The freeze-thaw stress response of the yeast Saccharomyces cerevisiae is growth phase specific and is controlled by nutritional state via the RAS-cyclic AMP signal transduction pathway.

The ability of cells to survive freezing and thawing is expected to depend on the physiological conditions experienced prior to freezing. We examined factors affecting yeast cell survival during freeze-thaw stress, including those associated with growth phase, requirement for mitochondrial functions, and prior stress treatment(s), and the role played by relevant signal transduction pathways. The yeast Saccharomyces cerevisiae was frozen at -20 degrees C for 2 h (cooling rate, less than 4 degrees C min-1) and thawed on ice for 40 min. Supercooling occurred without reducing cell survival and was followed by freezing. Loss of viability was proportional to the freezing duration, indicating that freezing is the main determinant of freeze-thaw damage. Regardless of the carbon source used, the wild-type strain and an isogenic petite mutant ([rho 0]) showed the same pattern of freeze-thaw tolerance throughout growth, i.e., high resistance during lag phase and low resistance during log phase, indicating that the response to freeze-thaw stress is growth phase specific and not controlled by glucose repression. In addition, respiratory ability and functional mitochondria are necessary to confer full resistance to freeze-thaw stress. Both nitrogen and carbon source starvation led to freeze-thaw tolerance. The use of strains affected in the RAS-cyclic AMP (RAS-cAMP) pathway or supplementation of an rca1 mutant (defective in the cAMP phosphodiesterase gene) with cAMP showed that the freeze-thaw response of yeast is under the control of the RAS-cAMP pathway. Yeast did not adapt to freeze-thaw stress following repeated freeze-thaw treatment with or without a recovery period between freeze-thaw cycles, nor could it adapt following pretreatment by cold shock. However, freeze-thaw tolerance of yeast cells was induced during fermentative and respiratory growth by pretreatment with H2O2, cycloheximide, mild heat shock, or NaCl, indicating that cross protection between freeze-thaw stress and a limited number of other types of stress exists.     

A comparative study of the morphology and viability of hyphae of Penicillium expansum and Phytophthora nicotianae during freezing and thawing

The changes in morphology of Penicillium expansum Link and Phytophthora nicotianae Van Breda de Haan during freezing and thawing in a growth medium with and without the cryoprotective additive glycerol were examined with a light microscope fitted with a temperature-controlled stage. Viability of 0.5-1.0 mm diameter colonies of both fungi was determined after equivalent rates of cooling to -196 degrees C in the presence or absence of glycerol. In P. expansum shrinkage occurred in all hyphae at rates of cooling of less than 15 degrees C min-1; at faster rates intracellular ice nucleation occurred. The addition of glycerol increased the rate of cooling at which 50% of the hyphae formed intracellular ice from 18 degrees C min-1 to 55 degrees C min-1. This species was particularly resistant to freezing injury and recovery was greater than 60% at all rates of cooling examined. At rapid rates of cooling recovery occurred in hyphae in which intracellular ice had nucleated. In contrast, during the cooling of Ph. nicotianae in the growth medium, shrinkage occurred and no samples survived on thawing from -196 degrees C. However, on the addition of glycerol, shrinkage during freezing decreased and viable hyphae were recovered upon thawing; at rates of cooling over 10 degrees C min-1 the loss of viability was related to glycerol-induced osmotic shrinkage during cooling rather than to the nucleation of intracellular ice.     

Multifaceted freezing injury in human polymorphonuclear cells at high subfreezing temperatures

Extracellular freezing injury at high subzero temperatures in human polymorphonuclear cells (PMNs) was studied with a cryomicroscope, electron microscope, and functional assays (phagocytosis, microbicidal activity, and chemotaxis). There are at least four major factors in freezing injury: osmotic stress, chilling, cold shock, and dilution shock. Extracellularly frozen PMNs lose functions when cooled to -2 degrees C without a cryoprotectant. Cells lose volume on freezing to the same degree as in hypertonic exposure. PMNs have a minimum volume to which they can shrink without injury. Greater dehydration produces irreversible injury to cellular functions, and cells eventually collapse under high osmotic stress. Chilling sensitivity is seen in slowly chilled, supercooled PMNs below -5 degrees C; at -7 degrees C, functions are lost in 1 h. This injury can be prevented by the addition of Me2SO but not glycerol. Me2SO does not, however, prevent cold shock (injury due to rapid cooling), which is seen during cooling at 10 degrees C/min to -14 degrees C, but not during slow cooling at 0.5 degrees C/min. One of the problems of using glycerol as a cryoprotectant stems from the high sensitivity of PMNs to dilution shock during the dilution or removal of glycerol.     

Cooling rate influences cryoprotectant distribution and organ dehydration in freezing wood frogs.

Ice formation in the freeze-tolerant wood frog (Rana sylvatica) induces the production and distribution of the cryoprotectant, glucose. Concomitantly, organs undergo a beneficial dehydration which likely inhibits mechanical injury during freezing. Together, these physiological responses promote freezing survival when frogs are frozen under slow cooling regimes. Rapid cooling, however, is lethal. We tested the hypothesis that the injurious effects of rapid cooling stem from an inadequate distribution of glucose to tissues and an insufficient removal of water from tissues during freezing. Accordingly, we compared glucose and water contents of five organs (liver, heart, skeletal muscle, eye, brain) from wood frogs cooled slowly or rapidly during freezing to -2.5 degrees C. Glucose concentrations in organs from slowly cooled frogs were significantly elevated over unfrozen controls, but no significant increases occurred in rapidly cooled frogs. Organs from slowly cooled frogs contained significantly less water than did those from controls, whereas water contents from rapidly cooled frogs generally were unchanged. Rapid cooling therefore inhibited the production and distribution of cryoprotectant and organ dehydration during freezing. This inhibition may result from an accelerated, premature failure of the cardiovascular system.     

Combined effects of glycerol concentration, cooling velocity, and osmolality of skim milk diluents on cryopreservation of ram spermatozoa

The interaction of glycerol concentration from 0 to 16% and cooling velocity from 1 to 100 degrees C/min on freeze-thaw survival of ram spermatozoa was studied using a diluent based on 15% skim milk (450 mOs/kg water). Optimal spermatozoa survival (percentage motility and rating) was obtained with 4 to 6% glycerol and freezing rates of 10 to 100 degrees C/min. Similar results were obtained with 8% glycerol at freezing rates of 5 to 30 degrees C/min. Although the ram spermatozoa tolerated several cooling velocities at each glycerol concentration, increasing the concentration of glycerol resulted in a downshift in the range of optimal cooling velocities. Glycerol concentrations above 8% were toxic and contributed greatly to the progressive decrease in spermatozoa survival. Comparison of the 15% skim milk diluent (450 mOs/kg water) with a 19% skim milk diluent (600 mOs/kg water) showed that optimal cryosurvival was obtained with 4 to 6% glycerol and freezing rates of 10 to 100 degrees C/min with both diluents.     

Studies on the cryopreservation of eggs of Angiostrongylus cantonensis

The possibility of cryopreserving the eggs of Angiostrongylus cantonensis collected from the uterus of female worms was investigated. Eggs were cultured in NCTC 109 medium containing 50% rat serum, and various growth stages, from one-cell eggs to embryonated eggs, were used in this study. As a cryoprotective agent, dimethylsulphoxide (Me2SO) was added to the medium at a final concentration of 1 M. Eggs suspended in 0.2 ml of the medium at 37 degrees C were cooled to 0 degrees C at a rate of 1 degree C min-1, then an equal volume of 2M-Me2SO solution was added. After equilibration for 15 min, the freezing procedures were started. In the freezing procedures, the effectiveness of (i) a seeding process, (ii) different cooling and warming rates and (iii) the relationship between the growth stages of the eggs and their tolerance to freezing at -20 degrees C were investigated. It was found the highest level of survival could be obtained with 32-cell eggs cooled at a rate of 0.3 degrees C min-1 or more slowly with seeding at -4 degrees C and warming at a rate of 5 degrees C min-1. Survival was influenced more by cooling rate than by warming rate. Using these optimum conditions, the survival of eggs was then investigated following cooling to various temperatures. While more than 50% of eggs were found to survive cooling to -30 degrees C, extremely low survival was noted from lower temperatures.     

Studies on the mechanisms of mammalian cell killing by a freeze-thaw cycle: conditions that prevent cell killing using nucleated freezing

Normally a freeze-thaw cycle is a very efficient method of killing mammalian cells. However, this report describes conditions that prevent killing of cultured mammalian cells by nucleated freezing at -24 degrees C. Optimal protection from cell killing at -24 degrees C was obtained in isotonic solutions containing an organic cryoprotectant such as dimethyl sulfoxide (DMSO; 10%, v/v), a saccharide such as sucrose over a broad concentration range from 50 to 150 mM, and glucose. Glycerol was also an effective cryoprotectant but other organic solvents were ineffective, although in some cases they appeared to protect cell membranes, while not protecting other vital components. A wide variety of saccharide structures were effective at protecting cells from freeze-thaw killing, with trehalose being particularly effective. The degree of resistance to killing by a freeze-thaw cycle under these conditions varied widely among different cell lines. If toxicity of DMSO was responsible for this variability of cryoprotection, it must have been due to short-term, not longer term, toxicity of DMSO. Studies on the mechanism by which cells are protected from killing under these conditions indicated that neither vitrification of the medium nor the concentrating of components during freezing were involved. One model not eliminated by the mechanistic studies proposes that the organic solvent cryoprotectant component acts by fluidizing membranes under the thawing conditions, so that any holes produced by ice crystals propagating through membranes can reseal during the thawing process. In this model one of the mechanisms by which the saccharide component could act is by entering the cells and stabilizing vital intracellular components. Consistent with this, a freeze-thaw cycle promoted the uptake of labeled sucrose into cultured cells.     

Freeze tolerance in the gray treefrog: cryoprotectant mobilization and organ dehydration.

Freeze tolerance in the frog Rana sylvatica is supported by nonanticipatory mobilization of cryoprotectant (glucose) and redistribution of organ water. Other freeze-tolerant frogs may manifest these responses but differences exist. For example, the gray treefrog (Hyla versicolor) accumulates mostly glycerol as opposed to glucose. The current study reports additional novel features about cryoprotection in H. versicolor. Frogs were acclimated to low temperature for 12 weeks and frozen for 3 days at -2.4 degrees C. Some frogs were then thawed at 3 degrees C for 4 hr. Calorimetry revealed that frozen frogs had 53.9% +/- 11.1% of their body water in ice, and all frogs recovered following this procedure. Plasma glucose was low prior to the onset of freezing (1.1 +/- 0.9 micromol/ml) and it was 20x higher in postfreeze frogs. Constituting nearly 30% of plasma solute, glycerol was 117.2 +/- 13.6 micromol/ml prior to freezing and it remained equally high in postfreeze frogs. Liver water content was moderately lower in frozen frogs when compared to controls (62.9% +/- 3.7% vs. 68.6% +/- 1.7%), whereas postfreeze frogs excessively hydrated their livers (75.7% +/- 2.1%). Less-pronounced changes were seen in muscle water content. H. versicolor can mobilize its major cryoprotectant, glycerol, in response to extended cold acclimation, which is unique in comparison to other freeze-tolerant frogs, and it experiences only moderate organ dehydration during freezing. This species conforms with other freeze-tolerant frogs, however, by mobilizing glucose as a direct response to tissue freezing.     

Corneal cryopreservation with dextran.

Different methods of corneal cryopreservation have been introduced, those employing intracellular cryoprotectants such as Me2SO or glycerol being the most widely favored. We investigated the influence of several freeze-thaw trauma variables on the survival of porcine endothelial monolayers when employing the extracellular cryoprotective agent dextran. We first examined the effects of various dextran concentrations and then, having ascertained the optimal concentration, further investigated the influence of fetal calf serum (FCS) concentration in the cryopreservation medium, the cooling rate, the thawing temperature, and the length of the preincubation in the freezing medium prior to cryopreservation. The numerical densities of endothelial cells were determined at dissection in hypoosmotic balanced salt solution and after organ culture by staining with alizarin red S and trypan blue. Morphological evaluation was not performed directly after thawing but after a subsequent organ culture at 37 degrees C to detect latent cell damage after freeze-thaw trauma. Our data revealed that corneas cryopreserved in minimal essential medium containing 10% dextran but lacking FCS, preincubated for 3 h, frozen at a cooling rate of 1 degrees C/min, and thawed at 37 degrees C incurred the lowest cell losses (22.4%, SD +/- 3.8). We conclude that dextran is an effective cryoprotectant for freezing of porcine corneas. However, variations between species in the results of cryopreservation require further investigation of an in vivo animal model and studies with human corneas before its clinical use can be recommended.     

Status of cryopreservation of embryos from domestic animals.

The discovery of glycerol as an effective cryoprotectant for spermatozoa led to research on cryopreservation of embryos. The first successful offspring from frozen-thawed embryos were reported in the mouse and later in other laboratory animals. Subsequently, these techniques were applied to domestic animals. Research in cryopreservation techniques have included studies concerning the type and concentration of cryoprotectant, cooling and freezing rates, seeding and plunging temperatures, thawing temperatures and rates, and methods of cryoprotectant removal. To date, successful results based on pregnancy rates have been obtained with cryopreserved cow, sheep, goat, and horse embryos but no success has been reported in swine. Post-thaw embryo survival has been shown to be dependent on the initial embryo quality, developmental stage, and species. The freezing techniques most frequently used in research and by commercial companies are identified as "equilibrium" cryopreservation. In this technique the embryos are placed in a concentrated glycerol solution (1.4 M in PBS supplemented with BSA) at room temperature and the glycerol is allowed to equilibrate for a 20-min period. During the cooling process the straws are seeded (-4 to -7 degrees C) and cooling is continued at a rate of 0.3 to 0.5 degree C/min to -30 degrees C when bovine embryos may be plunged into LN2. Sheep embryos are successfully frozen with ethylene glycol (1.5 M) or DMSO (1.5 M) rather than with glycerol. Horse embryos have been frozen in 0.5 rather than 0.25 cc straws but with cooling rates and seeding and plunging temperatures similar to those used with bovine embryos. Swine embryos have shown a high sensitivity to temperature and cryoprotectants probably due to their high lipid content and a temperature decrease to 15 or 10 degrees C causes a dramatic increase in the percentage of degenerated embryos. However, a recent study has shown that hatched pig blastocysts survived exposure below 15 degrees C. Recent research has shown that embryos may also be frozen by a "nonequilibrium" method. This rapid freezing by vitrification consists of dehydration of the embryo at room temperature by a very highly concentrated vitrification media (3.5 to 4.0 M) and a very rapid freeze that avoids the formation of ice allowing the solution to change from a liquid to a glassy state. Vitrification solutions consist of combinations of sucrose, glycerol, and propylene glycol. With this technique, 50% pregnancy rates have been reported with the bovine blastocyst.     

Cryopreservation of yellowfin seabream (Acanthopagrus latus) spermatozoa (Teleost, Perciformes, Sparidae)

The effects of both osmolality and cation in the initiation of sperm motility were examined in yellowfin seabream, Acanthopagrus latus. Various factors involved in the cryopreservation of yellowfin seabream spermatozoa on motility are discussed. Extender containing only glucose proved to be a suitable medium for freezing yellowfin seabream spermatozoa to -196 degrees C. Glycerol seems to have a direct osmotic effect on yellowfin seabream sperm cells, and it induced sperm motility before freezing and during thawing. However, this exhausted the energy needed for sperm motility for fertilization. Dimethyl sulfoxide (DMSO) proved superior to ethylene glycerol, propylene glycerol, glycerol and methanol as a cryoprotectant. Prolonged equilibration time had a detrimental effect on both prefreezing and post-thawing sperm motility. The estimated optimum freezing rate was in the range of -20 to -154 degrees C/min. More frozen-thawed than fresh spermatozoa are required to achieve comparable fertilization rates.     

Cryopreservation of Plasmodium chabaudi. II. Cooling and warming rates

Various cooling and warming rates were investigated to determine the optimum conditions for cryopreserving the intraerythrocytic stages of Plasmodium chabaudi. Infected blood, equilibrated in 10% v/v glycerol at 37 degrees C or in 15% v/v Me2SO at 0 degree C for 10 min, was cryopreserved using cooling rates between 1 and 5100 degrees C min-1. After overnight storage in liquid nitrogen the samples were warmed at 12,000 degrees C min-1. Warming rates between 1 and 12,000 degrees C min-1 were investigated using samples previously cooled at 3600 degrees C min-1. After thawing, the glycerol and Me2SO were removed by dilution in 15% v/v glucose-supplemented phosphate-buffered saline. Survival was assayed by inoculation of groups of five mice each with 10(6) infected cells and the time taken to reach a level of 2% parasitemia estimated. The optimum cooling rate was 3600 degrees C min-1 for parasites frozen using either 10% glycerol or 15% Me2SO; the pre-2% patent periods were 0.90 and 1.01 days above control values (representing survival levels of 21 and 17.5%, respectively). The optimum warming rate was 12,000 degrees C min-1; the pre-2% patent periods were 1.01 and 1.32 days above control values, respectively (18 and 10% survival), for glycerol and Me2SO. With ethanediol (5% v/v) and sucrose (15% w/v) as cryoprotectants the optimum warming rates were also 12,000 degrees C min-1 while the optimum cooling rates were 330 and 3600 degrees C min-1, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cryopreservation of Crassostrea gigas vesicular cells: viability and metabolic activity

Cryopreservation is widely used for long-term conservation of various tissues, embryos or gametes. However, few studies have described cryopreservation of invertebrate primary cell cultures and more particularly of marine invertebrate somatic cells. This technique would however be of great interest to facilitate the study of various metabolic processes which vary seasonally. The aim of the present study was to develop a protocol for cryopreservation of Crassostrea gigas vesicular cells. Different parameters were adjusted to improve recovery of cells after freezing. The most efficient cryoprotectant agent was a mix of Me(2)SO, glycerol, and ethylene glycol (4% each). The optimal cooling rate was -1 degrees Cmin(-1) down to -70 degrees C before transfer into liquid nitrogen. In these conditions the percentage of viable cells reached 70% of the control. The glucose metabolism of thawed cells was evaluated using radioactive glucose as a tracer. Immediately after thawing, glucose uptake involving membrane transporters was greatly reduced (24% of control) whereas glucose incorporation into glycogen was less affected (68% of control).     

Infective Juveniles of the Entomopathogenic Nematode,Steinernema feltiae Produce Cryoprotectants in Response to Freezing and Cold Acclimation

Steinernema feltiae is a moderately freeze-tolerant entomopathogenic nematode which survives intracellular freezing. We have detected by gas chromatography that infective juveniles of S. feltiae produce cryoprotectants in response to cold acclimation and to freezing. Since the survival of this nematode varies with temperature, we analyzed their cryoprotectant profiles under different acclimation and freezing regimes. The principal cryoprotectants detected were trehalose and glycerol with glucose being the minor component. The amount of cryoprotectants varied with the temperature and duration of exposure. Trehalose was accumulated in higher concentrations when nematodes were acclimated at 5°C for two weeks whereas glycerol level decreased from that of the non-acclimated controls. Nematodes were seeded with a small ice crystal and held at -1°C, a regime that does not produce freezing of the nematodes but their bodies lose water to the surrounding ice (cryoprotective dehydration). This increased the levels of both trehalose and glycerol, with glycerol reaching a higher concentration than trehalose. Nematodes frozen at -3°C, a regime that produces freezing of the nematodes and results in intracellular ice formation, had elevated glycerol levels while trehalose levels did not change. Steinernema feltiae thus has two strategies of cryoprotectant accumulation: one is an acclimation response to low temperature when the body fluids are in a cooled or supercooled state and the infective juveniles produce trehalose before freezing. During this process a portion of the glycerol is converted to trehalose. The second strategy is a rapid response to freezing which induces the production of glycerol but trehalose levels do not change. These low molecular weight compounds are surmised to act as cryoprotectants for this species and to play an important role in its freezing tolerance.     

Storage of Chinchilla lanigera Semen at 4°C for 24 or 72 h with Two Different Cryoprotectants

The objectives of this study were to: (a) test the functional activity of Chinchilla lanigera spermatozoa suspended in either glycerol or ethylene glycol, cooled to 4 degrees C, and stored for 24 or 72 h and (b) investigate, after these cooling periods, the effects of incubating sperm at 37 degrees C (for 4 h) upon sperm functional activity. The ejaculate was mixed with the cryoprotectant medium (at 1 M final concentration) and cooled to 4 degrees C. After warming, sperm motility, sperm viability, hypoosmotic swelling test results, and acrosomal integrity were significantly higher for samples containing ethylene glycol than for those in glycerol, stored for 24 or 72 h, and then assayed after 0 or 4 h incubation at 37 degrees C. A significant reduction of sperm motility and viability was detected only when the glycerol cryoprotectant agent was employed, compared to the fresh samples. These results clearly indicate that under our experimental conditions, ethylene glycol is a better protectant for sperm storage than glycerol.     

Manifestations of cell damage after freezing and thawing

The nature of the primary lesions suffered by cells during freezing and thawing is unclear, although the plasma membrane is often considered the primary site for freezing injury. This study was designed to investigate the nature of damage immediately after thawing, by monitoring several functional tests of the cell and the plasma membrane. Hamster fibroblasts, human lymphocytes, and human granulocytes were subjected to a graded freeze-thaw stress in the absence of cryoprotective compound by cooling at -1 degree C/min to a temperature between -10 and -40 degrees C, and then were either warmed directly in water at 37 degrees C or cooled rapidly to -196 degrees C before rapid warming. Mitochondrial function in the cells was then assessed using 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyl-tetrazolium bromide (MTT), fluorescein diacetate (FDA), colony growth, and osmometric response in a hypertonic solution. Cells behaved as osmometers after cooling at -1 degree C/min to low temperatures at which there were no responses measured by other assays, indicating that the plasma membrane is not a primary site for injury sustained during slow cooling. These results also indicate that the FDA test does not measure membrane integrity, but reflects the permeability of the channels through which fluorescein leaves the cells. Fewer cells could respond osmotically after cooling under conditions where intracellular freezing was likely, implying that the plasma membrane is directly damaged by the conditions leading to intracellular freezing. A general model of freezing injury to nucleated mammalian cells is proposed in which disruption of the lysosomes constitutes the primary lesion in cells cooled under conditions where the cells are dehydrated at low temperatures.     

Effects of extender composition, cooling rate and freezing on the fertilisation viability of spermatozoa of the Pacific oyster (Crassostrea gigas)

The aim of this research was to optimise protocols for freezing spermatozoa of the Pacific oyster. All the phases of the cryopreservation procedure (choice of cryoprotectant, cooling, freezing, and thawing) were studied in relation to the species of spermatozoa to restore on thawing the morphological and physiological characteristics of fresh semen. The choice of type and concentration of cryoprotectant in which semen is incubated before freezing is fundamental for a successful cryopreservation: the cryoprotectants (dimethylsulfoxide--Me(2)SO, ethylene glycol--EG, propylene glycol-PG, and glycerol in concentrations between 5 and 15%) were tested for their toxicity on the semen exposed up to 30 min at +26 degrees C (room temperature) by evaluating its ability to fertilise and the embryo development to the regular D larval stage. The best cryoprotectants, Me(2)SO, EG, and PG 5, 10, and 15% respectively, were used for the pre-cooling (adaptation/cooling) tests. Two different adaptation/cooling procedures were tested: (A) from +26 degrees C to 0-2 degrees C (2.6 degrees C/min) and (B) at +26 degrees C for 15 min. Lastly, using the cryoprotectants and the adaptation procedure (B) that had given the best results in the preceding stages of the experiment, four cooling rates were tested: 6, 11, 16, and 21 degrees C/min. It was seen that the semen that was incubated with EG 10%, adapted at +26 degrees C for 15 min, and then cooled at a rate of 6 degrees C/min showed a percentage of regular D larvae on thawing comparable to that of fresh semen (p > 0.05).     

The effect of internal and external cryoprotectants on zebrafish (Danio rerio) embryos

The study investigated the effects of internal (DMSO, 1,2-propanediol, glycerol, ethylene glycol, methanol, N,N-dimethylacetamide) and external cryoprotectants (glucose, sucrose) on the viability and on morphometric parameters of zebrafish embryos. From the tested internal cryoprotectants, DMSO had the lowest toxicity, followed by 1,2-propanediol and glycerol. The external cryoprotectants were less toxic then the internal ones. Early ontogenetic stages were more sensible to cryoprotectant exposure than advanced stages. Two-step incubation procedures in increasing concentrations of internal and external cryoprotectants were superior to multiple-step exposure procedures. All tested vitrification solutions exceeded the tolerance limit of embryos. The tolerance of zebrafish embryos to cryoprotectants was highly variable in a concentration range causing approximately 50% embryo mortality. The width of the perivitelline space showed significant morphometrical changes due to cryoprotectant exposure. In the germinative tissue non-significant changes occurred. The yolk did not change morphometrically after exposure to internal cryoprotectants and showed no sign of dehydration after exposure to external cryoprotectants. Based on these results the study comes to the following conclusions: as yolk dehydration was impossible and as vitrification solutions were over the tolerance limit it seems unlikely that successful vitrification of zebrafish embryos can be achieved. Under these considerations slow freezing methods would be a better option as lower cryoprotectant concentrations can be used and embryos can be dehydrated during freezing.     

Freeze-induced membrane damage in ram spermatozoa is manifested after thawing: observations with experimental cryomicroscopy.

Cryoinjury in ram sperm was investigated by direct observation, using cryomicroscopy, to validate model hypotheses of freezing injury in such a specialized cell. Fluorescein diacetate was used to determine when during the freeze-thaw cycle the sperm membrane became permeable. In noncryoprotected sperm plasma membrane, integrity was maintained throughout the cooling and freezing process, but fluorescein leakage occurred during rewarming. The temperature of post-thaw permeabilization varied in relation to the minimum temperature reached during freezing; cells cooled to -10 degrees C retained fluorescence into the post-thaw temperature range of 9-24 degrees C (mean +/- SEM; 13.25 +/- 0.91 degrees C), whereas cells cooled to -20 degrees C lost fluorescence shortly after thawing (mean +/- SEM; 2.62 +/- 0.91 degrees C). Sperm cooled to 5 degrees C, but not frozen, retained fluorescence during rewarming up to 20-30 degrees C. The inclusion of glycerol and egg yolk in the freezing medium significantly and independently increased the post-thaw permeabilization temperature. Maintenance of fluorescence was also correlated with ability to resume motility after thawing. Sperm reactivation experiments were undertaken to examine deleterious effects of freezing upon the flagellar microtubular assembly. No direct evidence for such effects was obtained. Instead, a highly significant correlation between minimum freezing temperature and post-thaw temperature of initial reactivation was detected.     

Effect of an interaction between haematocrit and cryoprotectant concentration on freeze-thaw haemolysis of bovine erythrocytes.

The effect of the haematocrit and cryoprotectant concentration on freeze-thaw haemolysis of bovine red cells was studied. Two-milliliter samples of bovine blood with an haematocrit of either 20 or 60% were diluted with 2 ml of either 5, 4, 3, 2, or 1 m glycerol or DMSO in PBS or with PBS alone. The degree of haemolysis after freezing to ?79 °C and thawing was least in blood diluted with 4m cryoprotectant. At the lower concentrations of cryoprotectant, haemolysis was greater in blood with the higher haematocrit, but this effect decreased as the cryoprotectant concentration was increased and was negligible at the optimal concentration.