, unfrozen with and without cryoprotective agents (CPA); frozen (to below ?80 °C), slowly (8 °C/min), and rapidly (18 °C/sec), with and without CPA. Intracellular and/or extracellular location of CPA, at least glycerol, was influenced, respectively, by high (22 °C) or low (0 °C) exposure temperature. Standard procedures in electron microscopy were employed and the frozen state preserved by freeze-substitution. Motility before freezing and after thawing was the criterion of cryosurvival.Results showed no evidence of deleterious ultrastructural effects of freezing at rates compared, or of benefits of CPA, regardless of their cellular location. Differences were noted, however, in the appearance of spermatozoa in the frozen state, as a function of the rate of freezing but not as a function of the presence, absence, or location of either glycerol of DMSO. Rapidly frozen cells showed intracellular ice formation in the acrosome, neck, midpiece, and tail regions; there was no intranuclear ice, and extracellular ice artifacts were small. Slowly frozen cells showed large extracellular ice artifacts with evidence of shrinkage distortion due to the dehydration induced by extracellular ice. No spermatozoa survived any of the freezing treatments, showing the lethal effect of both extracellular ice during slow freezing and of intracellular and/or extracellular ice during rapid freezing.     

Cryoprotectant removal temperature as a factor in the survival of frozen rice and sugarcane cells

Removal of cryoprotective additives through use of a room temperature (22 °C) washing step, instead of 0 °C, was found to improve the recovery of sugarcane suspension culture and rice callus tissues. Cultured cells were cryoprotected by gradual addition of a mixture of polyethylene glycol, glucose, and DMSO (PGD) to a final concentration of 10%-8%-10%, w/v, respectively, added at either 0 or 22 °C. After a programmed slow freezing of the cells, they were thawed rapidly and the cryoprotectants were gradually diluted and washed out using a 22 or 0 °C washing medium. Viability of suspension cultured sugarcane cells protected with PGD was greatly diminished when a cold washing solution was used, whether the cells had been frozen (?23 °C) or not. Two mutant lines of rice callus when frozen to ?196 °C in PGD and thawed showed less growth than unfrozen cells, but their growth was improved by washing the thawed cells with a 22 °C solution. With all cultures tested, the addition of PGD at 0 °C and post-thaw washing out at 22 °C gave improved survival. Particularly with the rice lines, optimizing the addition and washing procedures allowed culture survival of liquid nitrogen freezing not otherwise attained.     

The effect of glycerol concentration and cooling velocity on cryosurvival of ram spermatozoa frozen in straws

The effect of varying the concentration of glycerol from 0 to 16% on the survival of ram spermatozoa frozen at increasing rates of cooling (1–100 °C/min) or by direct plunging of spermatozoa in 0.5-ml straws in liquid nitrogen was studied after thawing at a constant rate (in water at 39 °C for 30 sec). For each glycerol concentration, the ram spermatozoa tolerated a range of cooling velocities and the best survival rates (percentage motility and rating) were obtained when the glycerol concentration was 4 or 6% and when the rate of freezing ranged from 10 to 100 °C/min. No spermatozoa survived in any glycerol concentration following freezing in straws plunged into liquid nitrogen. In general, the range of cooling rates shifts to lower values as the glycerol concentration increases for optimum cryosurvival. However, the toxic effect of increasing the concentration of glycerol over 8% contributes greatly to the gradual decrease in cryosurvival of spermatozoa at these particular concentrations.     

PVP contrasted with dextran and a multifactor theory of cryoprotection

Washed human erythrocytes were suspended in 0, 5, 10, 15, and 20% PVP in phosphate-buffered saline (PBS). Fifty lambda samples were frozen in alcohol baths at temperatures ranging from ?10 ° to ?80 °C. The specimens were frozen either for 1 or 16 min, rapidly thawed, and resuspended in PBS or PBS plus PVP. Percent hemolysis was determined colorimetrically. Results indicate that there is a high degree of latent damage when red cells are frozen in the presence of PVP. This damage is evident from the large increase in hemolysis when freeze-thawed, intact red cells are resuspended in the PBS. Under some circumstances 16 min freezing is significantly less damaging than 1 min freezing. This indicates a partial recovery from the freezing stress during subzero storage of the red cells.The general cryoprotective properties of PVP were described in terms of: (1) latent damage; (2) storage damage; (3) optimal cooling and rewarming rates (as a function of freezing bath temperature); (4) optimum PVP concentration; and (5) post-thaw cryoprotection. The data were compared with that from a similar study using dextran-40. This comparison indicated six similarities and ten differences in the cryoprotective properties of dextran and PVP. The remarkable differences between dextran and PVP was counted as an important common characteristics of macromolecular cryoprotective agents. That is, their cryoproteetive properties cannot be reduced to one or a few physical characteristics held in common. Nine other common characteristics were listed. Several of these, which include latent damage and recovery from latent damage, cannot be explained by current theories of cryoprotection. A multifactor theory was proposed to account for these ten common features of macromolecular cryoprotective agents.     

Recovery of a marine dinoflagellate following controlled and uncontrolled freezing

A free-living, marine dinoflagellate, Crypthecodinium cohnii, was successfully preserved by controlled and uncontrolled freezing. Tolerance testing to various concentrations of dimethylsulfoxide (DMSO) and glycerol established that 7.5% glycerol was the best cryoprotectant. Controlled freezing was accomplished by using a biological freezer to obtain a 1 °C/min cooling rate. After storage for a minimum of 7 days at ?150 °C material frozen by this method demonstrated a 47.7% mean recovery, and cells were viable through five subcultures. Uncontrolled freezing resulted from placing the ampoules on the bottom of a low temperature refrigerator at ?55 °C for 1 hr. This material demonstrated a mean recovery of 30.8% with a much wider range. Cells were initially nonmotile following recovery, and in those recovered after uncontrolled freezing motility was further delayed. One strain was viable after 6 years of storage with a 68% recovery following controlled freezing.The lack of motility immediately following recovery leads to inaccuracies when determining the percentage of cells recovered. Dilution techniques have been used for nonmotile recovered cells, but this method has been unsuccessful in our laboratory. Delayed motility has been reported for other flagellates and work in our laboratory indicates that flagellar shearing may be the cause.     

Effect of cooling and rewarming rates on glycerolated human erythrocytes.

Human erythrocytes suspended in a sodium-free buffered salt solution containing glycerol in 1 m concentration (1 part of packed cells to 4 parts buffered salt solution) were frozen by slow, moderately rapid, or very rapid cooling to various subzero C temperatures. The frozen specimens, after a 5-min storage period at a given temperature, were thawed at low, moderately high, or very high rates. The hemolysis in the frozen and thawed samples was measured by a colorimetric determination of the hemoglobin released from the damaged cells. At ?10 °C, the highest freezing temperature employed, nearly 100% recovery of intact erythrocytes was obtained irrespective of the cooling and rewarming conditions. The extent of the hemolysis after exposure to lower freezing temperatures depended upon the cooling and rewarming conditions. Moderately rapid and very rapid freezing to, and thawing from temperatures below ?40 °C permitted significantly higher recoveries of intact cells than the other freezing/ thawing combinations. In the temperature range ?15 to ?30 °C the combination slow cooling and slow rewarming afforded maximum protection. Very rapid freezing/ slow thawing was the most damaging combination throughout the entire freezing range. The results were interpreted in part by a conventional two-factor analysis, lower cooling rates allowing concentrated salts to determine hemolysis, higher cooling rates destroying the cells by intracellular freezing. Apparent anomalies were explained in terms of a generalized “thermal/osmotic” shock according to which the erythrocytes were subject to greater hemolysis the higher the rates of cooling and/or warming.     

A simple method for the freeze-preservation of zoospores of the green macroalga Enteromorpha intestinalis

Settled zoospores of the green macroalga Enteromorpha intestinalis were subjected to several different freezing and storing treatments at both cryogenic and non-cryogenic temperatures after which their viability was assessed using a spore germination bioassay. Three different cooling rates were tested: slow cooling at –1°C min⁻¹ and –0.5°C min⁻¹ to end temperatures in the range –20°C to –40°C, and a two-step procedure whereby the spores were frozen to –30°C at a rate of –1°C min⁻¹ prior to immersion in liquid nitrogen at –196°C. Spore viability was also investigated using the cryoprotectants glycerol and dimethyl suphoxide (DMSO), a reduced saline medium and various storage times. In the majority of experiments, the use of a cryoprotectant during the freezing process significantly increased the viability of the spores, with DMSO affording slightly greater protection than glycerol. All treatments produced high viabilities (ranging from 75.3–100.0%) after 5-min storage at the different end temperatures. However, progressively longer storage up to 7 days generally resulted in a marked reduction in viability. This was with the exception of spores frozen in a reduced saline medium; a medium of 75% seawater and either 5 or 10% DMSO greatly increased spore viability, with values of > 40% recorded for spores stored at –20°C for up to 5 weeks. This revised version was published online in July 2006 with corrections to the Cover Date.     

A METHOD FOR THE CRYOCONSERVATION OF DUNALIELLA SALINA (CHLOROPHYCEAE): EFFECT OF GLYCEROL AND COLD ADAPTATION1

The unicellular green alga Dunaliella salina Teod. was frozen according to the following procedure: 3 days cold adaptation at 4°C, addition of 3.5 M glycerol as a cryoprotectant, slow cooling to –40°C, immersion in liquid nitrogen, and rapid thawing. The survival rate was higher when cells were grown, before freezing, in the presence of 2 M NaCl instead of 1 M NaCl (78 and 48% survival, respectively). This difference is probably due to the intracellular amount of glycerol, which increases with external NaCl concentration and, therefore, may enhance cell protection. Although cells grown in 4 M NaCl accumulated a large amount of glycerol in response to osmotic stress, they did not withstand freezing. The use of cryoprotectant was absolutely necessary for the cells to recover from storage at –196°C. Glycerol was used because it is naturally produced by Dunaliella salina and therefore is not toxic. Provided it was added slowly to avoid osmotic shock, 3.5 M glycerol gave better results than 1M glycerol (48 and 18% survival, respectively). Cold adaptation in the dark increased postthaw viability. Cells grown in 1 M or 2 M NaCl had a survival rate of 48 and 78%, respectively, when cold-adapted, against 10 and 42% when not cold-adapted. This adaptation could be due to the synthesis, at low temperature, of specific proteins because two bands (28–29 kDa) appeared when electrophoretically separated proteins from cold-adapted cells and control cells were compared. Also, it could be due to the degradation of starch that occurs in the dark and leads to glycerol accumulation. Our procedure has never been used to cryopreserve microalgae and could enhance reported survival rates.     

Evaluation of extenders and cryopreservatives for cooling and cryopreservation of spermatozoa from the western spotted skunk (Spilogale gracilis)

Experiments were conducted to develop a suitable protocol for cryopreservation of spotted skunk semen. Semen was collected by electroejaculation of captive male skunks (n = 16) from late January through late November. In the first experiment, fresh semen was diluted in either TEST (n = 10), TRIS (n = 9), or BF5F (n = 7) extenders and maintained at 4°C for 16 hr. Sperm motility in these extenders was not significantly different before cooling (P = 0.71), but samples diluted with BF5F exhibited significantly lower sperm motility than the other extenders at all time points after cooling (P < 0.05). In the second experiment, fresh semen was diluted in TEST containing either 3, 5, or 10% DMSO or 3, 5, or 10% glycerol as a cryopreservative. These samples were cooled to 4°C and frozen in 0.25 ml French straws on dry ice. Some samples containing 5% DMSO or 5% glycerol (n = 4), were also frozen on dry ice as pellets. Frozen samples were maintained in liquid nitrogen. Fresh samples had significantly greater sperm motility in dimethyl sulfoxide (DMSO) than in glycerol (P < 0.05), while frozen and thawed samples had the highest motility in 5 or 10% DMSO or 10% glycerol. Samples frozen in French straws had significantly greater sperm motility after freezing and thawing than those frozen by the pellet method (P < 0.05). Optimum cryoprotection was achieved with the TEST extender containing 5 or 10% DMSO, when used in conjunction with French straws. © 1992 Wiley-Liss, Inc.     

The effect of warming velocity on motility and acrosomal integrity of boar sperm as influenced by the rate of freezing and glycerol level

The effect of thawing velocities ranging from 10°C/min to 1.800°C/min on the motility and acrosomal integrity of boar spermatozoa frozen at 1°C/min (suboptimal), 5°C/min, and 30°C/min (optimal) rate was studied with the sperm suspended for freezing in diluent containing 2, 4, or 6% of glycerol (v/v). The influence of thawing on sperm survival depends on the rate at which the sperm had been frozen. In semen frozen at a suboptimal rate of 1°C/min, the percentage of motile sperm (FMP) initially fell to 3.5–4.0% when the thawing rose to 200°C/ min, but, with further increases in thawing rate, increased and reached peak values (10.3–11.0% FMP) after thawing at 1,800°C/min. The percentage of sperm with normal apical ridge (NAR) also increased moderately with thawing rate, but the degree of improvement decreased as the glycerol level was increased. In semen frozen at 1°C/min, acrosomal integrity (NAR) was best maintained in 2% glycerol, reaching 22.9% NAR after thawing at 1,800°C/min. In semen frozen at the optimal rate of 30°C/min, the increases in thawing rates above 200°C/min substantially improved motility. Motility was generally higher in semen protected by 4 or 6% glycerol, with the peak values of 44 or 46% FMP, respectively, after thawing at 1,200°C/min. The proportion of sperm with NAR also increased with thawing rate, but as in the case of suboptimally frozen sperm it was influenced negatively by the glycerol concentration. The peak value 53% NAR was recorded in semen protected by 2% glycerol, frozen at 30°C/min, and thawed at 1,200°C/min. In view of the inverse relationship between FMP and NAR, selection of optimal conditions from among the interacting variables, freezing rate, glycerol concentration, and thawing rate requires compromising between maximal FMP and maximal NAR. Accordingly, we have adopted as optimal a protocol with a thawing rate of 1,200°C/min, a freezing rate of 30°C/min and concentrations of 3% glycerol. © 1993 Wiley-Liss, Inc.     

Effects of glycerol additions on post-thaw fertility of frozen rainbow trout sperm, with an emphasis on interaction between extender and cryoprotectant

The study was conducted to evaluate the effects of different extenders, cryoprotectants and glycerol additions on the post‐thaw fertility and interactions between extenders and cryoprotectants during cryopreservation. Semen was collected by abdominal stripping from 30 adult male rainbow trout (Oncorhynchus mykiss Walbaum, 1792) and diluted with three different extenders (Erdahl–Graham, Lahnsteiner, glucose‐based) containing 15% DMA, 15% DMSO, 15% DMA + 1% glycerol and 15% DMSO + 1% glycerol at a ratio of 1 : 2. Diluted samples were frozen as 0.1 ml pellets directly on dry ice (solid CO₂, −79°C). Eggs were pooled from 10 females. Fertilization was applied in plastic dishes and 600 eggs were used in each fertilization trial. Pellets were thawed in their own extenders (30°C) at a ratio of 1 : 10. 0.3% NaCl was used for activating motility. Sperm–egg ratio was approximately 3 × 10⁶ sp per egg. Experimental success was determined as the percentage of eyed‐eggs 25 days after fertilization. The highest eyed‐egg rate (49.3%) was obtained from semen frozen with glucose‐based extender containing 15% DMSO + 1% glycerol. Our results indicate that the glucose‐based extender containing DMSO is a useful combination, but that the addition of glycerol does not have a positive effect on post‐thaw fertility, and that interaction of the extender‐cryoprotectant is also important in the cryopreservation of rainbow trout semen.     

Non-toxic freezing media to retain the stem cell reserves in adipose tissues

Subcutaneous adipose tissue is a rich source of stromal vascular fraction (SVF) and adipose-derived stromal/stem cells (ASCs) that are inherently multipotent and exhibit regenerative properties. In current practice, lipoaspirate specimens harvested from liposuction surgeries are routinely discarded as a biohazard waste due to a lack of simple, cost effective, and validated cryopreservation protocols. The aim of this study is to develop a xenoprotein-free cryoprotective agent cocktail that will allow for short-term (up to 6 months) preservation of lipoaspirate tissues suitable for fat grafting and/or stromal/stem cell isolation when stored at achievable temperatures (−20 °C or −80 °C). Lipoaspirates donated by three consenting healthy donors undergoing elective cosmetic liposuction surgeries were suspended in five freezing media (FM1: 10% DMSO and 35% BSA; FM2: 2% DMSO and 43% BSA; FM3: 10% DMSO and 35% lipoaspirate saline; FM4: 2% DMSO and 6% HSA; and FM5: 40% lipoaspirate saline and 10% PVP) all suspended in 1X DMEM/F12 and frozen using commercially available freezers (−20 °C or −80 °C) and stored at least for a 1 month. After 1 month of freezing storage, SVF cells and ASCs were isolated from the frozen-thawed lipoaspirates by digestion with collagenase type I. Cell viability was evaluated by fluorescence microscopy after staining with acridine orange and ethidium bromide. The SVF isolated from lipoaspirates frozen at −80 °C retained comparable cell viability with the tested freezing media (FM2, FM3, FM4) comparable with the conventional DMSO and animal serum media (FM1), whereas the FM5 media resulted in lower viability. In contrast, tissues frozen and stored at −20 °C did not yield live SVF cells after thawing and collagenase digestion. The surface marker expression (CD90, CD29, CD34, CD146, CD31, and CD45) of ASCs from frozen lipoaspirates at −80 °C in different cryoprotectant media were also evaluated and no significant differences were found between the groups. The adipogenic and osteogenic differentiation potential were studied by histochemical staining and gene expression by qRT-PCR. Oil Red O staining for adipogenesis revealed that the CPA media FM1, FM4 and FM5 displayed robust differentiation. Alizarin Red S staining for osteogenesis revealed that FM1 and FM4 media displayed superior differentiation in comparison to other tested media. Measurement of adipogenic and osteogenic gene expression by qRT-PCR provided similar outcomes and indicated that FM4 CPA media comparable with FM1 for adipogenesis and osteogenesis.     

Cryopreservation of the promastigote form of Leishmania tropica var major at different cooling rates

Callow L. L. and Farrant J. 1973. Cryopreservation of the promastigote form of Leishmania tropica var major at different cooling rates. International Journal for Parasitology, 3: 77–88. An investigation of the optimal conditions for the preservation of Leishmania tropica var major by freezing was undertaken because it was important to obtain a high yield when the thawed organisms were cultured. As a prerequisite for comparing different conditions, assay methods were devised. One method was based on the reduced growth of promastigotes in diphasic medium that was found to follow inoculation of relatively few organisms. The other employed serial ten-fold dilutions of suspensions of organisms, and the inoculation of medium at each dilution stage. Viability was related to the time taken for flagellates to be found in the medium. A 1·0 m solution of glycerol in the flagellate suspension inhibited growth when diphasic medium was inoculated. This effect was removed by separating the organisms from the glycerol before inoculation, or by diluting the suspension approximately one hundred-fold. A similar inhibition was not observed for dimethylsulphoxide (DMSO). Glycerol (1·0 m), DMSO (1·5 m), polyvinylpyrrolidone (10% w/v) and sucrose (0·3 m) were not obviously detrimental to the organisms. Normal growth in diphasic medium resulted when these additives were removed after being in contact with organisms for 5 h in an ice bath. In freezing experiments, flagellates survived freezing and thawing while they were still in contact with their nutrient medium, and also after they had been separated, washed and resuspended in isotonic saline with 10 mm of glucose. The survival rate was much greater when either 1·5 m DMSO or 1·0 m glycerol was added. These additives were compared at one rate only, $\text{0·3°C}\text{min}$, and DMSO gave better protection. With 1·5 m DMSO, maximal survival was obtained at a cooling rate of $\text{1·9°C}\text{min}$. Relatively high rates of cooling, that is, over $\text{400°C}\text{min}$ were detrimental to the organisms.     

Freezing rabbit semen by the use of BF5 diluent

Three experiments were carried out to find the optimal concentration of DMSO and glycerol in BF5 diluent for freezing rabbit spermatozoa. Semen was diluted 1:1 with diluent A (BF5 + DMSO) at 25 degrees C and diluted further 1:1 with diluent B (diluent A + glycerol) after cooling down to 5 degrees C. Diluted semen was frozen immediately and stored in liquid nitrogen. Maximum percentages for motility and normal acrosomes were obtained in the presence of 12% DMSO (as expressed in diluent A) and 3% glycerol (final concentration) after thawing.     

Effect of glycerol and dimethyl sulfoxide on cryopreservation of rhesus monkey (Macaca mulatta) sperm

Glycerol and dimethyl sulfoxide (DMSO) are widely used as penetrating cryoprotectants in the freezing of sperm, and various concentrations are applied in different species and laboratories. The present study aimed to examine the effect of these two cryoprotectants at different concentrations (2%, 5%, 10%, and 15% glycerol or DMSO) on rhesus monkey sperm cryopreservation. The results showed that the highest recovery of post-thaw sperm motility, and plasma membrane and acrosome integrity was achieved when the sperm was frozen with 5% glycerol. Spermatozoa cryopreserved with 15% DMSO showed the lowest post-thaw sperm motility, and spermatozoa cryopreserved with 15% glycerol and 15% DMSO showed the lowest plasma membrane integrity among the eight groups. The results achieved with 5% glycerol were significantly better for all parameters than those obtained with 5% DMSO. The functional cryosurvival of sperm frozen with 5% glycerol was further assessed by in vitro fertilization (IVF). Overall, 85.7% of the oocytes were successfully fertilized, and 51.4% and 5.7% of the resulting zygotes developed into morulae and blastocysts, respectively. The results indicate that the type and concentration of the penetrating cryoprotectant used can greatly affect the survival of rhesus monkey sperm after it is frozen and thawed. The suitable glycerol level for rhesus monkey sperm freezing is 5%, and DMSO is not suitable for rhesus monkey sperm cryopreservation.     

Survival of frozen-thawed human red cells as a function of the permeation of glycerol and sucrose

Previous studies have demonstrated that glycerol does not have to permeate bovine red cells to protect them against subsequent freezing and thawing. The present study is concerned with the relation between solute permeation and freezing injury of human red cells. Cells were held in 2 m glycerol for 30 sec to 10 min at 0 °C and then frozen to ?196 °C at 60 °C/min. Cells cooled at this rate have a very low probability of undergoing intracellular freezing. Percent survivals (≡percent unhemolyzed) increased by 21% (from 66 to 80%) over the first 3-min period. Extrapolation to zero time (and zero glycerol permeation) yields a survival of 57%. Between 30 sec and 3 min the calculated osmolal ratio of intracellular glycerol to other solutes increased 240% (from 2.5 to 5.7). The human red cell is impermeable to sucrose at 0 °C. Cells suspended in 1.40 m sucrose (equiosmolal to 2.0 m glycerol) for 0.5 to 10 min prior to freezing yielded as high survivals after thawing as did cells in glycerol.These data indicate that prior permeation of additive is not a prerequisite for the survival of red cells subjected to subsequent freezing and thawing. Although sucrose and glycerol protect equally well to this point, differences appear when attempts are made to remove the additive. Over 90% of the cells survive the removal of glycerol. Only some 30% survive the removal of sucrose. Cells frozen in an equisomolal solution of sodium chloride do not even survive the initial freezing and thawing.The findings indicate that slow freezing injury cannot be accounted for in terms of the attainment of a critical minimum volume, nor can it be considered to be equivalent to posthypertonic hemolysis.     

Frozen DON cells as a source for a cell cycle assay of antitumor agents

This study was intended to determine the feasibility of using frozen mitotic mammalian cells as a source of synchronous cultures to determine the cell cycle phase specificity of cytotoxic agents. We first found that the relative effectiveness of different additives in protecting cells during freezing was DMSO > glycerol of polyvinyl pyrolidone > sucrose > 50% serum. We also found that mitotic cells frozen in glycerol did not progress synchronously through the cell cycle when thawed. However, mitotic cells frozen in DMSO had approximately the same cell cycle time as non-frozen mitotic cells and therefore could be thawed and cultured to determine phase specific cytotoxicity of compounds. However, better results were obtained when cells frozen in different phases were used to determine phase specific toxicity of compounds. The pattern of sensitivity to cytotoxic agents of cells frozen in different phases was the same as that of the non-frozen controls.     

Isolation and low temperature preservation of adult rat heart cells

Adult rat heart cells were isolated by perfusion of the coronary system of the heart with a 0.05% collagenase solution.In one method (A), cells were finally isolated by shaking the heart fragments in a collagenase solution, after which the cells were washed and suspended in a Ca- and Mg-free buffered salt solution. The effect of different DMSO concentrations, 5, 10, 15, 20, 25, and 30% and the effect of the addition and dilution rate of DMSO on the number of trypan blue-excluding, intact, and contracting cells were studied. The highest DMSO concentration which was tolerated by the isolated adult heart cells was 15%. Variation of addition rate and the dilution rate of DMSO had no effect. After freezing at external cooling rates of 1, 5, 10, 30, and 50 °C/min to ?100 °C, and then rapidly to ?196 °C, in the presence of 5, 10, or 15% DMSO, reanimation of these cells was not achieved.In another method (B), heart fragments, after collagenase perfusion of the heart, were first treated with 5, 10, or 15% DMSO, after which the cells were isolated. If these cells were frozen at 1 °C/min with 10% DMSO, 15% of the cells, expressed as a percentage of the control, remained morphologically intact and 38% of the cells were contracting after thawing. Significantly higher survival percentages of 30 and 61%, respectively, were obtained if the heart fragments were left intact during freezing.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing polyvinylpyrrolidone: relationship with postthypertonic hemolysis and solute movements

An investigation was made into the effects of the presence of polyvinylpyrrolidone (PVP) on changes in human red blood cells suspended in hypertonic solutions, on posthypertonic hemolysis, and on freezing at temperatures down to ?12 °C.PVP is very effective at reducing hemolysis when the red blood cells are frozen at temperatures down to ?12 °C. However, the membranes of the cells recovered on thawing have become very permeable to sodium and potassium ions and there is a much increased hemolysis if the cells are resuspended in an isotonic solution of sodium chloride.The presence of PVP does not affect the dehydration of the cells or the development of a change in membrane permeability when the cells are shrunken in hypertonic solutions at 0 °C. Neither does its presence in the hypertonic solution reduce the extent of posthypertonic hemolysis at 4 °C (as measured by the hemolysis on resuspension in an isotonic solution of sodium chloride), but it is more effective than sucrose at reducing hemolysis when present in the resuspension solution. It is concluded that the PVP is able to prevent swelling and hemolysis of cells which are very permeable to cations by opposing the colloid osmotic pressure due to the hemoglobin. However, this does not explain how PVP is able to protect cells against freezing damage at high cooling rates, and a mechanism by which it might do this is discussed.