Osmotic stress as a factor in the detrimental effect of glycerol on human platelets

The aim of this work was to determine the importance of osmotic stress as a damaging factor in the detrimental effect of glycerol on human platelets. The severity of osmotic stress was mitigated by reducing the rate of change of glycerol concentration in the suspending medium. The classical permeability equations were used to predict cell volume changes in response to step changes in extracellular glycerol concentration. Protocols were devised that limited cellular shrinkage during glycerol addition and cellular swelling during glycerol dilution. When glycerol was added and diluted rapidly, the recovery of the hypotonic stress response with respect to untreated controls was unaffected by 0.25 mol/liter glycerol, but was reduced to ca. 65% after exposure to 0.5 mol/liter glycerol and to ca. 25% after exposure to 1 mol/liter glycerol. When 1 mol/liter glycerol was added and removed slowly such that cell volume remained within the range of 60-130% of normal volume, recovery of the hypotonic stress response was improved to ca. 50%, and the aggregation response was undiminished. Osmotic stress was therefore at least partly responsible for the damage caused by glycerol. However, platelets were damaged more after slow dilution from 1 mol/liter glycerol, when cellular swelling was limited to 116% of normal volume, than after rapid dilution from 0.25 or 0.5 mol/liter glycerol, which resulted in cellular swelling to 123% and 146% of normal volume, respectively. Thus, a possible toxic effect of glycerol cannot as yet be discounted.     

The effect of glycerol on aggregation and ultrastructure of human platelets

Cryopreservation of platelets depends on the use of cryoprotectants to reduce freezing damage. However, the cryoprotectants may in themselves be harmful, and it is important to determine the amount of damage caused by these compounds. Platelets were incubated at 37 °C in plasma containing 0, 0.5 and 1.0 mol/liter glycerol. The aggregation response to 10 and 5 μmol/liter ADP was determined after 2, 15, 30, 60, and 120 min of incubation. Samples were prepared for electron microscopy after 30 min at 37 °C. Glycerol at a concentration of 0.5 mol/liter had no effect on the extent of aggregation, whereas 1.0 mol/liter glycerol caused a progressive decline in the response. However, platelet ultrastructure appeared to be undisturbed by 1.0 mol/liter glycerol. The results demonstrated a lack of toxicity of 0.5 mol/liter glycerol and support the use of glycerol at concentrations less than 1.0 mol/liter for cryopreservation.     

Survival of corneal endothelium following exposure to a vitrification solution

Corneal endothelium, a monolayer of cells lining the inner surface of the cornea, is particularly susceptible to freezing injury. Ice formation damages the structural and functional integrity of the endothelium, and this results in a loss of corneal transparency. Instead of freezing, an alternative method of cryopreservation is vitrification, which avoids damage associated with ice formation. Vitrification at practicable cooling rates, however, requires exposure of tissues to very high concentrations of cryoprotectants, and this can cause damage through chemical toxicity and osmotic stress. The effects of a vitrification solution (VS1) containing 2.62 mol/liter (20.5%, w/v) dimethyl sulfoxide, 2.62 mol/liter (15.5%, w/v) acetamide, 1.32 mol/liter (10%, w/v) propane-1,2-diol, and 6% (w/v) polyethylene glycol were studied on corneal endothelium. Endothelial function was assessed by monitoring corneal thickness during 6 hr of perfusion at 35 degrees C with a Ringer solution supplemented with glutathione and adenosine. Various dilutions of the vitrification solution were introduced and removed in a stepwise manner to mitigate osmotic stress. Survival of endothelium after exposure to VS1 or a solution containing 90% of the cryoprotectant concentrations in VS1 (90% VS1) was dependent on the duration of exposure, the temperature of exposure, and the dilution protocol. The basic dilution protocol was performed at 25 degrees C: corneas were transferred from 90% VS1 or VS1 into 50% VS1 for 15 min, followed by 25% VS1 for 15 min and finally into isosmotic Ringer solution. Using this protocol, corneal endothelium survived exposure to 90% VS1 for 15 min at -5 degrees C, but 5 min in VS1 at -5 degrees C was harmful and resulted in some very large and misshapen endothelial cells. This damage was not ameliorated by using a sucrose dilution technique; but endothelial function was improved when the temperature of exposure to VS1 was reduced from -5 to -10 degrees C. Exposure to VS1 for 5 min at -5 degrees C was well tolerated, however, when the temperature of the first dilution step into 50% VS1 was reduced from 25 to 0 degree C. The large, misshapen cells were not observed under these conditions nor after exposure to VS1 at -10 degrees C. These results suggested that damage was the result of cryoprotectant toxicity rather than osmotic stress. Thus, corneal endothelium survived exposure to two solutions of cryoprotectants, namely, 90% VS1 and VS1, that were sufficiently concentrated to vitrify. Whether corneas can be cooled fast enough in these solutions to achieve vitrification and warmed fast enough to avoid devitrification remains to be determined.     

Permeability of human blood platelets to glycerol

The permeability of human platelets to glycerol was determined at 37 degrees C, 25 degrees C, and 0 degrees C from the rate of change of cell volume after abrupt addition of 0.5 mol/liter glycerol in phosphate-buffered saline. Intracellular water volume was measured employing both tritiated water and a photometric method. Intracellular glycerol was measured employing tritiated glycerol. The glycerol permeability coefficient derived from the tracer cell volume data was 4.0 +/- 0.7 X 10(-7) cm/s at 37 degrees C, and 1.1 +/- 0.4 X 10(-7) cm/s at 25 degrees C, and the photometric data gave a permeability coefficient of 5.4 +/- 0.4 X 10(-7) cm/s at 37 degrees C. The activation energy between 23 degrees C and 37 degrees C for glycerol permeation was 19.8 kcal/mol. The cells were virtually impermeable to glycerol at 0 degrees C. The minimum intracellular water volume attained after the addition of 0.5 mol/liter glycerol at 37 degrees C determined by the photometric method was 47.8% of normal water volume, whereas the minimum water volume calculated assuming that glycerol exerted its full osmotic effect (i.e., sigma = 1) was 45.6%. The reflexion coefficient was therefore assumed to be unity. Neither method of cell volume determination could be used with 1 or 2 mol/liter glycerol: adequate separation of the cells from the labeled medium could not be achieved in the tracer method; in the photometric method, it was apparent that transmittance (660 nm) was influenced by one or more variables in addition to cell volume.     

Platelet cryopreservation with glycerol, dextran, and mannitol: recovery of 5-hydroxytryptamine uptake and hypotonic stress response

Human platelets were frozen in 0.5 M glycerol, 0.5 M glycerol + 3% Dextran T40, or 0.5 M glycerol + 5% mannitol. The recovery of active transport of 5-hydroxytryptamine (5-HT) and the hypotonic stress response after freezing were dependent on the rate of cooling: the optimum range of rates was between 12 and 23 degrees C/min. The numerical recovery of cells was independent of cooling rate, but freezing altered the cell-size distribution. The combination of dextran and glycerol was no better than glycerol alone at protecting platelets against freezing damage. Mannitol, however, adversely affected platelet 5-HT uptake, and this was reflected in a low recovery of that activity after freezing platelets in glycerol supplemented with mannitol.     

Influence of extender, cryoperservative and seminal processing procedures on postthaw motility of canine spermatozoa frozen in straws

Experiments were conducted to evaluate two extenders (egg-yolk Tris and egg-yolk lactose), varying concentrations of two cryopreservatives (glycerol and dimethyl sulfoxide), and rates for cooling to 5 degrees C, cooling from 5 to -100 degrees C, and warming for canine spermatozoa packaged in 0.5-ml French straws. At optimal concentrations of glycerol, egg-yolk Tris extender was superior to egg-yolk lactose in preserving spermatozoal motility. Addition of dimethyl sulfoxide, alone or in combination with glycerol in either extender, was not beneficial to spermatozoal survival after thawing. Canine spermatozoa withstood a range of cooling and equilibration times with no detrimental effect on spermatozoal motility prior to freezing. However, there were differences in spermatozoal motility immediately after thawing; these differences were variable, resulting in a cooling time by equilibration time interaction. Spermatozoal motility after thawing was best preserved by freezing in egg-yolk Tris extender containing 2-4% glycerol, using a moderate rate of cooling from 5 to -100 degrees C (-5 degrees C/min from 5 to -15 degrees C, then -20 degrees C/min from -15 to -100 degrees C). Three of 12 bitches inseminated intravaginally with semen frozen using this protocol became pregnant.     

Cooling and freezing damage platelet membrane integrity.

Cytoskeletal rearrangements and a membrane lipid phase transition (liquid crystalline to gel) occur in platelets on cooling from 23 to 4 degrees C. A consequence of these structural alterations is irreversible cellular damage. We investigated whether platelet membrane integrity could be preserved by (a) previously studied combinations of a calcium chelator (EGTA) and microfilament stabilizer (cytochalasin B) with apparent benefit in protecting platelets from cooling injury or (b) agents of known benefit in protecting membranes and proteins from freezing injury. Platelet function and activation before and after freezing or cooling were measured by agglutination with ristocetin, aggregation with thrombin or ADP, platelet-induced clot retraction (PICR), and expression of P-selectin. Platelets were loaded with 10 nM fluorescein diacetate. After freezing or cooling, the preparations were centrifuged and the supernatant was measured for fluorescein. For cooling experiments, fresh platelets were chilled at 4 degrees C for 1 to 21 days with or without the combination of 80 microM EGTA/AM and 2 microM cytochalasin B (EGTA/AM-CytoB) and then warmed rapidly at 37 degrees C. For freezing experiments, 5% dimethyl sulfoxide (Me2SO) or 5 mM glycerol were added to fresh platelets. The preparations were then frozen at -1 degrees C/min to -70 degrees C and then thawed rapidly at 37 degrees C. Platelet membrane integrity, as measured by supernatant levels of fluorescein, correlated inversely with platelet function. Chilling platelets at 4 degrees C with EGTA/AM-CytoB showed a gradual loss of membrane integrity, with maximum loss reached on day 7. The loss of membrane integrity preceded complete loss of function as demonstrated by PICR. In contrast, platelets chilled without these agents had complete loss of membrane integrity and function after 1 day of storage. Freezing platelets in Me2SO resulted in far less release of fluorescein than did freezing with or without other cryoprotectants (P < 0.001). This result correlated with enhanced function as demonstrated by PICR and supports earlier observations that Me2SO protects platelet membranes from freezing injury. Release of fluorescein into the surrounding medium reflected loss of membrane integrity and function in both cooled and frozen platelets. Membrane cytoskeletal rearrangements are linked to membrane changes during storage. These results may be generally applicable to the study of platelet storage.     

Effect of cryoprotectants on the viability and function of unfrozen human polymorphonuclear cells

High concentrations of membrane permeable cryoprotectants are necessary to protect human polymorphonuclear leukocytes from osmotic stress injury during freezing, but there are reports that some cryoprotectants are chemically toxic. Cells were exposed to various concentrations of glycerol, dimethyl sulfoxide, or ethylene glycol for 5 min to 2 hr at 37, 22 or 0 degree C, adding or removing the cryoprotectant either slowly or rapidly. Assays included cell number recovery, membrane integrity, phagocytosis, microbicidal ability, and chemotaxis. We conclude that (1) 1 and 2 M concentrations generally are not toxic if they are added and removed slowly at 22 degrees C; (2) addition and removal of glycerol at 0 degree C was injurious even at 1 M; (3) slow addition and removal allowed better recovery than rapid addition or removal; (4) salt concentration in cryoprotectant solutions should be adjusted to isotonic on the basis of moles per liter of solution, rather than moles per kilogram of water; (5) the toxicity reported by other investigators can be largely explained by osmotic stress or dilution shock rather than chemical toxicity; and (6) ethylene glycol is the easiest cryoprotectant to add to and remove from these cells.     

The effects of osmotic stress on human platelets

The effect of osmotic stress on human platelets was investigated at 0, 25, and 37 degrees C. The osmolality of the suspending plasma was decreased by adding water or increased by adding sodium chloride or sucrose. After 5 min, isotonicity was restored by dilution with an excess of isotonic phosphate-buffered saline. After centrifugation, the platelets were resuspended in autologous plasma and then incubated for 1 hr at 37 degrees C before assaying the active transport of 5-hydroxytryptamine (5-HT) and the hypotonic stress response. Anisosmotic conditions had a greater effect on the extent of volume reversal in the hypotonic stress test than on 5-HT uptake. At 25 degrees C, only moderate degrees of hypotonicity (0.25 osmol/kg) or hypertonicity (0.59 osmol/kg) were sufficient to depress the hypotonic stress response. In general, platelets tolerated departures from isotonic conditions better at 0 degree C than at the higher temperatures. Furthermore, at 0 and 25 degrees C approximately equiosmolal concentrations of sucrose and sodium chloride depressed the hypotonic stress response to similar extents, but at 37 degrees C high osmolalities (greater than 2 osmol/kg) were tolerated better when the additive was sucrose than when it was sodium chloride. Platelets shrank when subjected to hyperosmotic conditions, but their discoid shape and the peripheral band of microtubules were maintained.     

Development of a simple sperm cryopreservation model using a chemically defined medium and goat cauda epididymal spermatozoa

This investigation was carried out to develop a simple sperm cryopreservation model using a chemically defined synthetic medium (modified Ringer's solution) and mature goat cauda epididymal sperm as the model system. Rates of cooling, freezing, and maximum freezing temperature were manipulated with the help of a computer-controlled programmable biofreezer. Highly motile goat cauda sperm dispersed in a modified Ringer's solution was subjected to the freezing protocol: cooling 0.25 degrees C min(-1) to 5 degrees C, 5 degrees C min (-1) to -20 degrees C, 20 degrees C min(-1) to -100 degrees C, prior to plunging into liquid nitrogen. In the absence of any cryoprotective agent, all of the spermatozoa lost their motility. Addition of glycerol (0.22 to 0.87 M) caused a dose-dependent increase of sperm motility recovery. The highest recovery of forward and total motility was (32 and 35%, respectively) at 0.87 M. Further increase of the glycerol concentration caused a marked decrease in motility. Changes in the cooling rate particularly before and during freezing had a notable effect on the sperm motility recovery. There was no or low recovery (0-18%) of sperm motility when the cells were transferred directly to liquid nitrogen from the initial two cooling stages. The data demonstrate the importance of all of the cooling stages in the cryopreservation of the cells. Like glycerol, dimethyl sulfoxide (Me(2)SO) and ethylene glycol also showed a dose-dependent increase in motility recovery as well as a biphasic curve of cryoprotection. At optimal concentrations, dimethyl sulfoxide (1.00 M) and ethylene glycol (1.29 M) were effective in recovering sperm motility to the extent of 20 and 13%, respectively. Thus these reagents have markedly lower cryoprotection potential than glycerol.     

Subzero water permeability parameters and optimal freezing rates for sperm cells of the southern platyfish, Xiphophorus maculatus

This study reports the subzero water transport characteristics (and empirically determined optimal rates for freezing) of sperm cells of live-bearing fishes of the genus Xiphophorus, specifically those of the southern platyfish Xiphophorus maculatus. These fishes are valuable models for biomedical research and are commercially raised as ornamental fish for use in aquariums. Water transport during freezing of X. maculatus sperm cell suspensions was obtained using a shape-independent differential scanning calorimeter technique in the presence of extracellular ice at a cooling rate of 20 degrees C/min in three different media: (1) Hanks' balanced salt solution (HBSS) without cryoprotective agents (CPAs); (2) HBSS with 14% (v/v) glycerol, and (3) HBSS with 10% (v/v) dimethyl sulfoxide (DMSO). The sperm cell was modeled as a cylinder with a length of 52.35 microm and a diameter of 0.66 microm with an osmotically inactive cell volume (Vb) of 0.6 V0, where V0 is the isotonic or initial cell volume. This translates to a surface area, SA to initial water volume, WV ratio of 15.15 microm(-1). By fitting a model of water transport to the experimentally determined volumetric shrinkage data, the best fit membrane permeability parameters (reference membrane permeability to water at 0 degrees C, Lpg or Lpg [cpa] and the activation energy, E(Lp) or E(Lp) [cpa]) were found to range from: Lpg or Lpg [cpa] = 0.0053-0.0093 microm/minatm; E(Lp) or E(Lp) [cpa] = 9.79-29.00 kcal/mol. By incorporating these membrane permeability parameters in a recently developed generic optimal cooling rate equation (optimal cooling rate, [Formula: see text] where the units of B(opt) are degrees C/min, E(Lp) or E(Lp) [cpa] are kcal/mol, L(pg) or L(pg) [cpa] are microm/minatm and SA/WV are microm(-1)), we determined the optimal rates of freezing X. maculatus sperm cells to be 28 degrees C/min (in HBSS), 47 degrees C/min (in HBSS+14% glycerol) and 36 degrees C/min (in HBSS+10% DMSO). Preliminary empirical experiments suggest that the optimal rate of freezing X. maculatus sperm in the presence of 14% glycerol to be approximately 25 degrees C/min. Possible reasons for the observed discrepancy between the theoretically predicted and experimentally determined optimal rates of freezing X. maculatus sperm cells are discussed.     

Depression of the ice-nucleation temperature of rapidly cooled mouse embryos by glycerol and dimethyl sulfoxide.

The temperature at which ice formation occurs in supercooled cytoplasm is an important element in predicting the likelihood of intracellular freezing of cells cooled by various procedures to subzero temperatures. We have confirmed and extended prior indications that permeating cryoprotective additives decrease the ice nucleation temperature of cells, and have determined some possible mechanisms for the decrease. Our experiments were carried out on eight-cell mouse embryos equilibrated with various concentrations (0-2.0 M) of dimethyl sulfoxide or glycerol and then cooled rapidly. Two methods were used to assess the nucleation temperature. The first, indirect, method was to determine the in vitro survival of the rapidly cooled embryos as a function of temperature. The temperatures over which an abrupt drop in survival occurs are generally diagnostic of the temperature range for intracellular freezing. The second, direct, method was to observe the microscopic appearance during rapid cooling and note the temperature at which nucleation occurred. Both methods showed that the nucleation temperature decreased from - 10 to - 15 degrees C in saline alone to between - 38 degrees and - 44 degrees C in 1.0-2.0 M glycerol and dimethyl sulfoxide. The latter two temperatures are close to the homogeneous nucleation temperatures of the solutions in the embryo cytoplasm, and suggest that embryos equilibrated in these solutions do not contain heterogeneous nucleating agents and are not accessible to any extracellular nucleating agents, such as extracellular ice. The much higher freezing temperatures of cells in saline or in low concentrations of additive indicate that they are being nucleated by heterogeneous agents or, more likely, by extracellular ice.     

The potential of an equimolar combination of propane-1,2-diol and glycerol as a vitrification solution for corneas

Corneas must first be equilibrated with multimolar concentrations of cryoprotectants if the formation of ice during cryopreservation is to be avoided by vitrification at practicable cooling rates. Rabbit corneas were exposed to equimolar mixtures of the cryoprotectants propane-1,2-diol and glycerol in a Hepes-buffered Ringer's solution containing glutathione, adenosine, 5 mmol/liter sodium bicarbonate, and 6% w/v bovine serum albumin. Endothelial function was assessed by monitoring its ability to control stromal hydration during perfusion of the endothelial surface at 34 degrees C for 6 h. Endothelial morphology was observed by specular microscopy during perfusion and by scanning electron microscopy after perfusion. Endothelial pump activity and structural integrity of the endothelial layer were demonstrated after 20 min exposure at 4 degrees C to a total concentration of 1.4 mol/liter cryoprotectant (i.e., 0.7 mol/liter propane-1,2-diol + 0.7 mol/liter glycerol). Exposure to 2.0 and 3.4 mol/liter cryoprotectant for 20 min at 4 degrees and -5 degrees C, respectively, resulted in initial endothelial damage; but this repaired and a functioning endothelial pump was subsequently demonstrated. Although exposure to 4.1 mol/liter cryoprotectant for 10 min at -10 degrees C caused irreparable damage to 2/4 corneas, reduced dilution temperatures together with increased dilution time allowed exposure to 4.8 and 5.5 mol/liter cryoprotectant with retention of endothelial pump activity. Exposure to 6.1 mol/liter cryoprotectant for 10 min at -15 degrees C caused endothelial damage which was not mitigated by the presence of 2.5% w/v chondroitin sulfate. Endothelial function may be improved by further modification of addition and dilution protocols or by exposure to the cryoprotectants at lower temperatures.     

Glycerol stress and platelet integrity

Platelet response to glycerol gradient was studied using a few in vitro parameters. These were platelet count, mean platelet size, platelet response to hypotonic stress (PHRS), and collagen-induced platelet aggregation. An equal volume of 1-10% (w/v) glycerol in plasma was added at once to the platelet concentrate resulting in 0.5-5% (w/v) final glycerol concentration. The concentrate was kept at 22 degrees C for 60 min. Platelets were then separated by one centrifugation and resuspended in glycerol-free plasma. A loss in platelet count was observed when the gradient of glycerol was more than 3%. This was associated with an increase in mean cell size and a reduction in aggregability. With 5% glycerol stress, a loss of 30% in cell count, an increase in 18% in cell size, and a 78% loss in aggregability was observed. Declining of PRHS was shown already with a 1% glycerol gradient and 69% of this function was suppressed by 5% glycerol stress. In other experiments, 5% glycerol was first added, them removed in 5 steps with a gradient of 1% each. When time interval between each step was less than 0.5 min, platelet loss and PRHS reduction were 17 and 47% respectively. These values were gradually improved to 4% and 11-20%, respectively, as increasing time interval up to 15 min. It was concluded that a gradient of 1% glycerol and a 15-min interval for each step minimizes the detrimental osmotic stress on platelets while glycerol is added or removed. Our findings may lead up to devising an improved protocol for platelet cryopreservation with glycerol.     

Freeze preservation of platelets using hydroxyethyl starch (HES); a preliminary report.

A comparative study has been made of platelets stored by freeze preservation following treatment with dimethyl sulfoxide (DMSO) or hydroxyethyl starch (HES) with fresh platelets and platelets stored at 4 °C for 48 hr. The indices studied were platelet recovery, pH, light microscope morphology, platelet Factor 3 (PF₃) availability and the hypotonic stress response. The DMSO preserved platelets gave a better response to hypotonic stress and incurred lesser degrees of membrane damage as demonstrated by PF₃ availability. There was however a significantly higher recovery of platelets treated with HES; with DMSO the osmotic damage inflicted during removal caused considerable lysis. Platelets frozen by DMSO or HES gave consistently better in vitro results than platelets stored at 4 °C for 48 hr. A preliminary clinical trial of HES preserved platelets has confirmed haemostatic effectiveness in vivo. HES being relatively nontoxic, platelets can be infused immediately after thawing and with minimal post thaw manipulation, thus maintaining a relatively closed system. It is concluded that cryopreservation with HES is a practical and effective means for long term platelet storage.     

Successful cryopreservation of Asian elephant (Elephas maximus) spermatozoa

Reproduction in captive elephants is low and infant mortality is high, collectively leading to possible population extinction. Artificial insemination was developed a decade ago; however, it relies on fresh-chilled semen from just a handful of bulls with inconsistent sperm quality. Artificial insemination with frozen–thawed sperm has never been described, probably, in part, due to low semen quality after cryopreservation. The present study was designed with the aim of finding a reliable semen freezing protocol. Screening tests included freezing semen with varying concentrations of ethylene glycol, propylene glycol, trehalose, dimethyl sulfoxide and glycerol as cryoprotectants and assessing cushioned centrifugation, rapid chilling to suprazero temperatures, freezing extender osmolarity, egg yolk concentration, post-thaw dilution with cryoprotectant-free BC solution and the addition of 10% (v/v) of autologous seminal plasma. The resulting optimal freezing protocol uses cushioned centrifugation, two-step dilution with isothermal 285 m Osm/kg Berliner Cryomedium (BC) with final glycerol concentration of 7% and 16% egg yolk, and freezing in large volume by the directional freezing technique. After thawing, samples are diluted 1:1 with BC solution. Using this protocol, post-thaw evaluations results were: motility upon thawing: 57.2 ± 5.4%, motility following 30 min incubation at 37 °C: 58.5 ± 6.0% and following 3 h incubation: 21.7 ± 7.6%, intact acrosome: 57.1 ± 5.2%, normal morphology: 52.0 ± 5.8% and viability: 67.3 ± 6.1%. With this protocol, good quality semen can be accumulated for future use in artificial inseminations when and where needed.     

A theoretically estimated optimal cooling rate for the cryopreservation of sperm cells from a live-bearing fish, the green swordtail Xiphophorus helleri

Sperm cryopreservation of live-bearing fishes, such as those of the genus Xiphophorus is only beginning to be studied, although these fishes are valuable models for biomedical research and are commercially raised as ornamental fish for use in aquariums. To explore optimization of techniques for sperm cryopreservation of these fishes, this study measured the volumetric shrinkage response during freezing of sperm cells of Xiphophorus helleri by use of a shape-independent differential scanning calorimeter (DSC) technique. Volumetric shrinkage during freezing of X. helleri sperm cell suspensions was obtained in the presence of extracellular ice at a cooling rate of 20 degrees C/min in three different media: (1) Hanks' balanced salt solution (HBSS) without cryoprotective agents (CPAs); (2) HBSS with 14% (v/v) glycerol; and (3) HBSS with 10% (v/v) dimethyl sulfoxide (DMSO). The sperm cell was modeled as a cylinder of 33.3 microm in length and 0.59 microm in diameter with an osmotically inactive cell volume (V(b)) of 0.6V(o), where V(o) is the isotonic or initial cell volume. By fitting a model of water transport to the experimentally determined volumetric shrinkage data, the best-fit membrane permeability parameters (reference membrane permeability to water, L(pg) or L(pg)[cpa] and the activation energy, E(Lp) or E(Lp)[cpa]) of the Xiphophorus helleri sperm cell membrane were determined. The best-fit membrane permeability parameters at 20 degrees C/min in the absence of CPAs were: L(pg)=0.776 x 10(-15)m3/Ns (0.0046 microm/min atm), and E(Lp)=50.1 kJ/mol (11.97 kcal/mol) (R2=0.997). The corresponding parameters in the presence of 14% glycerol were L(pg)[cpa]=1.063 x 10(-15)m3/Ns (0.0063 microm/min atm), and E(Lp)[cpa]=83.81 kJ/mol (20.04 kcal/mol) (R2=0.997). The parameters in the presence of 10% DMSO were L(pg)[cpa]=1.4 x 10(-15)m3/Ns (0.0083 microm/min atm), and E(Lp)[cpa]=90.96 kJ/mol (21.75 kcal/mol) (R2=0.996). Parameters obtained in this study suggested that the optimal rate of cooling for X. helleri sperm cells in the presence of CPAs ranged from 20 to 35 degrees C/min and were in close agreement with recently published, empirically determined optimal cooling rates.     

Effect of amino acids on goat cauda epididymal sperm cryopreservation using a chemically defined model system

Studies were carried out to analyze the cryoprotecting efficacy of several amino acids by use of a chemically defined synthetic medium (modified Ringer's solution) and goat cauda epididymal sperm as the model system. Motile goat cauda sperm dispersed in the synthetic medium were subjected to a freezing protocol in a computer-controlled bio-freezer, cooling 0.25 degrees C x min(-1) to 5 degrees C, 5 degrees C x min(-1) to -20 degrees C, and 20 degrees C x min(-1) to -100 degrees C, prior to being plunged into liquid nitrogen. In the absence of amino acids, sperm cells completely lost their flagellar motility. Of all the amino acids tested, l-alanine showed maximal cryoprotection potential. l-Alanine at 135 mM offered optimum cryoprotection potential: recovery of sperm forward motility and total motility were 14 +/- 2% and 19 +/- 2%, respectively. l-Glutamine, l-proline, and glycine at optimum concentration (100-150 mM) cryopreserved approx. 11-17% total motility of the sperm cells, whereas amino acids such as l-arginine, l-lysine, and l-histidine offered little cryoprotection (0-5%) to the cells. Increasing the amino acid concentration beyond the optimum level sharply decreased the recovery of the sperm motility, which therefore showed a biphasic cryoprotection profile. Addition of amino acids enhanced (approx. 7-10%) the cryoprotection efficacy of the well-known cryoprotectants glycerol and a combination of glycerol and dimethyl sulfoxide. The presence of glycerol caused a marked reduction (from 100-150 mM to 20-70 mM levels) in the optimal cryoprotective concentration of the amino acids. The combined cryoprotecting action of glycerol, dimethyl sulfoxide, and amino acids provided motility recovery as high as 52%. The observation that amino acids and dimethyl sulfoxide had an additive effect in augmenting the cryoprotecting potential of glycerol suggests that the mechanism of their action is different from that of glycerol. This cocktail of cryoprotectants may be useful for cryopreservation of semen of various species.     

Effect of cooling rate,cryoprotectant and holding time at different transfer temperatures on the survival of cryopreserved cell suspension culture (Puccinellia distans (L.) Parl.)

Reflexed saltmarsh-grass suspension cultures produced by seed callus were frozen to the liquid nitrogen temperature. Cooling rates, cryoprotectants and holding times were taken as a function of transfer temperatures. The highest survival of cells (45%) was found at a freezing rate of 1°C min^-1, without cryoprotectant treatments. The cryoprotectants (proline, dimethyl sulphoxide, glycerol), used at different concentrations and transfer temperatures, increased the survival rate. The maximum value was 78% at 12.5% (w/v) of proline with –30°C transfer temperature. Considerable improvement of viability (from 0% to 95%) among the 12.5 and 15.0% (v/v) dimethyl sulphoxide cryopreserved cells was achieved by holding them at – 20°C for 10–30 min before plunging into the liquid nitrogen. A 20 min holding time at 15.0% (v/v) glycerol level and – 30°C transfer temperature significantly enhanced the viability of the explants from 42% to 92%. Plants were successfully regenerated from cells cryopreserved with proline (w/v) and dimethyl sulfoxide (v/v) levels of 12.5 and 15.0%, respectively.     

New thermal stress test to assess the viability of cryopreserved boar sperm.

A new, rapid, thermal stress test for assessing the viability of boar semen, requiring only 45 min of incubation at 42.5 degrees C, was developed and compared with a widely used stress test of 180 min incubation at 37 degrees C. The shorter procedure was found to have the same discriminatory ability as the standard test in assessing the effects of freezing conditions on the percentage of spermatozoa remaining motile. Neither test was able to show differences in the kinetic rating of motile sperm after freezing in relation to the glycerol concentration present during freezing. However, the new test had a greater ability to distinguish the effects of different concentrations of glycerol, over the range of 0 to 6%, and to reveal different degrees of acrosomal damage sustained during freezing. The longer procedure was unable to distinguish among glycerol concentrations from 0 to 4% with respect to acrosomal damage and produced an overall lower proportion of sperm having a normal apical ridge. The new thermal stress test thus has the advantages of greater sensitivity and more rapid execution over the test hitherto in widespread use.