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.     

Some combined effects of hypertonic solutions and changes in temperature on posthypertonic hemolysis of human red blood cells

The combined effects of hypertonic solutions and temperature changes on the posthypertonic hemolysis of human red blood cells have been investigated. Cells were exposed to hypertonic solutions of sodium chloride and also to hypertonic solutions of the extracellular cryoprotective additive sucrose, such as would occur during the freezing of cells in an isotonic salt solution to which 15% $\text{w}\text{v}$ sucrose had been added. In both cases the extent of posthypertonic hemolysis was increased by temperature reduction per se when the osmolality of the extracellular solution exceeded about 1400 mOsm/kg water. The posthypertonic hemolysis of cells exposed to a hypertonic solution at 0 °C was reduced with the temperature of the resuspension solution up to 35 °C.     

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.     

Membrane leakage of solutes after thermal shock or freezing

Washed human erythrocytes were cooled at different rates from +37 °C to 0 °C in hypertonic solutions of either NaCl (1.2 m) or of a mixture of sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). Thermal shock hemolysis was measured and the surviving cells were examined for their mass and cell water content and also for net movements of sodium, potassium, and ¹⁴C-sucrose. The results were compared with those obtained from cells in sucrose (40% $\text{w}\text{v}$) initially, cooled at different rates to ?196 °C and rapidly thawed.The cells cooled to 0 °C in NaCl (1.2 m) showed maximal hemolysis at the fastest cooling rate studied (39 °C/min). In addition in the surviving cells this cooling rate induced the greatest uptake of ¹⁴C-sucrose and increase in cell water and cell mass and also entry of sodium and loss of cell potassium. A different dependence on cooling rate was seen with the cells cooled from +37 °C to 0 °C in sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). In this solution, survival decreased both at slow and fast cooling rates correlating with the greatest uptake of cell sucrose and increase in cell water. There was extensive loss of cell potassium and uptake of sodium at all cooling rates, the cation concentrations across the cell membrane approaching unity.The cells frozen to ?196 °C at different cooling rates in sucrose (40% $\text{w}\text{v}$) initially, also showed sucrose and water entry on thawing together with a loss of cell potassium and an uptake of cell sodium. More sucrose entered the cells cooled slowly (1.8 ° C/min) than those cooled rapidly (318 ° C/min).These results show that cooling to 0 °C in hypertonic solutions (thermal shock) and freezing to ?196 °C both induce membrane leaks to sucrose as well as to sodium and potassium. These leaks are not induced by the hypertonic solutions themselves but are due to the effects of the added stress of the temperature reduction on the membranes modified by the hypertonic solutions. The effects of cooling rate are explicable in terms of the different times of exposure to the hypertonic solutions. These results indicate that the damage observed after thermal shock or slow freezing is of a similar nature.     

Effects of cooling rate on thermal shock hemolysis

The increase in thermal shock hemolysis in hypertonic sodium chloride with increasing cooling rate was confirmed. Thermal shock damage was also induced by hypertonic solutions of sucrose but it decreased with increasing cooling rate. The effect of cooling rate on thermal shock hemolysis appears to be due to the time that the cells are in the hypertonic solutions. The extent of the stress of the temperature reduction was independent of the cooling rate. In hypertonic sodium chloride susceptibility to thermal shock damage increased with increasing time of exposure at +25 °C (0–5 min) before decreasing with time (5–50 min). In contrast, with hypertonic sucrose, thermal shock damage increased gradually with time of exposure. The protective effects of sucrose on thermal shock hemolysis at a given osmolality can be explained by the different solution properties (e.g., ionic strength) of hypertonic sodium chloride and sucrose. These results suggest that the role of thermal shock damage during slow freezing should be reexamined.     

Thermal shock and dilution shock as the causes of freezing injury

We suggest that during slow freezing, cellular membranes are altered by the hypertonic solutions produced. This alteration in itself does not cause membrane leakage of normally impermeant solutes but it renders the cells susceptible to solute leakage on the application of a stress, which is provided during freezing by the reduction in temperature (thermal shock) and during thawing by dilution (dilution shock).During slow freezing the effects of cooling rate changes are due to the different times available for the hypertonic solutions to affect the membrane. At a given cooling rate cryoprotective agents reduce the effect on the cells at each temperature during freezing perhaps by reducing the ionic strength. The thermal shock stress during cooling and the dilution shock during thawing thus damages the cells less. With rapid freezing, there is insufficient time for these effects to take place during cooling, which allows the cells to reach low temperatures without thermal shock damage. However, the presence of extracellular ice and the formation of intracellular ice provide hypertonic conditions that render the cells liable to dilution shock on thawing. The slower the rate of thawing of rapidly cooled cells the greater will be the damage from this dilution shock.     

Thermal shock hemolysis in human red cells. I. The effects of temperature, time, and osmotic stress

Thermal shock is a form of hemolysis which occurs in human red cells exposed to greater than a critical level of osmotic stress of 1.4 Osm and subsequently cooled from above about 12 degrees C to below that temperature. Higher concentrations and higher cooling rates each increase the amount of hemolysis, within limits. Incubation for varying periods in hypertonic solutions and varying temperatures of incubation affect the amount of thermal shock. The effect of cooling rate on thermal shock is independent of the period of exposure to hypertonic solutions. Thermal shock is not the cause of freezing injury in human red cells, at least above -10 degrees C.     

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.     

Addition of oligosaccharide decreases the freezing lesions on human red blood cell membrane in the presence of dextran and glucose

Although incubation with glucose before freezing can increase the recovery of human red blood cells frozen with polymer, this method can also result in membrane lesions. This study will evaluate whether addition of oligosaccharide (trehalose, sucrose, maltose, or raffinose) can improve the quality of red blood cell membrane after freezing in the presence of glucose and dextran. Following incubation with glucose or the combinations of glucose and oligosaccharides for 3 h in a 37 °C water bath, red blood cells were frozen in liquid nitrogen for 24 h using 40% dextran (W/V) as the extracellular protective solution. The postthaw quality was assessed by percent hemolysis, osmotic fragility, mean corpuscle volume (MCV), distribution of phosphatidylserine, the postthaw 4 °C stability, and the integrity of membrane. The results indicated the loading efficiency of glucose or oligosaccharide was dependent on their concentrations. Moreover, addition of trehalose or sucrose could efficiently decrease osmotic fragility of red blood cells caused by incubation with glucose before freezing. The percentage of damaged cell following incubation with glucose was 38.04 ± 21.68% and significantly more than that of the unfrozen cells (0.95 ± 0.28%, P < 0.01). However, with the increase of the concentrations of trehalose, the percentages of damaged cells were decreased steadily. When the concentration of trehalose was 400 mM, the percentage of damaged cells was 1.97 ± 0.73% and similar to that of the unfrozen cells (P > 0.05). Moreover, similar to trehalose, raffinose can also efficiently prevent the osmotic injury caused by incubation with glucose. The microscopy results also indicated addition of trehalose could efficiently decrease the formation of ghosts caused by incubation with glucose. In addition, the gradient hemolysis study showed addition of oligosaccharide could significantly decrease the osmotic fragility of red blood cells caused by incubation with glucose. After freezing and thawing, when both glucose and trehalose, sucrose, or maltose were on the both sides of membrane, with increase of the concentrations of sugar, the percent hemolysis of frozen red blood cells was firstly decreased and then increased. When the total concentration of sugars was 400 mM, the percent hemolysis was significantly less than that of cells frozen in the presence of dextran and in the absence of glucose and various oligosaccharides (P < 0.01). However, when both glucose and trehalose were only on the outer side of membrane, with increase of the concentrations of sugars, the percent hemolysis was increased steadily. Furthermore, addition of oligosaccharides can efficiently decrease the osmotic fragility and exposure of phosphatidylserine of red blood cells frozen with glucose and dextran. In addition, trehalose or raffinose can also efficiently mitigate the malignant effect of glucose on the postthaw 4 °C stability of red blood cells frozen in the presence of dextran. Finally, addition of trehalose can efficiently protect the integrity of red blood cell membrane following freezing with dextran and glucose. In conclusion, addition of oligosaccharide can efficiently reduce lesions of freezing on red blood cell membrane in the presence of glucose and dextran.     

Survival of tissue culture cells frozen by a two-step procedure to -196 degrees C. I. Holding temperature and time.

A two-step freezing procedure has been examined in order to separate some of the causes of damage following freezing and thawing. Different holding temperatures and times have been studied during the freezing of Chinese hamster tissue culture cells in dimethyl sulphoxide (5%, $\text{v}\text{v}$). Damage following rapid cooling to, time at, and thawing from different holding temperatures was found to increase at lower holding temperatures and at longer times. Damage on subsequent cooling from the holding temperature to ?196 °C and thawing was found to diminish at lower holding temperatures and longer times. The net result was that optimal survival from ?196 °C was obtained after 10 min at ?25 °C. Protection against the second step of cooling to ?196 °C was acquired at the holding temperature itself and was absent at ?15 °C without freezing.It seems that this technique will allow the different phases of freezing injury to be separated. These phases may include thermal shock to the holding temperature, hypertonic damage at the holding temperature and dilution shock on thawing from ?196 °C.     

The mechanism of cryohemolysis: by direct observation with the cryomicroscope and the electron microscope.

Blood films (3–8 μm thick) supported between two glass coverslips were frozen to ?20 °C. In the extracellular areas, ice cavities of the order of 0.2 μm separated by bands of dense plasma were evident when examined with the electron microscope; intracellular ice was not observed with the light microscope. Electron microscopy also showed the presence of intracellular ice particles of the order of 0.2–0.7 μm, these appeared as fine reticulations when observed with the light microscope. Upon gradual rewarming the following changes were observed: recrystallization in the extracellular matrix (?18 to ?8 °C), intracellular recrystallization (?13 to ?10 °C), transfer of water from erythrocytes to extracellular areas (?9 to ?7 °C), and melting and hemolysis (?6 to ?2 °C).Freezing of blood at ?3 °C and subsequent thawing did not cause hemolysis of the red cells. In blood frozen at ?3 °C and cooled to ?20 °C or frozen by abrupt exposure to 20 °C the erythrocytes hemolyzed in 7/16–11/16 of a second, whereas in blood frozen at ?3 °C and cooled to ?10 °C the cells hemolyzed in 5–15 sec even though the mode if lysis (i.e., uniform seepage of hemoglobin from the surface of the cell) was similar in all cases. This indicates that the presence of intracellular ice does not seem to play a major role in the injury to the erythrocytes. The mechanism of cryoinjury demonstrated by hemolysis has been discussed.     

Effect of osmolality of skim-milk diluents and thawing rate on cryosurvival of ram spermatozoa

The effect of osmolality of skim-milk diluents (200, 320, 450, 600, and 750 mOsm/kg water) on the survival of ram spermatozoa frozen in straws were investigated after thawing in 39 °C water or in 20 °C air.Spermatozoa motility improved with increasing osmolality of the freezing diluent, irrespective of thawing rate. Diluents of 600 and 750 mOsm resulted in highest motility immediately after thawing and after 60 min incubation at 39 °C. A significant decrease in spermatozoa motility was observed when straws were thawed at 20 °C air with the magnitude of decrease inversely related to osmolality of the freezing diluent. Fertility of progestagen synchronized ewes inseminated with semen frozen in the 600 mOsm hypertonic skim-milk diluent was comparable to that obtained with fresh semen.     

An experimental study on the freezing of red blood cells with and without hydroxyethyl starch

Red blood cells were frozen in small capillaries down to ?196 °C at different linear cooling rates with or without the cryoadditive HES; the thawing rate was 3000 or 6500 °C/min. Hematocrit and hydroxyethyl starch concentration varied independently. The hemolysis of red blood cells was determined photometrically after 250-fold dilution and compared to totally hemolyzed samples. The typical U-shaped curves for hemolysis as a function of the cooling rate were obtained for all cell suspensions investigated. Relative optimum cooling rates were determined for the respective combinations of HES and hct. The results show that increasing hct causes an increased hemolysis; increased HES concentration C_HES reduces the optimum cooling rate B_opt; increased hct results in higher optimal cooling rates. The findings allow one to establish a linear correlation of the HES concentration and the optimum cooling rates when the dilution of the extracellular medium by the cell water efflux during freezing is taken into account. A comparison with results from larger volumes frozen (25 ml) shows that the established relationship between hematocrit, HES concentration, and optimal cooling rate remains valid.     

Hemolysis in several animal species after rapid freezing of blood

The effect of various freezing rates on the extent of hemolysis in human, bovine and ovine erythrocytes, which are known to have different cell volumes, water contents and permeabilities, was investigated. Blood in stainless steel capillary tubes was frozen at various rates by abrupt immersion of the capillaries into cooling baths at temperatures ranging from ?20° to ?130°C. Minimum lysis values were obtained at freezing temperatures of ?40°, ?50° and ?70°C with, respectively, human, bovine and ovine blood. The smallest, highly permeable sheep erythrocytes were the least damaged at the highest freezing rates; the largest human cells with the highest water content, suffered the greatest damage; intermediate values were obtained with ox blood. At the lower freezing rates, the largest, human cells were the least damaged; the highest hemolysis values were obtained with the smallest, highly permeable sheep erythrocytes; ox blood again gave intermediate values. These results are in agreement with current views that, (1) very rapid freezing results in the formation of damaging intracellular ice; (2) injury associated with slow freezing is related to the extent of dehydration or to the increase in electrolyte concentration which accompanies ice formation; (3) minimum hemolysis is obtained under those freezing conditions in which osmotic dehydration has been sufficient to prevent the formation of intracellular ice, but has left enough water in the cells to prevent the damaging effects of dehydration and high electrolyte concentrations.     

Efflux of Red Cell Water into Buffered Hypertonic Solutions

Buffered NaCl solutions hypertonic to rabbit serum were prepared and freezing point depressions of each determined after dilution with measured amounts of water. Freezing point depression of these dilutions was a linear function of the amount of water added. One ml. of rabbit red cells was added to each 4 ml. of the hypertonic solutions and after incubation at 38°C. for 30 minutes the mixture was centrifuged and a freezing point depression determined on the supernatant fluid. The amount of water added to the hypertonic solutions by the red cells was calcuated from this freezing point depression. For each decrease in the freezing point of -0.093°C. of the surrounding solution red cells gave up approximately 5 ml. of water per 100 ml. of red cells in the range of -0.560 to -0.930°C. Beyond -0.930°C. the amount of water given up by 100 ml. of red cells fits best a parabolic equation. The maximum of this equation occurred at a freezing point of the hypertonic solution of -2.001°C. at which time the maximum amount of water leaving the red cells would be 39.9 ml. per 100 ml. of red cells. The data suggest that only about 43 per cent of the red cell water is available for exchange into solutions of increasing tonicity.     

Role of membrane thermotropic properties on hypotonic hemolysis and hypertonic cryohemolysis of human red blood cells

The hypothesis of a correlation between the effects of temperature on red blood cells hypotonic hemolysis and hypertonic cryohemolysis and two thermotropic structural transitions evidenced by EPR studies has been tested. Hypertonic cryohemolysis of red blood cells shows critical temperatures at 7 degrees C and 19 degrees C. In hypotonic solution, the osmotic resistance increases near 10 degrees C and levels off above 20 degrees C. EPR studies of red blood cell membrane of a 16-dinyloxyl stearic acid spin label show, in the 0-50 degrees C range, the presence of three thermotropic transitions at 8, 20, and 40 degrees C. Treatments of red blood cells with acidic or alkaline pH, glutaraldehyde, and chlorpromazine abolish hypertonic cryohemolysis and reduce the effect of temperature on hypotonic hemolysis. 16-Dinyloxyl stearic acid spectra of red blood cells treated with glutaraldehyde and chlorpromazine show the disappearance of the 8 degrees C transition. Both the 8 degrees C and the 20 degrees C transitions were abolished by acidic pH treatment. The correlation between the temperature dependence of red blood cell lysis and thermotropic breaks might be indicative of the presence of structural transitions producing areas of mismatching between differently ordered membrane components where the osmotic resistance is decreased.     

A comparative study of the effects of freezing and frozen storage on intact and demembranated bull spermatozoa

The damage caused to bull sperm by freezing and thawing them without cryoprotectants was assessed in both intact and membrane-extracted cells. Preparations of membrane-extracted cells were produced by treating the sperm with 0.1% Triton X-100 and motility was restored with exogenously applied ATP and Mg²⁺. Motile demembranated sperm showed no detectable reduction in motility after freezing and thawing. In contrast, when intact cells where subjected to freezing and thawing they lost all motility. These damaged cells were also restored to motility when exogenous ATP and Mg²⁺ were added to the sperm mixture. Apparently freezing and thawing sperm cells causes damage to the plasma membrane which permits ATP and Mg²⁺ to freely enter or leave the cells, but does not damage the components of the sperm cell which generate motility.The effects of storage temperature on frozen demembranated sperm were also explored. Sperm held at ?20 °C showed marked structural changes and progressively decreased motility after prolonged storage. When sperm were frozen at ?20 °C the mitochondrial structures were completely lost after 48 to 72 hr and ATP caused the disintegration of the flagellum rather than initiating motility. Sperm which were frozen at ?76 °C retained motility after short periods of storage, but showed a significant decline in motility when thawed after 8 days. Demembranated sperm which were kept frozen at ?196 °C showed no significant loss of motility when thawed after 1 year of storage.     

The effect of initial tonicity on freeze/thaw injury to human red cells suspended in solutions of sodium chloride

Human red blood cells, suspended in solutions of sodium chloride, have been frozen to temperatures between -2 and -14 degrees C and thawed, and the extent of hemolysis was measured. In parallel experiments, red cells were exposed to similar cycles of change in the composition of the suspending solution, but by dialysis at 21 degrees C. The tonicity of the saline in which the cells were initially suspended was varied between 0.6x isotonic and 4x isotonic; some samples from each experimental treatment were returned to isotonic saline before hemolysis was measured. It was found that the tonicity of the saline used to suspend the cells for the main body of the experiment affected the amount of hemolysis measured: raising the tonicity from 0.6x to 1x to 2x reduced hemolysis, both in the freezing and in the dialysis experiments, whereas raising the tonicity further to 4x reversed that trend. There was little difference between the freeze/thaw and the dialysis treatments for the cells suspended in 1x or 2x saline, whether or not the cells were returned to isotonic conditions. However, the cells suspended in 0.6x saline showed greater damage from freezing and thawing than from the comparable change in the composition of the solution, whether or not they were returned to isotonic conditions. Cells that were suspended in 4x saline and exposed to changes in salt concentration by dialysis showed less hemolysis when they were assayed in the 4x solution than cells that had received the comparable freezing/thaw treatment, but when the experiment included a return to isotonicity, the two treatments gave similar results. Returning the cells to isotonic saline had a negligible affect on the cells in 0.6x and 1x saline, but caused considerable hemolysis in the 2x and 4x samples, more so after dialysis than after freezing and thawing. We conclude that cells suspended in 0.6x and 4x saline behave differently from cells suspended in 1x and 2x saline and hence that cells suspended in a range of solutions of differing initial tonicity should not be treated as a homogeneous population. We argue that an effect of the unfrozen fraction of water (U) cannot be distinguished, within the framework of these freeze/thaw experiments alone, from an effect of initial tonicity, and that the biphasic nature of the correlation between haemolysis and U makes a causal connection improbable.(ABSTRACT TRUNCATED AT 400 WORDS)     

Freezing injury to erythrocytes. I. Freezing patterns and post-thaw hemolysis.

The extent of hemolysis of human red blood cells suspended in different concentrations of glycerol and frozen at various cooling rates was investigated on the basis of morphological observation in the frozen state. Hemolysis of the cells in the absence of glycerol showed a V-shaped curve in terms of cooling rates. There was 70% hemolysis at an optimal cooling rate of approximately 10³ °C/min and 100% hemolysis at all other rates tested. Morphologically, a lower than optimal cooling rate resulted in cellular shrinkage, while a higher than optimal rate resulted in the formation of intracellular ice.The cryoprotective effect of glycerol was dependent upon its concentration and on the cooling rate. Samples frozen at 10³ and 10⁴ °C/min showed freezing patterns which differed from cell to cell. The size of intraand extracellular ice particles became smaller, and there was less shrinkage or deformation of cells as the rate of cooling and concentration of glycerol were increased.There was some correlation between the morphology of frozen cells and the extent of post-thaw hemolysis, but the minimum size of intracellular ice crystals which might cause hemolysis could not be estimated. As a cryotechnique for electron microscopy, the addition of 30% glycerol and ultrarapid freezing at 10⁵ °C/min are minimum requirements for the inhibition of ice formation and the prevention of the corresponding artifacts in erythrocytes.     

A method for simultaneous isolation and cryopreservation of bovine lymphocytes

A technique for the simultaneous isolation and cryopreservation of bovine lymphocytes was presented. Whole blood was slowly diluted 1:2 with RPMI-Hepes containing 15% Me₂SO to yield final concentrations of 50% whole blood and 7.5% Me₂SO. Aliquots were cooled to at least ?80 °C at a rate of 2.5 °C/min and subsequently immersed in liquid nitrogen for storage. Samples were thawed rapidly by agitation in a 37 °C water bath and diluted rapidly with warm RPMI-Hepes. After centrifugation, the lymphocyte pellet was washed and suspended in medium for cell identification and lymphocyte stimulation assays. Few red blood cells, granulocytes, and monocytes survived this freezing and thawing procedure. Recovery of lymphocytes was 69–75%, as compared to a recovery of 58–68% using isolation on density gradients. Only small differences in the numbers of lymphocytes that (i) form spontaneous rosettes with sheep red blood cells and (ii) bind anti-IgG were found between the two isolation procedures. Cell proliferation in response to PPD-B or PHA and the enhancement of amino acid transport in response to PPD-B were the same for lymphocytes isolated by both methods.