Factors affecting survival of deep frozen bovine embryos in vitro: The effect of freezing container and method of removing cryoprotectant

The effect of freezing container and method of glycerol removal on in vitro survival of frozen-thawed Day 7 bovine embryos was investigated. Two hundred and fifteen embryos were frozen in ampules or straws, in either vertical or horizontal position and at a cooling rate of 0.3 degrees C/minute from -7 degrees C to -35 degrees C, before being plunged into liquid nitrogen. Samples were thawed in a water bath at +35 degrees C and glycerol was removed by either step-wise dilution (increments 0.25 M) or by exposure to 1.0 M sucrose for 10 minutes. A total of 197 embryos was recovered post-thaw (91%) with an overall survival after 1, 3, 6 and 24 hours in culture of 87, 81, 71, and 23%, respectively. Embryonic quality and percent survival, as assessed morphologically, did not change significantly between 1 and 3 hours but decreased significantly between 6 and 24 hours in culture (p < 0.05). Survival at 24 hours was significantly higher after removal of the cryoprotectant with sucrose when compared to the step-wise glycerol dilution (p < 0.05). Overall, embryonic survival in straws equaled that in ampules; freezing orientation of straws did not affect results. Further, glycerol removal with sucrose tended to yield survival superior to that provided by a step-wise dilution technique.     

Effect of warming rate on mouse embryos frozen and thawed in glycerol

Mouse embryos (8-cell) fully equilibrated in 1.5 M-glycerol were cooled slowly (0.5 degrees C/min) to temperatures between - 7.5 and - 80 degrees C before rapid cooling and storage in liquid nitrogen (-196 degrees C). Some embryos survived rapid warming (approximately 500 degrees C/min) irrespective of the temperature at which slow cooling was terminated. However, the highest levels of survival of rapidly warmed embryos were observed when slow cooling was terminated between -25 and -80 degrees C (74-86%). In contrast, high survival (75-86%) was obtained after slow warming (approximately 2 degrees C/min) only when slow cooling was continued to -55 degrees C or below before transfer into liquid N2. Injury to embryos cooled slowly to -30 degrees C and then rapidly to -196 degrees C occurred only when slow warming (approximately 2 degrees C/min) was continued to -60 degrees C or above. Parallel cryomicroscopical observations indicated that embryos became dehydrated during slow cooling to -30 degrees C and did not freeze intracellularly during subsequent rapid cooling (approximately 250 degrees C/min) to -150 degrees C. During slow warming (2 degrees C/min), however, intracellular ice appeared at a temperature between -70 and -65 degrees C and melted when warming was continued to -30 degrees C. Intracellular freezing was not observed during rapid warming (250 degrees C/min) or during slow warming when slow cooling had been continued to -65 degrees C. These results indicate that glycerol provides superior or equal protection when compared to dimethyl sulphoxide against the deleterious effects of freezing and thawing.     

Pregnancy rate and survival in culture of in vitro fertilized bovine embryos frozen in various cryoprotectants and thawed using a one-step system

Bovine oocytes surrounded with compact cumulus cells were cultured for 20 to 22 hours (38.5 degrees C, 5% CO(2)) in modified TCM-199 medium supplemented with 5% superovulated cow serum (SCS) and inseminated by in vitro capacitated spermatozoa. Day 7 to 8 embryos were equilibrated for 10 minutes in 1.3 M methyl cellosolve (MC), 1.1 M diethylene glycol (DEG), 1.8 M ethylene glycol (EG), 1.6 M propylene glycol (PG) and 1.1 M 1, 3-butylene glycol (BG) solutions. They were then loaded into 0.25-ml straws, placed into an alcohol bath freezer at 0 degrees C, cooled from 0 degrees C to -6 degrees C at -1 degrees C/minute, seeded, held for 10 minutes, and cooled again at -0.3 degrees C or -0.5 degrees C/minute to -30 degrees C. Straws were then plunged and stored in liquid nitrogen. After thawing in 30 degrees C water, the embryos were rehydrated in TCM-199 medium and then cultured for 48 hours in TCM-199 plus 5% SCS. Embryos were considered viable if they progressed to later developmental stages with good morphology. Some of the embryos frozen in each cryoprotectant were thawed and transferred nonsurgically without removing the cryoprotectant. Hatched embryos survived freezing and one-step dilution as follows: EG (50.0%), MC (53.6%), DEG (56.9%), PG (58.0%) and BG (11.5%). The survival rate of embryos cooled at -0.3 degrees C vs -0.5 degrees C/minute was not significantly different (P>0.05), however, blastocysts hatched most often (P<0.01) in vitro when cooled at a rate of -0.3 degrees C/minute (64.6%, 31 48 ) than at -0.5 degrees C/minute (22.6%, 12 53 ). Pregnancy rates resulting from embryos frozen in the different cryoprotectants were as follows: MC (48%, 10 21 ); DEG (30%, 3 10 ); EG (74%, 20 27 ); and PG (40%, 4 10 ). These results indicate that MC, DEG, EG and PG have utility as cryoprotectants for the freezing and thawing of IVF bovine embryos.     

Commercial freezing of bovine embryos in straws

Bovine embryos were frozen commercially in clear double length $\text{1}\text{2}$ cc French straws with the wick and powder plug in the center of the straw. One-half of the double length straw serves as a handle and contains a color coded $\text{1}\text{4}$ cc straw around which an adhesive backed label has been applied. After plunging into liquid nitrogen, straws are transferred into goblets on canes while under liquid nitrogen. The straws are stored in the liquid phase of a nitrogen tank and canes containing straws are not transferred from one container to another unless the goblet containing the straws is full of liquid nitrogen.Embryos held for longer than 4 hours after collection prior to freezing showed a steady decline in pregnancy rate related to the length of time held prior to freezing. The percentage of embryos thawed and then evaluated as being transferrable was related to the quality of the embryos prior to freeze (Grade 1–93.6%, Grade 2–87.0%, Grade 3–63.8%). There was no statistical difference in pregnancy rates obtained from prefreeze Grade 1 embryos when comparing advanced blastocysts (45.2%), blastocysts (38.7%), early blastoclyst (43.1%) and advanced morula (41.6%).     

Cryoprotective effect of polyols on rat embryos during two-step freezing.

The cryoprotective effect of polyols on rat embryos was measured after two-step freezing, and the mechanism of action of polyols on embryo survival was examined. Rat embryos frozen in solution of polyol by two-step method at the morula stage showed higher survival than that obtained using DMSO. As the number of hydroxyl groups increased, the cryoprotective effect of the polyol increased. However, this was true only when the additive could permeate the cell membrane. Of the additives tested, four or five carbon polyols were most effective at concentrations of 0.3 or 1.0 M than two, three, six, or seven carbon polyols. The highest survival rate was obtained with adonitol, which yielded 83% embryo survival at 1.0 M and 67% even at 0.3 M. Embryos frozen in 0.3 M adonitol and transferred directly into foster mothers without any dilution of the additive after thawing developed into live young. During slow cooling below -40 degrees C, embryonic blastomeres exhibited cell fusion only in the presence of adonitol. These findings suggest that one cryoprotective action of polyols is that the hydroxyl groups act both on the cell surface and the cytoplasm to stabilize the bound water on the embryonic membrane, and that the length of the C-chain determines the permeability of the membrane to the additive.     

Fertility of stallion semen processed, frozen and thawed by a new procedure

The fertility of frozen-thawed and fresh semen from three stallions was compared in a trial using a randomized block design and 90 mares for 108 cycles. Semen was collected every third day, diluted to 50 x 10(6) sperm/ml with a citrate-based centrifugation medium, and centrifuged. The cells were resuspended at 700 x 10(6) progressively motile sperm/1.0 ml of added lactose-EDTA-egg yolk extender containing 4% glycerol, packaged by placing 0.55 ml into polypropylene straws, and frozen. Semen was thawed by immersion in 75 degrees C water for 10 sec. All of the 43 ejaculates collected were frozen, but 21 were discarded because progressive sperm motility was <35% immediately after thawing or <40% after 30 min of incubation at 37 degrees C. semen from the same stallions was collected daily for inseminations with fresh semen. Semen containing 200 x 10(6) progressively motile sperm was added to 10 ml of heated skimmilk extender. Mares were inseminated daily starting on the third day of estrus or when a >/=4-cm follicle was detected, whichever came later, and continuing through the end of estrus or for nine days. Based on palpation per rectum on day 50 postovulation, the pregnancy rates from inseminations during one estrus were 50, 56 and 61% with frozen semen and 67, 67 and 61% with fresh semen (P>0.05) from the three stallions, respectively. Thus, mean pregnancy rate with frozen semen was 86% of the rate attained with fresh semen.     

Pregnancy rates after transfer of frozen bovine embryos: a field trial

An efficient and practical technique for bovine embryo cryopreservation is a fundamental issue in the widespread use of embryo transfer. The present study shows results obtained in field experiments. In the first experiment, two slow-freezing methods using glycerol and a one-step method using ethylene glycol were compared: glycerol added in two steps (5 and then 10%), glycerol added in one step (10%) and 1.5 M ethylene glycol with direct transfer. The three methods were equally effective; pregnancy rates of 40.4, 39.1 and 45.4%, respectively were achieved. In the second experiment, using 1.5 M ethylene glycol with direct transfer, 20 and 5 min of equilibration of the cryoprotectant were tested. There were no observed significant differences in pregnancy rates. In the third experiment, ethylene glycol and propylene glycol were combined with three sucrose concentrations (0, 0.1 or 0.3 M) in a one-step method. It was observed that ethylene glycol and 0.1 M sucrose yielded the highest pregnancy rate, not differing from fresh controls. Similar pregnancy rates were noted after using multiple-step or one-step methods, but the one-step method is preferable due to its simplicity and applicability to field conditions.     

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 dimethylsulphoxide (DMSO) as cryoprotectant were in the range -29 degrees C to -31 degrees C and 17.5% to 20% respectively. These concentrations of DMSO are much greater than those reported in most other studies.     

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.     

A simplified method for freezing mouse embryos

Mouse oviducts containing eight-cell embryos were frozen to ?196 °C in 1.45 m DMSO. The cooling rate was 0.3 °C/min and thawing occurred at 3 °C/min. Dilution of DMSO took place either before or after flushing of the thawed oviducts. The yield of intact embryos was higher in the second group.In one particular series involving 21 donor mice (natural ovulation) 88 recovered embryos were transferred to the oviducts of recently mated pseudopregnant mice without prior in vitro culture to the blastocyst stage. Fifty-five live young were born.It is concluded that the freezing of embryos in the oviduct is a reliable method for establishing an embryo bank. Handling and collection of isolated embryos is not required and a large amount of material can be frozen at once. In vitro culturing of embryos is not required immediately after thawing in order to obtain a high yield of live young.     

Improved cryopreservation of in vitro-produced bovine embryos using a chemically defined freezing medium

This study evaluates a new synthetic substitute (CRYO3, Ref. 5617, Stem Alpha, France) for animal-based products in bovine embryo cryopreservation solutions. During the experiment, fetal calf serum (FCS) and bovine serum albumin (BSA) were used as references. A combination of a thermodynamic approach using differential scanning calorimetry and a biological approach using in vitro-produced bovine embryo slow-freezing was used to characterize cryopreservation solutions containing CRYO3, FCS and BSA. The CRYO3 and fetal calf serum (FCS) slow-freezing solutions were made from Dulbecco's phosphate-buffered saline containing 1.5 m ethylene glycol, 0.1 m sucrose and 20% (v.v⁻¹) of CRYO3 or FCS. The bovine serum albumin (BSA) solution was made by adding 0.1 m sucrose to a commercial solution containing 1.5 m ethylene glycol and 4 g L⁻¹ BSA. These solutions were evaluated using three characteristics: the end of melting temperature, the enthalpy of crystallization (thermodynamic approach) and the embryo survival and hatching rates after in vitro culture (biological approach). The CRYO3 and FCS solutions had similar thermodynamic properties. In contrast, the thermodynamic characteristics of the BSA solution were different from those of the FCS and CRYO3 solutions. Nevertheless, the embryo survival and hatching rates obtained with the BSA and FCS solutions were not different. Similar biological properties can thus be obtained with slow freezing solutions that have different physical properties within a defined range. The embryo survival rate after 48 h of in vitro culture obtained with the CRYO3 solution (81.5%) was higher than that obtained with the BSA (42.2%, P = 0.000 12) and FCS solutions (58%, P = 0.016). Similarly, the embryo hatching rate after 72 h of in vitro culture was higher with the CRYO3 solution (61.1%) than with the BSA (31.1%, P = 0.0055) and FCS solutions (36%, P = 0.018). We conclude that CRYO3 can be used as a chemically defined substitute for animal-based products in in vitro-produced bovine embryo cryopreservation solutions.     

Plasmid transformation of frozen and thawed bacteria]

Plasmid DNA transformation efficiency depends on three essential factors: 1) the optimal regime of the recipients freezing-thawing; 2) the period of the recipients competence preservation; 3) individual sensitivity of microorganisms to freezing-thawing. It is demonstrated that plasmid DNA pMB9 activity indices are of maximal value during freezing at -70 degrees C or -196 degrees C and thawing at 42 degrees C. The short period of the competence, about 15 seconds, determines the rate of its infection. In this case it was achieved by mutual freezing-thawing of bacteria and DNA pMB9. The optimal yield of transformants is obtained in the following conditions: the concentration of bacteria - 1 - 5.10(9) cells/ml, the concentration of DNA pMB9 - 0.05--0.5 mcg/ml in the reaction mixture containing 0.5--1% of bactopeptone ("Spofa") and at pH 7.4--7.6.     

Fertility evaluation of frozen/thawed semen

In vitro semen analyses have been used for more than half a century to estimate the fertilizing potential of a semen sample. Unfortunately, none of the assays developed provide results that consistently correlate well with fertility. The reasons for this lack of consistency, due in part to the complexity of the spermatozoon itself, the collection of fertility data, and factors beyond control of the semen analyses themselves, are discussed. Different spermatozoal attributes that are necessary for a spermatozoon to fertilize an oocyte are presented and assays used to evaluate each attribute described. Although laboratory assay results do not correlate well with semen fertility, the importance of conducting laboratory assays on every semen sample used for artificial insemination or to attempt to determine causes for infertility, is discussed.