Effect of different cryoprotectants and transfer temperatures on the survival rate of hemp (Cannabis sativa L.) cell suspension in deep freezing

Adequate cell dehydration is the precipitating element in the successful cryopreservation of plant cells and organs. This could be achieved by using different cooling rates, transfer temperatures and cryoprotectants. Experiments were performed to determine these critical points in the freeze preservation procedure of Cannabis sativa (L.) suspension cultures. The explants were frozen at a cooling rate of 2 degrees C/min, while the transfer temperatures were -10 degrees C, -20 degrees C, -30 degrees C, -40 degrees C and -50 degrees C. The applied cryoprotectants were the DMSO, glycerol, proline and PEG in different concentration. The highest viability (58%) was obtained by using 10% DMSO and at -10 degrees C transfer temperature. The optimum transfer temperature varied remarkably by different cryoprotectant concentrations indicating the importance of their interactions.     

Preservation of rat bone marrow with dimethylsulphoxide at -150 degrees C.

The authors tested preserving properties of three concentrations of dimethylsulphoxide (15%, 10% and 7.5%) in preservation of rat bone marrow cells at -150 degrees C. Cells of rat bone marrow were frozen at 1 degree C/min to -20 degrees C, 5 degrees C/min to -80 degrees C and then placed directly at -150 degrees C and held at such temperature for 6 months. Vitality of cells was checked monthly for a period of 6 months by means of several vitality tests with dyes (eosin and trypane blue), autoradiography and erythrophagocytosis. It was found that cells capable of cleavage could be equally preserved at such low temperature with all the three DMSO concentrations while mature cells (granulocytes, reticular cells) revealed considerably higher erythrophagocytic activity when preserved at 15% DMSO and lower activity at 10% and 7.5% DMSO.     

A method for freezing bovine lymphocytes

A simple two-stage technique for preserving bovine lymphocytes is described. Lymphocytes from animals chosen at random were used. The experiments indicate that the optimum temperature for freezing and the optimum concentration of dime-thylsulphoxide (DMSO) as cryoprotectant were in the range -29 °C to -31 °C and 17.5 % to 20 % respectively. These concentrations of DMSO are much greater than those reported in most other studies.     

Solvent-free enzymatic synthesis of alitame precursor using eutectic substrate mixtures

N-benzyloxycarbonyl-L-aspartic acid ethyl ester-D-alanine amide, a derivative of alitame, was synthesized from a eutectic mixture of the substrates N-benzyloxycarbonyl-L-aspartic acid diethyl ester and D-alanine amide using alpha-chymotrypsin. The hydrophilic solvents DMSO and MEA were found to be the best adjuvants for formation of a eutectic substrate mixture. A low eutectic temperature of 27 degrees C was obtained for the substrate mixture containing 9% DMSO, 18% MEA, and 12% water. Under these conditions a conversion yield of 70.3% (mol/mol) was obtained at 37 degrees C. The optimum molar ratio of the acyl acceptor D-alanine amide and the acyl donor N-benzyloxycarbonyl-L-aspartic acid diethyl ester was 1:1.     

Structural and catalytic response to temperature and cosolvents of carboxylesterase EST1 from the extremely thermoacidophilic archaeon Sulfolobus solfataricus P1

The interactive effects of temperature and cosolvents on the kinetic and structural features of a carboxylesterase from the extremely thermoacidophilic archaeon Sulfolobus solfataricus P1 (Sso EST1) were examined. While dimethylformamide, acetonitrile, and dioxane were all found to be deleterious to enzyme function, dimethyl sulfoxide (DMSO) activated Sso EST1 to various extents. This was particularly true at 3.5% (v/v) DMSO, where k(cat) was 20-30% higher than at 1.2% DMSO, over the temperature range of 50-85 degrees C. DMSO compensated for thermal activation in some cases; for example, k(cat) at 60 degrees C in 3.5% DMSO was comparable to k(cat) at 85 degrees C in 1.2% DMSO. The relationship between DMSO activation and enzyme structural characteristics was also investigated. Nuclear magnetic resonance spectroscopy and circular dichroism showed no gross change in enzyme conformation with 3.5% DMSO between 50 and 80 degrees C. However, low levels of DMSO were shown to have a small yet significant change in enzyme conformation. This was evident through the reduction of Sso EST1's melting temperature and changes in the microenvironment of the enzyme's tyrosine and tryptophan residues at 3.5% versus 1.2% (v/v) solvent. Finally, activation parameter analysis based on kinetic data, at 1.2% and 3.5% DMSO, implied an increase in conformational flexibility with additional cosolvent. These results suggest the activating effect of DMSO was related to small changes in the enzyme's structure resulting in an increase in its conformational flexibility. Thus, in addition to their use for solubilizing hydrophobic substrates in water, cosolvents may also serve as activators in applications involving thermostable biocatalysts at sub-optimal temperatures.     

A differential scanning calorimetric study of the conformational transitions of schizophyllan in mixtures of water and dimethylsulfoxide

The thermal conformational transitions of two sonicated samples of schizophyllan were studied in water-dimethylsulfoxide (DMSO) mixtures by high-sensitivity differential scanning calorimetry (DSC). Two transitions were observed over most of the range of solvent compositions. These were assigned to an internal change of the triple helix [T. Itou et al. (1986) Macromolecules 19, 1234-1240] and a triple-helix-single-coil transition [T. Sato et al. (1981) Carbohydr. Res. 95, 195-204], respectively. In water, the former transition observed at lower temperature for a low molecular weight sample, U-1, is centered at 3 degrees C and characterized by the specific enthalpy, delta hcal = 3.29 J g-1. A higher molecular weight sample, M-2, showed this transition at 7 degrees C with delta hcal = 4.39 J g-1. The transition temperature for both samples increased with increasing DMSO concentration up to about 50 degrees C at 70 weight % DMSO, and then rapidly decreased with increasing DMSO concentration, with about 3 degrees C higher for M-2 than for U-1 over the DMSO concentration. The transition was not observed when the concentration of DMSO exceeded 87%. It was found that delta hcal for both samples was a linear function of t 1/2, the temperature of half-completion in degrees C, delta hcal = 0.177t + 2.96. The triple helix-coil transition was observed at around 127 degrees C for U-1 and above 130 degrees C for M-2 in the range of DMSO composition below about 70%. The transition temperature decreased with increasing DMSO concentration at above 70%, and the transition finally disappeared when the DMSO concentration exceeded 90%. The plot of delta hcal vs. t 1/2 for the transition of both samples gave a linear relation, delta hcal = 0.253t - 10.58. The reversibility of the transition at lower temperature was demonstrated by the reversibility of the curves when the first heating was stopped before the second transition. Once the heating was performed over the second transition, the reheating DSC curves showed several endothermic peaks, indicating the irreversibility of the transition and heterogeneity in the conformation of the heated schizophyllan.     

Refrigerated storage and cryopreservation of black drum (Pogonias cromis) spermatozoa

Procedures were developed for the collection, refrigerated storage and cryopreservation of black drum spermatozoa. Sperm samples were collected by removing and slicing the testis, and suspending the spermatozoa in Hanks' balanced salt solution (HBSS) at 200 mOsm/kg. Threshold activation (10%) of black drum spermatozoa occurred at 370 mOsm/kg, and complete activation occurred at 580 mOsm/kg in HBSS. Sperm cells activated in artificial seawater had higher motility than those activated in HBSS at osmolalities from 350 to 500 mOsm/kg. Spermatozoa stored at 4 degrees C in HBSS or artificial seawater at osmolalities from 202 to 290 mOsm/kg retained motility longer than did those stored at other osmolalities Dilution rate had no effect on sperm storage time at 4 degrees C. Four chemicals were evaluated as cryoprotectants: dimethyl sulfoxide (DMSO), n,n-dimethyl acetamide (DMA), methanol, and glycerol. Glycerol and DMA at concentrations of 10% significantly reduced motility within 52 min. Spermatozoa were cryopreserved at 3 freezing rates (-27, -30, or -45 degrees C/min) in a nitrogen vapor shipping dewar or a computer-controlled freezer. Spermatozoa frozen using 10% DMSO had the highest post-thaw motility at a freezing rate of -27 or -30 degrees C/min. Spermatozoa frozen using 5% glycerol, 5% DMSO, or 10% DMSO had the highest post-thaw motility at a freezing rate of -45 degrees C/min.     

Comparison of stem cell viability of bone marrow cryopreserved by two different methods

Two different cryogenic methods were used to study the preservation of murine bone marrow cells. Compared to the classical methods, in which separated mononuclear marrow cells in 10% dimethyl sulfoxide (DMSO) were cryopreserved in liquid nitrogen (-196 degrees C), a modified technique was carried out by cryopreservation of unfractionated marrow cells in a mixed protectant of 5% DMSO and 6% hydroxyethyl starch (HES) at -80 degrees C. Samples that were separately thawed after storage for 1, 4, 8, and 12 weeks were assayed for cell viability and recovery of CFU-GM and CFU-S. No macroscopic clumping of cells was noted either in fractionated or in unfractionated marrow cell cryopreservations. A mild damage, about 25% reduction of stem cells, was found at 1 week and did not deepen further. It seems that the greatest loss of stem cells occurred in the process of cryopreservation itself. Compared to prefreeze values, both a high number of cells that excluded trypan blue (87 +/- 3.4%) and a high recovery of CFU-GM (75 +/- 9.8%) and CFU-S (74 +/- 11.2) were observed in unfractionated marrow samples cryopreserved with the DMSO/HES mixture at -80 degrees C for 3 months and these results were very similar to those obtained from fractionated mononuclear marrow cells cryopreserved at -196 degrees C. The DMSO/HES protectant provides a simplified bone marrow cryopreservation technique that should be favorable to clinical application because of its high stem cell recovery and avoidance of cell-separation manipulation.     

Solution stability of salmon calcitonin at high concentration for delivery in an implantable system.

Salmon calcitonin solutions (50 mg/mL and 100 mg/mL) were placed on stability at 37 degrees C for 1 year in a variety of solvent systems including water, ethanol, glycerol, propylene glycol (PG) and dimethyl sulfoxide (DMSO). Calcitonin degradation was monitored by RP-HPLC and size-exclusion chromatography. DMSO and pH 3.3 solutions provided optimum stability. Conformational stability was also monitored by FTIR over the 1 year time course and compared with chemical and physical stability. After 12 months at 37 degrees C, four major conformations were observed: a beta-sheet conformation (pH 3.3, pH 5.0, 70% DMSO and 70% glycerol), an aggregate conformation (pH 7.0 water), a strong alpha-helical conformation (70% EtOH, 70% PG) and a weak alpha-helical conformation (100% DMSO). No correlation between structure and chemical stability was observed in which both the beta-sheet structure (pH 3.3, water) and a loose alpha-helical structure (100% DMSO) demonstrated good stability. However, some correlation was observed between structure and physical stability, where co-solvents inducing an alpha-helical structure resulted in a decrease in gelation. These two structural states associated with improved stability and minimal gelation, indicated that gelation can be reduced or eliminated by the use of pharmaceutically acceptable co-solvents. Finally, salmon calcitonin (50 mg/mL) was formulated in 100% DMSO and delivered from a DUROS implant over 4 months. Delivery at a target dose of 18 microg/day calcitonin at 37 degrees C was confirmed.     

Development of a cryopreservation protocol for long-term storage of black tiger shrimp (Penaeus monodon) spermatophores

The objectives of this study were to determine the effect of cryoprotectants on sperm viability and develop a freezing protocol for long-term storage of P. monodon spermatophores. Spermatophores suspended for 30 min in calcium-free saline (Ca-F saline) containing the cryoprotectants dimethyl sulfoxide (DMSO), ethylene glycol (EG), 1,2-propylene glycol (PG), formamide, and methanol at concentrations of 5, 10, 15, or 20% were studied using a modified eosin-nigrosin staining technique. The smallest reductions in apparent sperm viability occurred with DMSO; therefore, a freezing protocol was developed using Ca-F saline containing 5% DMSO. Spermatophores were cryopreserved using three protocols; cooling to a final temperature of -30, -80 or -80 degrees C and immediately stored in liquid nitrogen (cooling rates of -2, -4, -6, -8, -10, -12, -14 or -16 degrees C/min). Frozen spermatophores were thawed (2 min) at 30, 60, 70, or 90 degrees C. Successful cryopreservation of spermatophores in liquid nitrogen was achieved by a one-step cooling rate of -2 degrees C/min between 25 and -80 degrees C before storing in liquid nitrogen. Optimal thawing was in a 30 degrees C water bath for 2 min; this yielded live sperm after storage in liquid nitrogen for 210 days. Average sperm viability for fresh (97.8+/-2.9%) and cryopreserved spermatophores held for less than 60 days (87.3+/-4.1%) did not differ (P>0.05); however, that for spermatophores stored in liquid nitrogen between 90 and 210 days were lower (P<0.05) and varied from 27.3+/-3.4 to 53.3+/-4.3%. Thawed spermatophores previously held in liquid nitrogen for less than 62 days fertilized eggs (fertilization and hatching rates of 71.6-72.2% and 63.6-64.1%, respectively) at rates comparable to fresh spermatophores (70.8-78.2% and 66.3-67.8%, respectively). In conclusion, sperm within cryopreserved spermatophores stored in liquid nitrogen retained their viability for up to 210 days.     

Unfractionated human marrow cell cryopreservation using dimethylsulfoxide and hydroxyethyl starch

Unfractionated bone marrow (BM) cells were cryopreserved in 1- to 2-ml aliquots using a mixture containing both 5% dimethylsulfoxide (DMSO) and 6% hydroxyethyl starch (HES) in an attempt to increase the viable cell yield and reduce the clumping after thawing, observed when 10% DMSO is used alone. Samples thawed after storage for 6 months in the vapor phase of liquid nitrogen, were assayed. Compared to prefreeze values, there was both a greater number of cells that excluded Trypan Blue (50 +/- 12 vs 28 +/- 12%, P less than .01) and a greater CFU-C Recovery (110 +/- 20 vs 89 +/- 35%, P less than .02) for cells in the DMSO/HES mixture, compared to those in 10% DMSO alone. No macroscopic clumping of the thawed cells was observed for those cryopreserved in the mixture in contrast to those in DMSO alone. Freezing was done without a rate-controlled freezing apparatus by simply placing the samples initially into a -80 degrees C freezer, and then later into a liquid nitrogen freezer. Additional samples stored in the DMSO/HES mixture were kept at only -80 degrees C, and when thawed 12 to 16 months later also gave an excellent CFU-C recovery (105 +/- 39% of prefreeze). The DMSO/HES mixture allows for a simplified BM cryopreservation technique that not only assures excellent recovery of CFU-Cs and eliminates clumping upon thawing, but also does not require either the use of a rate-controlled freezer or liquid nitrogen temperatures for storage up to a year.     

Nucleation and growth of ice crystals inside cultured hepatocytes during freezing in the presence of dimethyl sulfoxide.

A three-part, coupled model of cell dehydration, nucleation, and crystal growth was used to study intracellular ice formation (IIF) in cultured hepatocytes frozen in the presence of dimethyl sulfoxide (DMSO). Heterogeneous nucleation temperatures were predicted as a function of DMSO concentration and were in good agreement with experimental data. Simulated freezing protocols correctly predicted and explained experimentally observed effects of cooling rate, warming rate, and storage temperature on hepatocyte function. For cells cooled to -40 degrees C, no IIF occurred for cooling rates less than 10 degrees C/min. IIF did occur at faster cooling rates, and the predicted volume of intracellular ice increased with increasing cooling rate. Cells cooled at 5 degrees C/min to -80 degrees C were shown to undergo nucleation at -46.8 degrees C, with the consequence that storage temperatures above this value resulted in high viability independent of warming rate, whereas colder storage temperatures resulted in cell injury for slow warming rates. Cell damage correlated positively with predicted intracellular ice volume, and an upper limit for the critical ice content was estimated to be 3.7% of the isotonic water content. The power of the model was limited by difficulties in estimating the cytosol viscosity and membrane permeability as functions of DMSO concentration at low temperatures.     

Improved catalytic performance of Bacillus megaterium epoxide hydrolase in a medium containing Tween-80

A new epoxide hydrolase with high enantioselectivity toward (R)-glycidyl phenyl ether (R-GPE) was partially purified from Bacillus megaterium strain ECU1001. The maximum activity of the isolated enzyme was observed at 30 degrees C and pH 6.5 in a buffer system with 5% (v/v) of DMSO as a cosolvent. The enzyme was quite stable at pH 7.5 and retained full activity after incubation at 40 degrees C for 6 h. Interestingly, when the cosolvent DMSO was replaced by an emulsifier (Tween-80, 0.5% w/v) as an alternative additive to help disperse the water-insoluble substrate, the apparent activity of the epoxide hydrolase significantly increased by about 1.8-fold, while the temperature optimum shifted from 30 to 40 degrees C and the half-life of the enzyme at 50 degrees C increased by 2.5 times. The enzymatic hydrolysis of rac-GPE was highly enantioselective, with an E-value (enantiomeric ratio) of 69.3 in the Tween-80 emulsion system, which is obviously higher than that (41.2) observed in the DMSO-containing system.     

Cryopreservation of sperm from the marine shrimp Sicyonia ingentis

Sperm from a marine shrimp, Sicyonia ingentis, were frozen to -196 degrees C using a variety of cooling rates and cryoprotectants. A cooling rate of 1 degree C/min resulted in minimal cell breakage. Sperm samples were frozen in solutions of known membrane stabilizers--trehalose, sucrose, proline, and glycerol. These compounds were somewhat effective but a dramatic increase in sperm viability was seen when DMSO was present in the freezing medium. Sperm viability was assessed using the in vitro acrosome reaction technique of Griffin et al. (1987). The highest sperm survival (56%) was obtained with samples frozen at 1 degrees C/min in a 5% (v/v) DMSO solution. No decrease in viability was seen in sperm samples stored in liquid nitrogen (-196 degrees C) for 1 month.     

Survival of 16-celled and morula stage rabbit embryos frozen to -196 degrees C,.

Preimplantation stage (16-celled and morula) rabbit embryos were successfully frozen to -196 degrees C. The cooling rate (from a room temperature to 0 degrees C), the presence of the mucin layer surrounding embryos, the ice-seeding treatment and the thawing procedure were examined to determine their effects on the survival of the frozen embryos of Japanese white, New Zealand white and Dutch-Belted rabbits. A high proportion (51%; 16-celled, 69%; morula) of Dutch-Belted rabbit embryos developed in vitro, when they were frozen to -196 degrees C, applying the ice-seeding at -4 degrees C in the presence of 12.5% DMSO, after being cooled to 0 degrees C at the rate of 7-9 degrees C/min, and were diluted by a stepwise addition of 4 different strength PBS on thawing. The highest rate of in vitro development (81%; Japanese white, 75%; New Zealand white, 82%; Dutch Belted embryos) was obtained when the morula stage embryos were frozen to -196 degrees C applying seeding at -4 degrees C after being cooled to 0 degrees C at the rate of 1 degrees C/2.5 min and were diluted, on thawing, by stepwise addition of 6, 3 and 1% DMSO solution and a culture medium. No great difference was found in the survival rate between the embryos covered with the mucin layer and those which had not the coat. All the embryos frozen without applying seeding treatment failed to develop in vitro after being thawed and diluted. Nine out of 27 does each of which received 6 reimplantations of the embryos frozen-thawed became pregnant and were found to be carrying 37 normal fetuses on the 12th day of pregnancy.     

Freeze-induced phase transitions in the plasma membrane of isolated protoplasts

Protoplasts were enzymically isolated from 2-week-old non-acclimated rye ( Secale cereale L. cv. Puma) seedlings. They were resuspended in isotonic sorbitol with different concentrations (0–10%) of dimethyl sulfoxide (DMSO). The survival of the protoplasts frozen in isotonic sorbitol solutions declined at temperatures below the freezing point with the LT₅₀ being -8°C. Addition of DMSO to the osmoticum increased survival at freezing temperatures. The optimum concentration of DMSO was 4% and lowered the LT₅₀ to -19°C. Freeze-fracture studies of the plasma membrane revealed aparticulate lipid lamellae at -4°C, but the first appearance of lateral phase separations, striations and inverted cylindrical micelles (hexagonal₁₁-type structures) occurred at -6°C. At lower temperatures, -8 and -10°C, the occurrence of nonbilayer structures became more common. The addition of DMSO decreased the incidence of the ultrastructural changes. With 2 or 4% DMSO, non-bilayer structures were not observed at temperatures above -10°C. Instead, striations and H₁₁-type structures were observed at - 15 and -20°C.     

Cryopreservation of tench, Tinca tinca, sperm: Sperm motility and hatching success of embryos

The aim of the present study was to elaborate cryopreservation methods for ex situ conservation of tench. Success of cryopreservation was tested during two series of experiments. The first set of experiments studied the effects of two types of cryoprotectants (DMSO and a combination of DMSO with propanediol at ratio 1:1) at concentrations of 8 and 10% and three different equilibration times in two different immobilization solutions (IS) (Kurokura 180 and Kurokura) before freezing (0.0, 2.0 and 4.0h after T(0)). The K4 cooling programme was used to freeze 1ml of cryoextended sperm using 1.8ml cryotubes. Main monitored parameter was hatching rate after using of cryopreserved sperm. The second set of experiments studied the volume effect of 0.5, 1 and 5ml straws and compared these with 1.8ml cryotubes as well as the effect of the cooling programme (K4 and L1). Following the results of the first study, a combination of DMSO and propanediol (ratio 1:1) at concentration of 10% was added to extended sperm in Kurokura 180 IS. Main monitored parameter was hatching rate after using cryopreserved sperm, supplementary parameters were sperm velocity and motility percentage assessed at 10s post-activation. Sperm was collected directly into IS and stored at 4 degrees C for 2.5h. Thereafter were sperm samples pooled, equlibred in IS (first set of experiments) or directly mixed with cryoprotectants (DMSO or a mixture of DMSO with propanediol at ratio 1:1) and transferred to 1.8ml cryotubes or straws (0.5, 1 and 5ml). Then the cryotubes/straws were directly transferred to pre-programmed PLANER Kryo 10 series III and cooled using two different cooling programmes including a slow cooling programme (a) named K4 (from +4 to -9 degrees C at a rate of 4 degrees Cmin(-1) and then from -9 to -80 degrees C at a rate of 11 degrees Cmin(-1)) and a rapid cooling programme (b) named L1 (directly from +4 to -80 degrees C at a rate of 20 degrees Cmin(-1)). Both slow (K4) and rapid (L1) cooled samples were held 6min at -80 degrees C. Finally, samples were transferred into liquid N(2). The frozen spermatozoa were thawed in a water bath (40 degrees C) according to the frozen volume and checked for fertilization and hatching rates. Percentage of sperm motility and sperm velocity were measured using video recorded frames. ANOVA showed a significant influence of frozen and fresh sperm in all treatments. The hatching rates of 33.8% were obtained when sperm was equilibrated for 0h before freezing in IS of Kurokura 180 and frozen with a 10% of mixture 1:1 of DMSO and propanediol into straws of 5ml and cooled using program L1. The velocity of frozen-thawed spermatozoa ranged from 31 to 46microms(-1) and in post-thawed sperm was not significantly different according to frozen sperm volume, but a higher velocity was obtained when sperm was fast frozen using programme L1. A large volume of frozen sperm could reveal the best procedure for freezing, but also for simulating methods of artificial propagation for future practical use of frozen tench sperm at a large scale.     

Effects of cooling on meiotic spindle structure and chromosome alignment within in vitro matured porcine oocytes

Meiotic spindle structure and chromosome alignment were examined after porcine oocytes were cooled at metaphase II (M II) stage. Cumulus-oocyte complexes (COCs) collected from medium size follicles were cultured in an oocyte maturation medium at 39 degrees C, 5% CO(2) in air for 44 hr. At the end of culture, oocytes were removed from cumulus cells and cooled to 24 or 4 degrees C for 5, 30, or 120 min in a solution with or without 1.5 M dimethyl sulfoxide (DMSO). After being cooled, oocytes were either fixed immediately for examination of the meiotic spindle and chromosome alignment or returned to maturation medium at 39 degrees C for 2 hr for examination of spindle recovery. Most oocytes (65-71%) cooled to 24 degrees C showed partially depolymerized spindles but 81-92% of oocytes cooled at 4 degrees C did not have a spindle after cooling for 120 min. Quicker disassembly of spindles in the oocytes was observed at 4 degrees C than at 24 degrees C. Cooling also induced chromosome abnormality, which was indicated by dispersed chromosomes in the cytoplasm. Limited spindle recovery was observed in the oocytes cooled to both 4 and 24 degrees C regardless of cooling time. The effect of cooling on the spindle organization and chromosome alignment was not influenced by the presence of DMSO. These results indicate that the meiotic spindles in porcine M II oocytes are very sensitive to a drop in the temperature. Both spindle and chromosomes were damaged during cooling, and such damage was not reversible by incubating the oocytes after they had been cooled.     

Fast freezing of cow embryos in French straws with an automatic program

Cow embryos between day 6.5 and 9 were frozen in 1.5M DMSO in PBS at 2 degrees C/min from seeding to -25 degrees C before being plunged into liquid nitrogen directly or after 10 min at -25 degrees C. Cooling rate from 20 degrees C to -5 degrees C was 9 degrees C/min. Seeding was induced automatically at -5 degrees C by injection of liquid nitrogen vapour. Embryos were subsequently thawed by direct transfer to water at 20 degrees C (group I) or at 37 degrees C (group II). Survival was assessed by culture in vitro and by transfer. In group I, 35.7% were degenerated after thawing (compared to 35.4% in group II). Survival rate after culture in vitro for 24h was not significantly different (48.3% vs 42.8%) and hatching rate after 96h culture was quite similar (33.3% vs 34.4%). In group II, four pregnancies were obtained from 10 embryos transferred. Time at -25 degrees C did not improve the results. Automatic seeding did not impair survival. These results show that the quality of the embryo is the determinant factor for survival after freezing and that the plastic straw is the most suitable vessel for freezing, storage and transfer of embryos.     

Semen cryopreservation of small abalone (Haliotis diversicolor supertexa)

Methods for cryopreserving spermatozoa and maximizing fertilization rate in Taiwan small abalone, Haliotis diversicolor supertexa, were developed. The gametes (spermatozoa and eggs) of small abalone were viable 3 h post-spawning, with fertilization, and development rate decreasing with time. A minimum of 10(2) cell/ml sperm concentration and a contact time of 2 min between gametes is recommended for artificial insemination of small abalone eggs. Eight cryoprotectants, dimethyl sulfoxide (DMSO), dimethyl acetamide (DMA), ethylene glycol (EG), propylene glycol (PG), butylene glycol (BG), polyethylene glycol, glycerol and methanol, were tested at concentrations between 5 and 25% to evaluate their effect on motility of spermatozoa exposed to cryoprotectant for up to 60 min at 25 degrees C before freezing. The least toxic cryoprotectant, 10% DMSO, was added to artificial seawater (ASW) to formulate the extender for freezing. Semen was diluted 1:1 with the extender, inserted into 1.5 ml microtubes and frozen using a cooling rate between -3.5 and -20 degrees C/min to various transition temperatures (0, -30, -60, -90 and -120 degrees C), followed by transfer and storage in liquid nitrogen (-196 degrees C). The microtubes were thawed from +45 to +145 degrees C/min. Spermatozoa, cooled to -90 degrees C at a cooling rate of -12 or -15 degrees C/min and then immersed in liquid nitrogen, had the best post-thaw motility. Post-thaw sperm motility was markedly reduced compared to fresh sperm. More frozen-thawed spermatozoa are required to achieve fertilization rates comparable to those achieved using fresh spermatozoa.