Cryopreservation of in vitro matured buffalo (Bubalus bubalis) oocytes by minimum volumes vitrification methods

The aim of this study was to evaluate the efficiency of the solid surface vitrification (SSV) and the cryoloop vitrification (CLV) methods to cryopreserve in vitro matured buffalo oocytes. Another objective of the work was to investigate whether the presence of cumulus cells affects the efficiency of oocyte vitrification in this species. In the SSV method, oocytes were vitrified in a solution of 35% ethylene glycol, 5% polyvinyl-pyrrolidone and 0.4% trehalose and they were warmed in a 0.3M trehalose solution. In the CLV method, oocytes were vitrified in 16.5% ethylene glycol and 16.5% dimethyl sulfoxide and warmed in decreasing concentrations of sucrose. The oocytes that survived vitrification were fertilized and cultured in vitro up to the blastocyst stage. Although high survival rates were recorded in all groups, when the oocytes were vitrified by the CLV method in the absence of cumulus cells, the survival rate was significantly (P<0.05) lower. However, the CLV gave a significantly higher cleavage rate compared to the SSV with the denuded oocytes (45% versus 26%, respectively; P<0.05), whereas no differences were found between methods with the cumulus-enclosed oocytes (14% versus 15%, respectively). Blastocysts were produced for the first time from in vitro matured oocytes that were vitrified-warmed in buffalo. Nevertheless, vitrification significantly decreased blastocyst yield, regardless of both the method employed and the presence or absence of cumulus cells.     

Production of transgenic mice from vitrified pronuclear-stage embryos.

Cryopreservation of pronuclear-stage embryos would be useful for transgenic technology and genome preservation purposes. We compared a novel vitrification technique (solid surface vitrification, SSV) with another vitrification method in straws for cryosurvival and to generate transgenic progeny from cryopreserved mouse zygotes following microinjection. The SSV solution consisted of 35% ethylene glycol (EG), 5% polyvinyl-pyrrolidone (PVP), and 0.4 M trehalose in M2 supplemented with 4 mg/ml BSA; the in straw vitrification solution was 7 M EG in M2 plus BSA. In experiment I, we compared the effect of the vitrification solutions alone, without cooling. No reduction was detected in survival and cleavage rates. In experiment II, SSV yielded a significantly higher percentage of morphologically normal zygotes (96%) that also cleaved at significantly higher rates (80%) when compared to that following "in straw" vitrification (68 and 66%, respectively). Cleavage rate in the non-vitrified control group (93%) was significantly higher than that of both vitrified groups. Following embryo transfer, there was no difference in the rate of pups obtained from the SSV, "in straw" vitrified, and control groups (97/457, 21%; 15/75, 20% and 56/209, 27%, respectively). In experiment III, SSV vitrified and fresh embryos were used for pronuclear DNA injection. Survival rate of vitrified embryos after microinjection was reduced compared to nonvitrified ones (64 vs. 72%, respectively; P < 0.05); however, development to two-cell stage was not different (76 vs. 72%, respectively). Following embryo transfer of vitrified vs. fresh microinjected embryos, in both cases 10% live pups were generated, including transgenic pups. The results demonstrated that the efficiency of generating transgenic pups from SSV vitrified pronuclear zygotes is comparable to that from fresh embryos.     

Vitrification of pronuclear-stage mouse embryos on solid surface (SSV) versus in cryotube: comparison of the effect of equilibration time and different sugars in the vitrification solution

The cryopreservation of pronuclear-stage embryos has particular importance in transgenic technology and human assisted reproductive technology (ART). The objective of this study was to improve the efficiency of cryopreservation of pronuclear-stage mouse embryos. Two vitrification methods (solid surface vitrification (SSV) vs. vitrification in cryotube) have been compared with special emphasis on the effect of the exposure of the embryos to the solutions for various times and the sugar content (trehalose, sucrose, or raffinose) of the vitrification solutions. Pronuclear-stage embryos were either exposed to 1 M dimethyl sulfoxide (DMSO) + 1 M propylene-glycol (PG) solution for 2, 5, 10, or 15 min or not exposed to this "equilibration" solution. The vitrification solutions consisted of 2.75 M DMSO and 2.75 M PG in M2 medium supplemented with 1 M trehalose (DPT), 1 M sucrose (DPS), or 1 M raffinose (DPR). In the cryotube method, groups of 15-25 embryos were transferred into a 1.8 ml cryotube containing 30 microl of DPT, DPS, or DPR. After 30 sec, the cryotubes were directly plunged into liquid nitrogen (LN(2)) and stored for 1 day to 1 month. Vitrified samples were warmed by immersing the cryotubes in a 40 degrees C water bath and then immediately diluted with 300 microl of 0.3 M trehalose, sucrose, or raffinose in M2. In the SSV method, after equilibration 15-20 embryos were exposed to DPT, DPS, or DPR solutions for around 20 sec before being dropped in 2-microl drops onto a pre-cooled (-150 to -180 degrees C) metal surface. Vitrified droplets were stored in cryovials in LN(2). Warming was performed by transferring the vitrified droplets into 0.3 M solutions of trehalose, sucrose, or raffinose at 37 degrees C, respectively. Results showed that both SSV and cryotube vitrification methods can result in high rates of in vitro blastocyst development (up to 58.3 and 68.5% with DPR, respectively), not statistically different from that of the controls (58.3 and 64.4%). Even without the equilibration step prior to vitrification, relatively high-survival rates have been achieved, except for the DPS solution. In conclusion, vitrification of pronuclear-stage mouse embryos can result in high rates of in vitro development to blastocyst, and the use of raffinose in the vitrification solution is advantageous to improve cryosurvival.     

Vitrification of Yunnan Yellow Cattle oocytes: work in progress

The objective of this study was to provide a simple cryopreservation method for oocytes from Yunnan Yellow Cattle and facilitate preservation efforts in this native Chinese breed, which is threatened by agricultural modernization. Cumulus-oocyte complexes (COCs) were collected from slaughterhouse ovaries and matured in vitro for 22-24 h, then selected for cryopreservation. Vitrification in open pulled straws (OPS) or in microdrops on a cooled metal surface (solid surface vitrification, SSV) was compared. The OPS vitrification solution consisted of 20% ethylene glycol (EG) and 20% DMSO. The SSV solution was a mixture of 35% EG, 5% polyvinyl-pyrrolidon (PVP) and 0.4 M trehalose. Vitrified and warmed oocytes were either fertilized in vitro or parthenogenetically activated. The rates of cleavage and development to blastocysts of fertilized oocytes following OPS versus SSV were not statistically different (38.3 and 12.5% versus 35.8 and 6.0%, respectively). The corresponding rates of parthenogenetic development to blastocysts were also not different (8.2 versus 3.5%, respectively). Development to blastocysts of non-vitrified controls following fertilization was significantly higher than that of the vitrified oocytes (22.6%, P < 0.05). These results demonstrate for the first time, that although both OPS and SSV procedures reduced embryonic development, Yunnan Yellow Cattle oocytes are capable of developing to blastocysts following cryopreservation.     

Cat blastocysts produced in vitro from oocytes vitrified using the cryoloop technique and cryopreserved electroejaculated semen

Oocyte preservation is still a challenge in the cat. The aim of this study was to evaluate the efficiency of oocyte vitrification in cryoloop in the domestic cat and to assess the embryonic development after IVF with cryopreserved semen. In vitro matured cat oocytes were vitrified in cryoloop after exposure to 10% ethylene glycol (EG, 0.9 M) in hepes synthetic oviductal fluid (HSOF) for 1 min, 20% EG (1.8M) in HSOF for 1 min, and 40% EG (3.6M), 10mg/ml Ficoll 70 and 0.3M sucrose in HSOF for 20s. Warmed oocytes were fertilized in vitro with frozen-thawed semen collected by electroejaculation and presumptive zygote were cultured in vitro for 10 days. Results showed that percentage of degenerated oocytes was higher (P<0.01), while cleavage rate and morulae blastocysts rate on day 6 were significantly lower (P<0.01) for vitrified oocytes than control. Blastocyst rate on day 8 was higher (P<0.01) for control oocytes than vitrified counterparts, and also developmental ability was higher (P<0.05) for non-vitrified oocytes, while the hatched blastocyst rate on day 10 was higher (P<0.05) for vitrified oocytes than control. In conclusion cat oocytes can be vitrified in cryoloop with a fairly good survival rate, cleavage rate and embryo development until pre-implantation stage.     

Effects of vitrification cryoprotectant treatment and cooling method on the viability and development of buffalo oocytes after intracytoplasmic sperm injection

In vitro matured (IVM) buffalo oocytes at the metaphase of the second meiotic division (MII) were vitrified in 20% Me(2)SO: 20% EG (v/v) and 0.5M sucrose (VA), or 35% EG (v/v), 50mg/mL polyvinylpyrrolidone (PVP), and 0.4M trehalose (VB), either on cryotops or as 2μL microdrops. The viability was assessed after warming by fluorescein diacetate (FDA) staining and all surviving oocytes were subjected to ICSI and ethanol activation. All vitrified groups had similar recovery rates but both VA groups had significantly higher survival and pronuclear formation rates than either of the VB groups. Non treated control oocytes and non cryopreserved oocytes exposed to FDA had significantly higher survival, 2nd polar body extrusion, PN and blastocyst formation rates than any of the four vitrified groups (P<0.05). In conclusion The cryotop and microdrop methods are equally effective for buffalo oocyte vitrification, and although vitrification in VA solution yielded higher rates of survival and formation of 2 pronuclei than VB, the rate of blastocyst formation was comparable for both solutions. A detailed analysis of oocytes that extruded the second polar body after ICSI and activation revealed that only a minority (7-20% of the vitrified and 46-48% of the control oocytes) also had two pronuclei, indicating that normal activation is compromised by vitrification.     

Effects of cooling and warming rates during vitrification on fertilization of in vitro-matured bovine oocytes

The purpose of this study was to clarify the relationship of cooling rates (CR) and warming rates (WR) during vitrification with postwarming viability of in vitro-matured bovine oocytes. In Experiment 1, oocytes were vitrified in a solution containing 7.2 M ethylene glycol and 1.0 M sucrose by use of open-pulled glass capillaries with five different outer diameters and were warmed by placement of the capillaries into 0.25 M sucrose solution. The capillaries of 2000-, 1400-, 1000-, 630-, and 440-mm diameters provided CR of 2000, 3000, 5000, 8000, and 12,000 degrees C/min and WR of 5000, 8000, 17,000, 33,000, and 62,000 degrees C/min, respectively. In oocytes vitrified in capillaries of 1400-mm diameter (CR, 3000 degrees C/min; WR, 8000 degrees C/min), the morphological survival rate (86% of vitrified), penetration rate (79% of inseminated), and normal fertilization rate (69% of penetrated) were higher or tended to be higher than those in the other vitrification groups. In Experiment 2, oocytes cooled at 2000, 3000, or 12,000 degrees C/min were warmed at 8000 degrees C/min, and oocytes cooled at 3000 degrees C/min were warmed at 5000, 8000, or 33,000 degrees C/min. Among these CR-WR combinations, cooling of oocytes at 3000 degrees C/min regardless of the WR resulted in higher postwarming survival. These results indicate that survival of in vitro-matured bovine oocytes after vitrification and subsequent warming is improved by a slightly rapid cooling rate in open-pulled glass capillaries compared to that obtained in conventional straws.     

New technology for vitrification and field (microscope-free) warming and transfer of small ruminant embryos

This study was designed to test the efficiency of recently developed vitrification technology followed by microscope-free thawing and transfer of sheep embryos. In a first set of experiments, in vivo derived embryos at the morula to blastocyst stage were frozen in an automated freezer in ethylene glycol, and after thawing and removal of cryoprotectants, were transferred to recipient ewes according to a standard protocol (control group). A second group of embryos were loaded into open-pulled straws (OPS) and plunged into liquid nitrogen after exposure at room temperature to the media: 10% glycerol (G) for 5 min, 10% G+20% ethylene glycol (EG) for 5 min, 25% G+25% EG for 30s; or 10% EG+10% DMSO for 3 min, 20% EG+20% DMSO+0.3M trehalose for 30s. The OPS were thawed by plunging into tubes containing 0.5M trehalose. After this rapid thawing, the embryos were directly transferred using OPS as the catheter for the transplantation process. In a second set of experiments, in vivo derived and in vitro produced expanded blastocysts were vitrified in OPS and then transferred as described above. The lambing rates recorded (59% for the conventionally cryopreserved in vivo derived embryos, 56% for the vitrified in vivo derived embryos, and 20% for the vitrified in vitro produced embryos), suggest the suitability of the vitrification technique for the transfer of embryos obtained both in vivo and in vitro. This simple technology gives rise to a high embryo survival rate and will no doubt have applications in rearing sheep or other small ruminants.     

High developmental rates of vitrified bovine oocytes following parthenogenetic activation, in vitro fertilization, and somatic cell nuclear transfer

Successful cryopreservation of mammalian oocytes would provide a steady source of materials for nuclear transfer and in vitro embryo production. Our goal was to develop an effective vitrification protocol to cryopreserve bovine oocytes for research and practice of parthenogenetic activation, in vitro fertilization, and nuclear transfer. Bovine oocytes matured in vitro were placed in 4% ethylene glycol (EG) in TCM 199 plus 20% fetal bovine serum (FBS) at 39 degrees C for 12-15 min, and then transferred to a vitrification solution (35% EG, 5% polyvinyl-pyrrolidone, 0.4 M trehalose in TCM 199 and 20% FBS). Oocytes were vitrified in microdrops on a precooled (-150 degrees C) metal surface (solid-surface vitrification). The vitrified microdrops were stored in liquid nitrogen and were either immediately thawed or were thawed after storage for 2-3 wk. Surviving oocytes were subjected to 1) parthenogenetic activation, 2) in vitro fertilization, or 3) nuclear transfer with cultured adult fibroblast cells. Treated oocytes were cultured in KSOM containing BSA or FBS for 9 to 10 days. Embryo development rates were recorded daily and morphologically high-quality blastocysts were cryopreserved for nuclear transfer-derived embryos at Day 7 or Day 8 of culture. Immediate survival of vitrified/thawed oocytes varied between 77% and 86%. Cleavage and blastocyst development rates of vitrified oocytes following in vitro fertilization or activation were lower than those of the controls. For nuclear transfer, however, vitrified oocytes supported embryonic development as equally well as fresh oocytes.     

Vitrification of goat preantral follicles enclosed in ovarian tissue by using conventional and solid-surface vitrification methods

Caprine preantral follicles within ovarian fragments were exposed to or vitrified in the presence of sucrose, dimethyl sulfoxide (DMSO), ethylene glycol (EG), or various combinations thereof. The fragments were cryopreserved by using either a conventional (CV) or a solid-surface vitrification (SSV) protocol, and the cryoprotectants were removed by equilibrating vitrified ovarian fragments in “warming solution” consisting of minimum essential medium and heat-inactivated fetal calf serum (MEM⁺) followed by washes in MEM⁺ with or without sucrose. Histological analysis of follicle integrity showed that the percentages of normal follicles in ovarian fragments vitrified in sucrose mixed with EG and/or DMSO (CV method) or mixed with EG or DMSO (SSV method) followed by washes in MEM⁺ plus sucrose were similar to those of controls (ovarian fragments fixed without previous vitrification). Unlike for MEM⁺ (supplemented or unsupplemented by sucrose) and DMSO followed by washes in the absence of sucrose, the percentages of normal follicles found after exposure to cryoprotectant did not significantly differ from that found after vitrification, indicating that follicular degeneration was attributable to a toxic effect of cryoprotectants and not to the vitrification procedure. The viability of preantral follicles after the CV and SSV procedures was investigated by using calcein-AM and the ethidium-homodimer as “live” and “dead” markers, respectively. In both tested vitrification procedures, the highest percentages of viable follicles were observed when a mixture of sucrose and EG (70.3% for CV and 72.4% for SSV) was used. Preantral follicles were also vitrified (either by CV or SSV) in sucrose and EG and then cultured for 24 h, after which their viability was compared with that of cultured fresh and uncultured vitrified follicles. The viability of these follicles was maintained after SSV, but not after CV. Thus, the viability of caprine preantral follicles can be best preserved after SSV in a mixture of sucrose and EG, followed by washes in medium containing sucrose.CAPES/Brazil supported this work. Regiane Rodrigues dos Santos is a recipient of a grant from CAPES/Brazil.     

Development of vitrified bovine secondary and primordial follicles in xenografts

The objective was to evaluate the effect of various vitrification conditions on the morphology of bovine secondary and primordial follicles, and to use xenografting to confirm their developmental ability. Secondary follicles were placed in vitrification solution containing 15% (v:v) ethylene glycol (EG), 15% (v:v) dimethyl sulfoxide (DMSO), 20% (v:v) fetal calf serum (FCS), and 0, 0.25, or 0.5 M sucrose at room temperature for 1 or 30 min, or at 4 °C for 30 min before being plunged into liquid nitrogen (LN₂). Ovarian tissues with primordial follicles were equilibrated in a solution containing 7.5% EG, 7.5% DMSO, and 20% FCS for 5 or 15 min, and then treated with a vitrification solution (15% EG, 15% DMSO, and 20% FCS) containing 0 or 0.5 M sucrose at room temperature for 1 min, and then plunged into LN₂. One week later, follicles and tissues were warmed, and morphology assessed histologically. Secondary follicles vitrified in sucrose-free solution had more oocytes with shrinkage of the nucleus and abnormal cytoplasm relative to those vitrified in sucrose-containing solution. When primordial follicles were equilibrated for 5 min and vitrified in sucrose-free solution, the percentage of morphologically normal primordial follicles was higher than in the other groups (P < 0.05). After 4 wk and 6 mo of xenografting of vitrified-warmed secondary and primordial follicles, respectively, in SCID mice, follicles developed to the antral stage and oocytes grew. In conclusion, bovine secondary follicles were successfully cryopreserved in sucrose-containing vitrification solutions and maintained their ability to develop to the antral stage and grow oocytes, whereas primordial follicles vitrified in sucrose-free solution maintained their morphology and developed to the antral stage, with oocyte growth.     

Effect of cryoprotectants and their concentration on in vitro development of vitrified-warmed immature oocytes in buffalo (Bubalus bubalis)

Experiments were conducted to study the effect of cryoprotectants, dimethyl sulfoxide (DMSO), ethylene glycol (EG), 1,2-propanediol (PROH), and glycerol at different concentrations (3.5, 4, 5, 6, and 7 M each with 0.5 M sucrose and 0.4% BSA in DPBS) on survival, in vitro maturation, in vitro fertilization, and post-fertilization development of vitrified-thawed immature buffalo oocytes. The COCs were harvested from the ovaries by aspirating the visible follicles. The recovery of post-thaw morphologically normal oocytes was lower in 3.5 and 4 M DMSO, EG, and PROH compared to 5, 6, and 7 M. In all the concentrations of glycerol, an overall lower numbers of oocytes recovered were normal compared to other cryoprotectants. Less number of oocytes reached metaphase-II (M-II) stage from the oocytes cryopreserved in any of the concentrations of DMSO, EG, PROH, and glycerol compared to fresh oocytes. Among the vitrified groups, highest maturation was obtained in 7 M solutions of all the cryoprotectants. The cleavage rates of oocytes vitrified in different concentrations of DMSO, EG, PROH, and glycerol were lower than that of the fresh oocytes. The cleavage rates were higher in oocytes cryopreserved in 6 and 7 M DMSO, EG, PROH, and glycerol compared with oocytes cryopreserved in other concentrations. However, the percentage of morula and blastocyst formation from the cleaved embryos did not vary in fresh oocytes and vitrified oocytes. In conclusion, this report describes the first successful production of buffalo blastocysts from immature oocytes cryopreserved by vitrification.     

Comparison of different vitrification protocols on viability after transfer of ovine blastocysts in vitro produced and in vivo derived

We compare different vitrification protocols on the pregnancy and lambing rate of in vitro produced (IVP) and in vivo derived (IVD) ovine embryos. Ovine blastocysts were produced by in vitro maturation, fertilization and culture of oocytes collected from slaughtered ewes or superovulated and inseminated animals. Embryos were cryopreserved after exposure at room temperature either for 5 min in 10% glycerol (G), then for 5 min in 10% G + 20% ethylene glycol (EG), then for 30 s in 25% G + 25% EG (glycerol group), or for 3 min in 10% EG + 10% dimethyl sulphoxide (DMSO), then for 30s in 20% EG + 20% DMSO + 0.3 M sucrose (DMSO group). One group of in vitro produced embryos was cryopreserved similarly to the DMSO group, but with 0.75 M sucrose added to the vitrification solution (DMSO 0.75 group). Glycerol group embryos were then loaded into French straws or open pulled Straws (OPS) while the DMSO group embryos were all loaded into OPS and directly plunged into liquid nitrogen. Embryos were warmed with either a one step or three step process. In the one step process, embryos were placed in 0.5 M sucrose. The three-step process was a serial dilution in 0.5, 0.25 and 0.125 M sucrose. The embryos of DMSO 0.75 group were warmed directly by plunging them into tissue culture medium-199 (TCM-199) + 20% foetal bovine serum (FBS) in the absence of sucrose (direct dilution). Following these manipulations, the embryos were transferred in pairs into synchronised recipient ewes and allowed to go to term. The pregnancy and the lambing rate within each group of IVP and IVD embryos indicated that there was no statistical difference among the vitrification protocols.     

Maturation rates of vitrified-thawed immature buffalo (Bubalus bubalis) oocytes: effect of different types of cryoprotectants

Cryopreservation of oocytes collected from slaughtered animals of high genetic value, their subsequent utilisation for production of embryos for transfer may provide an opportunity to replenish the valuable germplasm lost. Experiments were conducted to study the effect of cryoprotectants, dimethyl sulfoxide (DMSO), ethylene glycol (EG), 1,2-propanediol (PROH) and glycerol at different concentrations (3.5, 4, 5, 6 and 7 M each with 0.5M sucrose and 0.4% BSA in DPBS) on morphological survival and in vitro maturation of vitrified-thawed immature buffalo oocytes. The cumulus oocyte complexes were harvested from the ovaries obtained from a local slaughterhouse by aspirating the visible follicles. Less number of oocytes reached metaphase-II stage from the oocytes cryopreserved in any of the concentrations of DMSO, EG, PROH and glycerol compared to fresh oocytes. Among the vitrified groups, highest maturation (40.3, 42.5, 40.4 and 23.5%) was obtained in 7 M DMSO, EG, PROH and glycerol, respectively. Oocytes reaching to M-II stage from the oocytes cryopreserved in 7 M glycerol were significantly lower than that of the oocytes vitrified in 7 M DMSO, EG and PROH. It can be concluded that 7 M solutions of DMSO, EG and PROH can be used for vitrification of immature buffalo oocytes for subsequent utilisation of these oocytes in IVM/IVF and embryo production for transfer.     

Nonequilibrium cryopreservation of rabbit embryos using a modified (sealed) open pulled straw procedure

The study was designed to evaluate the efficiency of a modified (sealed) open pulled straw (mOPS) method for cryopreserving rabbit embryos by vitrification or rapid freezing. An additional objective was to determine whether the mOPS method could cause the vitrification of a cryoprotectant solution generally used in rapid freezing procedures. Two consecutive experiments of in vitro and in vivo viability were performed. In Experiment 1, the in vitro viability of rabbit embryos at the morula, compacted morula, early blastocyst and blastocyst stages was assessed after exposure to a mixture of 25% glycerol and 25% ethylene glycol (25GLY:25EG: vitrification solution) or 4.5 M (approximately 25% EG) ethylene glycol and 0.25 M sucrose (25EG:SUC: rapid freezing solution). Embryos were loaded into standard straws or mOPS and plunged directly into liquid nitrogen. The mOPS consisted of standard straws that were heat-pulled, leaving a wide opening for the cotton plug and a narrow one for loading embryos by capillarity. The embryos were aspirated into the mOPS in a column positioned between two columns of cryoprotectant solution separated by air bubbles. The mOPS were then sealed with polyvinyl-alcohol (PVA) sealing powder. The vitrification 25GLY:25EG solution became vitrified both in standard straws and mOPS, whereas the rapid freezing 25EG:SUC solution crystallized in standard straws, but vitrified in mOPS. The total number of embryos cryopreserved was 1695. Embryos cryopreserved after exposure to each solution in mOPS showed higher rates (88.2%) of survival immediately after thawing and removal of the cryoprotectant than those cryopreserved in 0.25 ml standard straws (78.8%; P < 0.0001). After culture, the developmental stage of the cryopreserved embryos significantly affected the rates of development to the expanded blastocyst stage. Regardless of the cryoprotectant used, lower rates of in vitro development were obtained when the embryos were cryopreserved at the morula stage, and higher rates achieved using embryos at blastocyst stages. Based on the results of Experiment 1, the second experiment was performed on blastocysts using the mOPS method. Experiment 2 was designed to evaluate the in vivo viability of cryopreserved rabbit blastocysts loaded into mOPS after exposure to 25GLY:25EG or 25EG:SUC. Embryos cryopreserved in mOPS and 25GLY:25EG solution gave rise to rates of live offspring (51.7%) not significantly different to those achieved using fresh embryos (58.5%). In conclusion, the modified (sealed) OPS method allows vitrification of the cryoprotectant solution at a lower concentration of cryoprotectants than that generally used in vitrification procedures. Rabbit blastocysts cryopreserved using a 25GLY:25EG solution in mOPS showed a similar rate of in vivo development after thawing to that shown by fresh embryos.     

Optimization of triacetate cellulose hollow fiber vitrification (HFV) method for cryopreservation of in vitro matured bovine oocytes

The aim of the current work was to evaluate applicability of triacetate cellulose hollow fiber vitrification (HFV) method for cryopreservation of groups of in vitro matured bovine oocytes (12–17 oocytes per device). We also attempted to optimize HFV protocol by altering concentration of non-permeating cryoprotectant (sucrose) in vitrification solution and concentration of extracellular Ca²⁺ by using a calcium-free base medium for preparation of vitrification/rewarming solutions with ethylene glycol (EG) as a single permeating cryoprotectant. Neither of modifications of HFV protocol significantly affected survival or fertilization rates of the vitrified bovine oocytes. Embryo development rates in the vitrification groups were lower than those in the control (31.2% of blastocysts at Day 8 post IVF). Use of vitrification/rewarming solutions with lower Ca²⁺ concentration and EG did not significantly improve embryo development rates. An increase of sucrose concentration in vitrification solution from 0.5 to 1.0 M significantly improved blastocyst yield on Day 8 post IVF (21.1–23.4% vs 3.1–3.5%; p < 0.05). Obtained results indicated that sufficient dehydration of the oocytes and/or the solution surrounding them in hollow fiber before immersion into liquid nitrogen is an important factor for successful vitrification. Use of HFV method allowed simplification and standardization of vitrification/rewarming procedures. Triacetate cellulose hollow fibers can be used successfully for cryopeservation of groups of in vitro matured bovine oocytes.     

Cryopreservation of equine embryos by open pulled straw, cryoloop, or conventional slow cooling methods

Cryopreservation of equine embryos with conventional slow-cooling procedures has proven challenging. An alternative approach is vitrification, which can minimize chilling injuries by increasing the rates of cooling and warming. The open pulled straw (OPS) and cryoloop have been used for very rapid cooling and warming rates. The objective of this experiment was to compare efficacy of vitrification of embryos in OPS and the cryoloop to conventional slow cool procedures using 0.25 mL straws. Grade 1 or 2 morulae and early blastocysts (< or = 300 microm in diameter) were recovered from mares on Day 6 or 7 post ovulation. Twenty-seven embryos were assigned to three cryopreservation treatments: (1) conventional slow cooling (0.5 degrees C/min) with 1.8 M ethylene glycol (EG) and 0.1 M sucrose, (4) vitrification in OPS in 16.5% EG, 16.5% DMSO and 0.5 M sucrose, or (3) vitrification with a cryoloop in 17.5% EG, 17.5% DMSO, 1 M sucrose and 0.25 microM ficoll. Embryos were evaluated for size and morphological quality (Grade 1 to 4) before freezing, after thawing, and after culture for 20 h. In addition, propidium iodide (PI) and Hoechst 33342 staining were used to assess percent live cells after culture. There were no differences (P > 0.1) in morphological grade or percent live cells among methods. Mean grades for embryos after culture were 2.9 +/- 0.2, 3.1 +/- 0.1, and 3.3 +/- 0.2 for conventional slow cooling, OPS and cryoloop methods, respectively. Embryo grade and percent live cells were correlated, r = 0.66 (P < 0.004). Thus OPS and the cryoloop were similarly effective to conventional slow-cooling procedures for cryopreserving small equine embryos.     

Influence of vitrification techniques and solutions on the morphology and survival of preantral follicles after in vitro culture of caprine ovarian tissue

The objective was to compare the efficiency of various vitrification techniques and solutions for preserving morphology and viability of preantral caprine follicles enclosed in ovarian tissue. Fragments of ovarian cortex were cryopreserved by conventional vitrification (CV) in French straws, vitrification in macrotubes (MTV), or solid-surface vitrification (SSV). Six solutions containing 6 M ethylene glycol, with or without sucrose (SUC; 0.25 or 0.50 M) and/or 10% fetal calf serum (FCS) were tested (Experiment I). After 1 wk, samples were warmed and preantral follicles were examined histologically. To evaluate follicular viability (Experiment II), ovarian fragments were vitrified with the three techniques listed above, in a solution containing 0.25 M SUC and 10% FCS. After warming, follicles were assessed by the trypan blue dye exclusion test. In Experiment III, preantral follicles enclosed in ovarian tissue were vitrified using the protocol which yielded the highest percentage of viable preantral follicles (SSV with 0.25 M SUC and 10% SFB). After warming, the preantral follicles enclosed in ovarian tissue were cultured in vitro and then, were analyzed by histology and fluorescence microscopy (calcein-AM and ethidium homodimer-1). Every vitrification protocol significantly reduced the percentages of morphologically normal follicles relative to the control (88.0%); however, the addition of 0.25 M SUC and 10% FCS to the vitrification solution improved preservation of follicular morphology (67.4, 67.4, and 72.0% for CV, MTV, and SSV, respectively). Although follicular viability after SSV (80.7%) did not differ from that in fresh (non-vitrified) ovarian tissues (88.0%), after in vitro culture, percentages of viable follicles were significantly reduced (70.0%). Percentages of morphologically normal follicles after in vitro culture of vitrified ovarian tissue were similar (76.0%) to those in ovarian cortex fragments cultured without previous vitrification (83.2%). In conclusion, SSV using a solution containing 0.25 M SUC and 10% FCS, was the most efficient method for vitrifying caprine ovarian tissue.     

The effect of prefreezing the diluent portion of the straw in a step-wise vitrification process using ethylene glycol and polyvinylpyrrolidone to preserve bovine blastocysts.

A total of 678 bovine blastocysts, which had been produced by in vitro maturation, fertilization, and culture, were placed into plastic straws and were vitrified in various solutions of ethylene glycol (EG) + polyvinylpyrrolidone (PVP). Part of the straw was loaded with TCM199 medium + 0.3 M trehalose as a diluent; the diluent portions of the straw were prefrozen to either -30 or -196 degrees C. Then, the embryos suspended in the vitrification solution were pipetted into the balance of the straw and vitrified by direct immersion into liquid nitrogen. For thawing, the straws were warmed for 3 s in air and 20 s in a water bath at 39 degrees C and then agitated to mix the diluent and cryoprotectant solution for 5 min followed by culture in TCM199 + 10% FCS + 5 + microg/ml insulin + 50 microg/ml gentamycin sulfate for 72 h. Variables that were examined were the time of exposure to EG prior to vitrification, the PVP concentration, and the temperature of exposure to EG + PVP prior to vitrification. Survival and hatching rates of the blastocysts exposed to 40% EG in four steps at 4 degrees C were higher than those of embryos exposed in two steps (81.3 +/- 4.3% and 80.2 +/- 3.4% vs 67.6 +/- 4.5% and 71.5 +/- 4.7%, respectively; P < 0.05). The same indices were superior following vitrification-thawing of the blastocysts in 40% EG + 20% PVP than it was in 40% EG + 10% PVP (76.1 +/- 5.5% vs 63.7 +/- 1.8%; P < 0.05; and 61.6 +/- 6.0% vs 70.5 +/- 4.7%; P < 0.01, respectively). Exposure to the vitrification solution (40% EG + 20% PVP) at higher temperatures (37.5 degrees C vs 4 degrees C) reduced both survival and hatching rates (45.8 +/- 6.9% vs 83.9 +/- 4.4% and 41.5 +/- 1.8% vs 64.0 +/- 4.7%, respectively; P < 0.001). These results indicate that blastocysts vitrified after prefreezing the diluent portions of the straws do favor developmental competence of in vitro produced embryos.