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.     

Vitrification of domestic cat (Felis catus) ovarian tissue: Effects of three different sugars

We aimed to evaluate the effect of three extracellular cryoprotectants on the morphology of vitrified feline preantral follicles. Feline ovarian fragments (0.5 × 2 × 2 mm) collected from five domestic adult cats subjected to ovariohysterectomy for routine castration were vitrified with ethylene glycol (EG) 40% combined or not with sucrose (0.1 or 0.5 M), trehalose (0.1 or 0.5 M), or raffinose (0.1 M). After vitrification using the solid-surface method and warming of the tissues, cryoprotectants were washed out of the ovarian tissues, which were fixed for histological analysis. The percentages of normal follicles were similar to the control (fresh) (62.9 ± 4.1%) only for tissues exposed and cryopreserved with EG + trehalose at concentrations of 0.1 (35.8 ± 8.3%) and 0.5 M (33.4 ± 5.4%). All the other sugars decreased the percentages of morphologically normal follicles as compared to the control group and the trehalose groups. Based on the results of the present study, we recommend the use of trehalose as the extracellular cryoprotectant for the vitrification of feline ovarian tissue.     

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.     

Effects of different sucrose concentrations on vitrified porcine preantral follicles: Qualitative and quantitative analysis

The aim of the present study was to perform a qualitative and quantitative analysis of the effect of different sucrose concentrations combined with ethylene glycol in the preservation of vitrified porcine preantral follicles. Fragments of ovarian cortex were vitrified in cryotubes containing 200 μl of the vitrification solution (30% Ethylene Glycol; 20% Fetal Bovine Serum; 0 M–0.25 M – 0.75 M or 1 M sucrose) and stored in liquid nitrogen for a week. Histological analysis showed that after vitrification the number of normal follicles decreased compared to the fresh tissue (control). The percentage of normal primordial follicles was sucrose dose dependent. The percentage of normal primary follicles was similar in 0 M or 0.25 M sucrose, while higher concentrations (0.75 M and 1 M) increased significantly the percentage of abnormal follicles (p < 0.05). Morphometric analysis showed a statistically significant reduction in the total area of primordial follicles with 0.75 M sucrose and a significant increase in the cytoplasmic area of primordial follicles with 0 M sucrose (p < 0.05). The qualitative and the quantitative analysis appear to be a complementary tool when choosing a vitrification protocol. For our cryopreservation system - vitrification of ovarian cortex slices in cryotubes-the best vitrification medium was TCM 199-Hepes with 30% de ethylene glycol, 20% of Fetal Bovine Serum and 0 or 0.25 M sucrose. The present study shows that the use of high sucrose concentrations in the vitrification solution has a deleterious effect on the preservation of porcine preantral follicles contained in ovarian tissue. Consequently, its use at 0.75 M or 1 M wouldn't be recommended.     

Survival of oocytes recovered from vitrified sheep ovarian tissues

The objective of this work was to develop an effective vitrification technique for cryopreserving oocytes in sheep ovarian tissues. Ovaries were surgically recovered from 15 pubertal ewes and the ovarian cortex was cut into sections. Ovarian tissues were placed in equilibration medium consisting of 4% (v/v) ethylene glycol (EG) and 20% (v/v) FBS in TCM-199 on ice for 30 min and transferred to vitrification solution (35% EG, 5% polyvinylpyrrolidone, 0.4M trehalose and 20% FBS in TCM-199) for 5 min. Ovarian tissues were vitrified by dropping the tissue on the surface of a steel cube cooled by liquid nitrogen. Cumulus-enclosed oocyte complexes (COC) were also collected and vitrified following the procedure used for ovarian tissues. After 2-3 weeks of storage in liquid nitrogen, ovarian tissues and COC were thawed at 37 degrees C in 0.3M trehalose and COC in ovarian tissues were mechanically and enzymatically isolated. Vitrified COC and freshly collected COC were washed twice in maturation medium (TCM-199 supplemented with 0.255 mM pyruvate and 10% heat-treated estrus cow serum) and cultured in 50 microl drops of maturation medium under paraffin oil for 23-25h at 39 degrees C in a humidified atmosphere of 5% CO(2) in air. After culture, cumulus cells were removed by hyaluronidase treatment and vortexing and oocytes were fixed and stained. No significant differences were observed between vitrified oocytes, oocytes recovered from vitrified ovarian tissues and non-vitrified control oocytes in the percentage of oocytes with acceptable staining per total number of oocytes fixed or with visible chromatin per total number of oocytes with acceptable staining. However, fewer (P<0.05) oocytes obtained from vitrified ovarian tissues (70%) reached metaphase II compared to vitrified oocytes (88%) and non-vitrified control oocytes (90%). In contrast, when oocytes with at least 3-5 layers of cumulus cells were considered from each of the three groups, no differences (P>0.05) were observed due to treatment in the percentages of oocytes developing to metaphase II. These results demonstrate that sheep oocytes can be successfully cryopreserved by vitrification of ovarian tissues and exhibit in vitro maturation rates similar to that of vitrified and non-vitrified oocytes.     

Development of vitrified porcine primordial follicles in xenografts

The objective was to cryopreserve porcine primordial follicles by vitrification and to assess the development of these follicles in xenografts. Ovarian tissues containing primordial follicles were collected from neonatal (15-d-old) piglets. They were vitrified in modified tissue culture medium (TCM)-199 containing 15% (v/v) ethylene glycol, 15% (v/v) dimethylsulfoxide, 20% (v/v) fetal calf serum, and 0, 0.25, or 0.5 M sucrose. After 1 wk of storage in liquid nitrogen (LN₂), the tissues were warmed, and the morphology of follicles and oocytes was examined histologically. After vitrification in sucrose-free medium, there were 50 ± 2 (mean ± SEM; n = 10) follicles per tissue, in contrast with 108 ± 10 (n = 10) in fresh tissues. Losses were attributed to puncturing oocytes during the vitrification-warming process, as oocytes were apparently normal after treatment of the sucrose-free vitrification solution without plunging into LN₂. When tissues were vitrified in sucrose-supplemented medium, loss of oocytes decreased (P < 0.05). However, the number of abnormal oocytes having nuclear shrinkage was increased (P < 0.05) by the addition of 0.5 M sucrose; this occurred in a small number of oocytes treated with sucrose-supplemented vitrification solutions without vitrification. After 2 mo of xenografting of vitrified-warmed tissues in SCID (severe combined immune deficiency) mice, primordial follicles developed to the secondary stage (accompanied by oocyte growth), whereas there was development to the antral stage in xenografts of fresh tissues. In conclusion, primordial follicles from neonatal pigs maintained their developmental ability after vitrification and warming, although their developmental rate was slower than that of the fresh control in xenografts.     

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.     

Effective vitrification of human induced pluripotent stem cells using carboxylated ε-poly-l-lysine

Derivation of human induced pluripotent stem (iPS) cells could enable their widespread application in future. Establishment of highly efficient and reliable methods for their preservation is a prerequisite for these applications. In this study, we developed a vitrification solution comprising ethylene glycol (EG) and sucrose as well as carboxylated ε-poly-l-lysine (PLL); this solution inhibited devitrification. Human iPS cells were vitrified in 200-μL vitrification solutions comprised 6.5 M EG, 0.75 M sucrose and 0 or 10% w/v carboxylated PLL with 65 mol% of the amino groups converted to carboxyl groups [PLL (0.65)] in a cryovial by directly immersing in liquid nitrogen. After warming, attached colony and recovery rates of human iPS cells vitrified by adding PLL (0.65) were significantly higher than those for cells without PLL (0.65) and vitrification solution (DAP213: 2 M dimethyl sulfoxide, 1 M acetamide and 3 M propylene glycol). Furthermore, even after warming at room temperature, attached colony and recovery rates of iPS cells vitrified with PLL (0.65) were reduced to a lesser extent than those vitrified with either DAP213 or EG and sucrose without PLL (0.65). This could be attributed to inhibition of devitrification by PLL (0.65), as differential scanning calorimetry indicated less damage after vitrification with PLL (0.65). In addition, human iPS cells vitrified in the solution with PLL (0.65) had normal karyotypes and maintained undifferentiated states and pluripotency as determined by immunohistochemistry and teratoma formation. Addition of PLL (0.65) successfully vitrified human iPS cells with high efficiency. We believe that this method could aid future applications and increase utility of human iPS cells.     

Survival rate of preantral follicles derived from vitrified neonate mouse ovarian tissue by Cryotop and conventional methods

The aim of this study was to investigate the growth and survival rate of preantral follicles isolated from vitrified ovarian tissue by Cryotop and conventional methods. The ovaries of 14-day-old mice were separated and divided into four groups as following: Cryotop group, vitrified by Cryotop; CV (Conventional; CV) group, vitrified by conventional straw; toxicity test group and control group. After warming the vitrified ovaries, isolated preantral follicles from four groups were cultured for 4 days to compare survival rate and follicular growth between above-mentioned groups. Survival rate (97.3%) in toxicity test group alike the control group (98.7%) were significantly higher (P<0.05) than the Cryotop (92.7%) and CV (47.7%) groups. Increase in follicle diameters after 4 days in Cryotop and CV groups was significantly lower (P<0.05) than the control and toxicity test groups, but growth and survival rate of follicles in Cryotop group was significantly higher (P<0.05) than the CV group. These results demonstrated that ovarian tissue vitrification by Cryotop highly preserves the viability rate of preantral follicles.     

Comparison of the developmental potential of 2-week-old preantral follicles derived from vitrified ovarian tissue slices, vitrified whole ovaries and vitrified/transplanted newborn mouse ovaries using the metal surface method

Background

Cryopreservation of preantral follicles or ovarian tissues would enable the storage of large numbers of primordial follicles or preantral follicles and preserves the structural integrity of somatic and reproductive cells. In the present study, we compared the developmental potential of cryopreserved two-week-old mouse preantral follicles, ovarian tissue slices, two-week-old mouse ovaries and newborn mouse ovaries using a metal plate with a high cooling rate for cooling the droplet of vitrification solution.

Methods

Groups of 2 to 4 samples (including of 14-day old preantral follicles, ovarian tissue slices, whole ovaries, and whole newborn ovaries) were exposed to 4% ethylene glycol (EG) in DPBS + 10% FBS for 15 min and then rinsed in a vitrification solution composed of 6 M ethylene glycol and 0.4 M trehalose in DPBS + 10% FBS. Equilibration in room temperature was performed for 20–30 seconds for preantral follicle and 5 min equilibration was performed in an ice bath for ovaries. The samples were dropped onto the surface of metal plate around -180°C in the volume of 2 μl and 6 μl. After thawing, the ovarian tissue was mechanically isolated for collecting the preantral follicles. The thawed newborn ovaries were transplanted under the renal capsule of recipient male mice for 14 days. Preantral follicles collected from each groups were cultured individually in 20-μl droplets of α-MEM culture medium in culture dish for 12 days. On the day 12 of culture, the cumulus-oocyte complexes (COCs) were collected for IVM and IVF. Fertilization and embryo cleavage were scored.

Results

After the vitrification of 14-day-old preantral follicles using 2 μl or 6 μl droplet onto surface of metal plate, the results indicated that no significant difference in survival rate, antral-like cavity formation, COCs collected, 2 cell embryo cleavage and blastocyst development was found in vitrification of the 2 μl and 6 μl droplet groups. As comparing 14-day old ovarian tissue (ovarian tissue slices and whole ovaries) and whole newborn ovaries vitrified in 6 μl droplet, lower success rates of antral-like cavity formation and COCs collection were found in the whole ovaries group.

Conclusion

Our results suggest that the metal plate surface vitrification method is an appropriate and convenient method for cryopreservation of mouse ovaries and preantral follicles. The droplet volume of vitrification solution in 2 μl and 6 μl can be an option.     

Fresh and vitrified bovine preantral follicles have different nutritional requirements during in vitro culture

The aim of this study was to compare the efficiency of different media for the in vitro culturing of fresh and vitrified bovine ovarian tissues. Fragments of the ovarian cortex were subjected to vitrification and histological and viability analyses or were immediately cultured in vitro using the alfa minimum essential medium, McCoy’s 5A medium (McCoy), or medium 199 (M199). Samples of different culture media were collected on days 1 (D1) and 5 (D5) for quantification of reactive oxygen species and for hormonal assays. In non-vitrified (i.e., fresh) ovarian tissue cultures, the percentage of morphologically normal follicles was significantly greater than that recorded for the other media (e.g., M199). In the case of previously vitrified tissues, the McCoy medium was significantly superior to the other media in preserving follicular morphology up until the last culture day (i.e., D5), thus maintaining a similar percentage from D1 to D5. Reactive oxygen species levels were higher in D1 vitrified cultured tissues, but there were no differences in the levels among the three media after 5 days. The hormonal assays showed that in the case of previously vitrified tissues, at D5, progesterone levels increased on culture in the M199 medium and estradiol levels increased on culture in the McCoy medium. In conclusion, our results indicate that the use of M199 would be recommended for fresh tissue cultures and of McCoy for vitrified tissue cultures.     

Evaluation of sheep ovarian tissue cryopreservation with slow freezing or vitrification after chick embryo chorioallantoic membrane transplantation

The aim of our investigations was to compare the effectiveness of two methods for cryopreservation of sheep ovarian tissue, slow freezing and vitrification. The quality of cryopreserved tissues was evaluated after 5 days of thawing and chorioallantoic membrane (CAM) transplantation. Follicular structure, stromal integrity and neovascularization were assessed. The areas of fibrosis and necrosis were measured using MICROVISIBLE software, and proliferation was assessed with Ki-67 immunostaning. After 5 days of culture, the proportion of primordial follicles decreased, whereas the primary and intermediary follicles increased insignificantly (p > .05). Only necrosis in the vitrified culture group increased significantly (p < .05). It was established also that 5 days CAM culture was not suitable methodology for detection of folliculogenesis. Follicular quality decreased after culture, but was better in fresh and slow frozen tissues than after vitrification (p < .05). Cellular proliferative activity fell, but it preserved to some extent in all groups. In conclusion, follicles was preserved better in grafted tissue after slow freezing than vitrification and stroma was more susceptible to ischemia in vitrified rather than conventional freezing in this view. Vitrification may not be a suitable alternative to the slow freezing.     

Cryopreservation of the mouse ovary inhibits the onset of primordial follicle development

The cryopreservation of ovarian tissue has been reported to affect the development of preantral follicles. However, the effect of cryopreservation of ovarian tissue on the development of primordial follicles remains to be elucidated. This study was conducted to evaluate the effect of cryopreservation on the development of frozen-thawed mouse primordial follicles. One-day-old mouse ovaries were cryopreserved by either slow-freezing or a vitrification method. The development of primordial follicles was evaluated histologically and also with markers for follicle development such as: GDF-9, inhibin-alpha subunit and ZP3 in fresh and frozen-thawed ovaries cultured for five days. The proportion of apoptotic and necrotic areas was analyzed in fresh and frozen-thawed ovaries at one and five days after culture, in order to examine the viability of ovarian cells that influence primordial follicle development. The development rate of primordial follicles was significantly lower in slow-frozen and vitrified ovaries than the fresh controls after five days of in vitro culture (P<0.05). The mRNA expression for all developmental markers was slightly decreased in the frozen-thawed ovaries; this difference was not significant. The proportion of apoptosis was significantly increased in the slow-frozen and vitrified ovaries compared to the fresh ovaries at one day (P<0.05); however, there was no difference at five days after culture. The proportion of the area of necrosis was significantly higher in slow-frozen and vitrified ovaries compared to the fresh ovaries at one and five days after culture (P<0.05). Our preliminary data suggest that ovarian tissue cryopreservation using slow-freezing and vitrification methods inhibits development of primordial follicles. This may be caused by the death of ovarian cells through apoptosis and necrosis after cryopreservation.     

Vitrification of one-cell mouse embryos in cryotubes

Preventing intracellular ice formation is essential to cryopreserve cells. Prevention can be achieved by converting cell water into a non-crystalline glass, that is, to vitrify. The prevailing belief is that to achieve vitrification, cells must be suspended in a solution containing a high concentration of glass-inducing solutes and cooled rapidly. In this study, we vitrified 1-cell mouse embryos and examined the effect of the cooling rate, the warming rate, and the concentration of cryoprotectant on cell survival. Embryos were vitrified in cryotubes. The vitrification solutions used were EFS20, EFS30, and EFS40, which contained ethylene glycol (20, 30 and 40% v/v, respectively), Ficoll (24%, 21%, and 18% w/v, respectively) and sucrose (0.4 0.35, and 0.3 M, respectively). A 5-μl EFS solution suspended with 1-cell embryos was placed in a cryotube. After 2 min in an EFS solution at 23 °C, embryos were vitrified by direct immersion into liquid nitrogen. The sample was warmed at 34 °C/min, 4,600 °C/min and 6,600 °C/min. With EFS40, the survival was low regardless of the warming rate. With EFS30 and EFS20, survival was also low when the warming rate was low, but increased with higher warming rates, likely due to prevention of intracellular ice formation. When 1-cell embryos were vitrified with EFS20 and warmed rapidly, almost all of the embryos developed to blastocysts in vitro. Moreover, when vitrified 1-cell embryos were transferred to recipients at the 2-cell stage, 43% of them developed to term. In conclusion, we developed a vitrification method for 1-cell mouse embryos by rapid warming using cryotubes.     

Development of a modified vitrification strategy suitable for subsequent scale-up for hepatocyte preservation

This work explores the design of a vitrification solution (VS) for scaled-up cryopreservation of hepatocytes, by adapting VS_basic (40% (v/v) ethylene glycol 0.6 M sucrose, i.e. 7.17 M ethylene glycol 0.6 M sucrose), previously proven effective in vitrifying bioengineered constructs and stem cells. The initial section of the scale-up study involved the selection of non-penetrating additives to supplement VS_basic and increase the solution’s total solute concentration. This involved a systematic approach with a step-by-step elimination of non-penetrating cryoprotectants, based on their effect on cells after long/short term exposures to high/low concentrations of the additives alone or in combinations, on the attachment ability of hepatocytes after exposure. At a second stage, hepatocyte suspension was vitrified and functions were assessed after continuous culture up to 5 days.     

Cryopreservation of goat oocytes and in vivo derived 2- to 4-cell embryos using the cryoloop (CLV) and solid-surface vitrification (SSV) methods

This study evaluated the efficiency and toxicity of two cryopreservation methods, solid-surface vitrification (SSV) and cryoloop vitrification (CLV), on in vitro matured oocytes and in vivo derived early stage goat embryos. In the SSV method, oocytes were vitrified in a solution of 35% ethylene glycol (EG), 5% polyvinyl-pyrrolidone (PVP), and 0.4% trehalose. Microdrops containing the oocytes were cryopreserved by dropping them on a cold metal surface that was partially immersed in liquid nitrogen. In the cryoloop method, oocytes were transferred onto a film of the CLV solution (20% DMSO, 20% EG, 10mg/ml Ficoll and 0.65 M sucrose) suspended in the cryoloop. The cryoloop was then plunged into the liquid nitrogen. In vivo derived embryos were vitrified using the same procedures. The SSV microdrops were warmed in a solution of 0.3M trehalose and those vitrified with CLV were warmed with incubation in 0.25 and 0.125 M sucrose. Oocytes and embryos vitrified by the SSV method had a significantly lower survival rate than the control (60 and 39% versus 100%, respectively; P<0.05), while the survival rate of CLV oocytes and embryos (89 and 88%, respectively) did not differ from controls. Cleavage and blastocyst rates of the surviving vitrified oocytes (parthenogenetically activated) and embryos (cultured for 9 days) were not significantly different (P>0.05) from the control nor did they differ between vitrification methods. Embryos vitrified with the CLV method gave rise to blastocysts (2/15). Our data demonstrated that the two vitrification methods employed resulted in acceptable levels of survival and cleavage of goat oocytes and embryos.     

Vitrification of bovine embryos in a mixture of ethylene glycol and dimethyl sulfoxide

The influence of equilibration time before vitrification on the viability of vitrified morula- to blastocyst-stage bovine embryos and in vivo viability of vitrified embryos following transfer to recipients were investigated. In experiment 1, the embryos were exposed to an equilibration solution (50% VSED) containing 12.5% v/v ethylene glycol and 12.5% v/v dimethyl sulfoxide in modified Dulbecco's phosphate buffered saline with 4 mg/ml BSA (m-PBS) for 1, 2 and 5 minutes at room temperature (22 to 24 degrees C). The embryos were then placed in 15mul vitrification solution (VSED) consisting of 25% v/v ethylene glycol and 25% v/v dimethyl sulfoxide in m-PBS and were loaded into 0.25 ml plastic straws at room temperature. After 30 seconds, the straws were placed in liquid nitrogen (LN(2)) vapor for 2 minutes, plunged and stored in LN(2). To thaw, the straws were warmed in water at 20 degrees C for 15 seconds and the contents of the straws were expelled into a plastic dish. The embryos were diluted in 0.5 M sucrose + m-PBS for 5 minutes and were cultured in TCM-199 supplemented with bovine oviductal epithelial tissue. Viability of the embryos was assessed by the forming or reforming of the blastocoele after 24 hours of culture. High in vitro survival rates (73 approximately 90%) of vitrified embryos were obtained after 1 and 2 minute equilibrations, but was reduced (P<0.05) after 5 minute equilibration. In Experiment 2, morula- to blastocyst-stage embryos were vitrified after 1 minute equilibration in 50% VSED and 30 seconds of exposure to VSED. The vitrified-warmed embryos were transferred to recipient heifers at 7 days after estrus (1 embryo per recipient). Five (38%) of 13 (40%) of 10 recipients that had received blastocysts were diagnosed as pregnant using ultrasonography 60 days following transfer.     

Preservation of caprine preantral follicle viability after cryopreservation in sucrose and ethylene glycol

Caprine preantral follicles within ovarian fragments were cryopreserved in the absence or presence of 0.5 M sucrose with or without 1 M dimethyl sulfoxide and/or 1 M ethylene glycol (EG). After being thawed, they were washed in minimum essential medium with or without 0.3 M sucrose. Histological analysis of follicle integrity immediately after cryopreservation showed consistent beneficial effects of including sucrose in the three cryoprotectant solutions analyzed when tissue was thawed without sucrose (53.9±14.8–82.4±3.2% normal vs 27.6±1.6–36.6±6.5%, P<0.05). However, in further studies, the addition of sucrose to the thaw solutions proved detrimental or of no benefit. An analysis of the cryopreserved material with calcein-AM and ethidium homodimer (markers for living and dead cells, respectively) gave comparable results to those obtained by histology. Follicles cryopreserved in EG, EG plus sucrose, or sucrose alone were cultured in vitro for 24 h following warming. During this culture period, viability fell most rapidly in material cryopreserved in sucrose alone and was no longer correlated with either the viability or integrity estimates made immediately after warming. By contrast, the viability of follicles cryopreserved in EG with sucrose and then cultured for 24 h was not significantly different from the cultured non-frozen controls. These results indicate that cryopreservation in 1 M EG plus 0.5 M sucrose combined with thawing without sucrose is effective for caprine ovarian tissue.This work was supported by CAPES/Brazil. Regiane Rodrigues dos Santos is a recipient of a grant from FUNCAP of Brazil.     

Vitrification of caprine secondary and early antral follicles as a perspective to preserve fertility function

The present study aimed to evaluate the structure, survival and development of isolated caprine (secondary-SEC and early antral-EANT) follicles, after vitrification in the presence of synthetic polymers and in vitro culture. Additionally, transzonal projections (TZPs) and p450 aromatase enzyme were evaluated. After isolation, SEC and EANT follicles were in vitro cultured for six days or vitrified. After one week, SEC and EANT follicles were warmed and also in vitro cultured for six days. Data revealed that the percentage of morphologically normal follicles was similar between fresh and vitrified follicles in both follicular categories and antrum formation rate was similar between fresh and vitrified SEC follicles. Fluorescence by calcein-AM did not show difference between fresh and vitrified (SEC and EANT) follicles, however, the trypan blue test showed low viability for vitrified follicles. The integrity of TZPs was not affected between fresh and vitrified SEC follicles, however, in vitrified EANT follicles, there were signs of TZPs loss. Regarding steroidogenic function, it was observed a positive staining for p450 aromatase enzyme in fresh and vitrified SEC and EANT follicles. It was concluded that SEC follicles seem to be more resistant to vitrification than EANT follicles, as shown by the trypan blue test and TZPs assay. Future studies may confirm this hypothesis, in order to consolidate the use of SEC and EANT follicles as an alternative to ovary cryopreservation.     

A study on the vitrification of stage III zebrafish (Danio rerio) ovarian follicles

Attempts to cryopreserve fish embryos have been conducted over the past three decades, nevertheless successful cryopreservation protocol for long-term storage still remains elusive. Fish oocytes offer some advantages when compared to embryos, which may help in improving the chances of cryopreservation. In the present study, a series of cryo-solutions were designed and tested for their vitrifying ability using different devices (0.25 ml plastic straw, vitrification block and fibreplug™). Toxicity of vitrification solutions was evaluated by assessing follicle membrane integrity with trypan blue staining. In addition, the effect of vitrification protocol on stage III zebrafish ovarian follicles was investigated by measuring the cytoplasmic ATP content and the mitochondrial distribution and activity using JC-1 probe and confocal microscopy. After vitrification, follicles showed membrane integrity of 59.9 ± 18.4% when fibreplug and V₁₆ (1.5 M methanol + 4.5 M propylene glycol) solution were employed. When vitrified in V₂ (1.5 M methanol + 5.5 M Me₂SO) the membrane integrity decreased to 42.0 ± 21.0%. It was observed that follicles located in the middle of the fragments were more protected from injuries and some of them showed good morphological appearance 2 h post-warming. Mitochondria integrity of granulosa cells layer was clearly damaged by the vitrification protocol and ATP level in the follicles declined significantly after warming. Vitrification of zebrafish follicles in ovarian tissue fragments and its effect at sub-cellular level is reported here for the first time. Information gained from this study will help in guiding development of optimal protocol for cryopreservation of fish oocytes.