Morphological and functional preservation of pre-antral follicles after vitrification of macaque ovarian tissue in a closed system.

STUDY QUESTION: What are the appropriate conditions to vitrify the macaque ovarian cortex in a large-volume, closed system that will preserve functional pre-antral follicles? SUMMARY ANSWER: The combination of glycerol, ethylene glycol (EG) and polymers with cooling in liquid nitrogen (LN2) vapor and a two-step warming procedure was able to preserve tissue and follicle morphology as well as function of a small population of secondary follicles in the macaque ovarian cortex following vitrification in a closed system. WHAT IS KNOWN ALREADY: For prepubertal cancer patients or those who require immediate cancer therapy, ovarian tissue cryopreservation offers the only hope for future fertility. However, the efficacy of live birth from the transplantation of cryopreserved ovarian tissue is still unclear. In addition, live birth from cryopreserved ovarian tissue has only been demonstrated after tissue autotransplantation, which poses the risk of transmitting metastatic cancer cells back to the cancer survivor in certain cancers. STUDY DESIGN, SIZE, DURATION: Non-human primate model, n = 4, randomized, control versus treatment. End-points were collected from tissue histology, tissue culture (48 h) and isolated secondary follicle culture (6 weeks). PARTICIPANTS/MATERIALS, SETTING, METHODS: Two vitrification solutions (VSs) containing EG + glycerol (VEG) and EG + dimethylsulfoxide (VED) were examined for vitrification, devitrification and thermodynamic properties. Once the optimal VS was determined, macaque ovarian cortical pieces (3 × 3 × 0.5 mm(3)) were divided into fresh and two vitrified groups (VEG and VED). For the vitrification groups, tissues were exposed to 1/4, 1/2 and 1× VS for 5 min/step as well as 1× VS + polymers for 1 min at 37°C, loaded into high-security straws with 1 ml of VS + polymers, heat sealed and cooled in LN2 vapor. Samples were warmed in a 40°C water bath and cryoprotective agents were diluted with 1, 0.5, 0.25 and 0 M sucrose. Tissues were fixed for histological analysis and cultured with bromodeoxyuridine (BrdU). Secondary follicles from VEG tissues were encapsulated and cultured (n = 24/treatment/animal). Follicle health, diameter and steroid [progesterone, androstenedione (A4), estradiol (E2)] production were analyzed weekly. MAIN RESULTS AND THE ROLE OF CHANCE: Dense stroma and intact pre-antral follicles were observed using VS containing 27% glycerol, 27% EG and 0.8% polymers with cooling in LN2 vapor and a two-step warming. Higher cooling and warming rates led to fracturing. BrdU uptake was evident in granulosa cells of growing follicles in fresh and vitrified tissues. Secondary follicles from fresh tissues (70 ± 12%) and tissues vitrified with VEG (52 ± 2%) showed similar survival rates (all data: mean ± SEM; P > 0.05). For both groups, the initial follicle diameter was similar and increased (P < 0.05) by Week 3, but diameters in vitrified follicles were smaller (P < 0.05) by Week 6 (566 ± 27 µm) than those of the fresh follicles (757 ± 26 µm). Antrum formation rates were lower (P < 0.05) for vitrified (37 ± 6%) relative to fresh (64 ± 8%) follicles. There was no significant change in levels in culture media of E2, P4 and A4 between fresh and VEG groups at any time point during culture. LIMITATIONS, REASONS FOR CAUTION: Only in vitro studies are reported. Future in vivo tissue transplantation studies will be needed to confirm long-term function and fertility potential of vitrified ovarian tissues. WIDER IMPLICATIONS OF THE FINDINGS: This is the first demonstration of antral follicle development during 3D culture following ovarian tissue vitrification in a closed system using primate ovarian tissue. While diminished antrum formation and slower growth in vitro reflect residual cryodamage, continued development of ovarian tissue vitrification based on cryobiology principles using a non-human primate model will identify safe, practical and efficient protocols for eventual clinical use. Tissue function following heterotopic transplantation is currently being examined. STUDY FUNDING/COMPETING INTEREST(S): National Institutes of Health (NIH) Oncofertility Consortium UL1 RR024926 (1RL1-HD058293, HD058295, PL1 EB008542), the Eunice Kennedy Shriver NICHD/NIH (U54 HD018185) and ONPRC 8P51OD011092-53. G.M.F. works for the company that makes the polymers used in the current study.

A chronologic review of mature oocyte vitrification research in cattle, pigs, and sheep.

Vitrification as a means of cryopreservation has become a standard approach for oocytes from livestock. This paradigm shift occurred primarily as a result of the demonstration in 1996 that bovine oocytes are extremely susceptible to chilling injury. Since that early work, numerous devices have been used as supports for oocytes during so-called "ultra-rapid cooling", and occasionally, trials involving the deposition of small volumes of media containing oocytes directly into liquid nitrogen to facilitate cooling have been reported. Results reporting blastocyst development exceeding 10% are common, but variability remains high, and a standard method for bovine oocytes remains to be established. Oocytes from pigs are particularly difficult to cryopreserve, even with the use of ultrarapid cooling approaches. Few reports have demonstrated blastocyst development exceeding 5%. The application of hydrostatic pressure before vitrification appears to impart stress tolerance to porcine oocytes, as the results of some treatments have shown development to blastocysts at proportions >10%. Work on sheep oocyte vitrification is relatively new, and a few articles have reported blastocyst development at 10% or more. Messenger RNA levels are reportedly altered in sheep oocytes as a result of vitrification, and damage to the cytoskeleton is common across species.

Morphological and apoptotic comparison of primordial and primary follicles in cryopreserved human ovarian tissue.

There are few reports which were designed to compare the survival rate of human primary follicles with primordial follicles after cryopreservation. This study was designed to evaluate whether such a difference occurs. Human ovarian biopsies were cryopreserved using dimethylsulphoxide/sucrose as the cryoprotectants. Fresh and cryopreserved ovarian samples were evaluated for viability differences between the two types of follicles using the endpoints of histology, ultrastructure and DNA fragmentation. In comparison with fresh ovarian tissue (83.9%+/-10.0%), the percentage of morphologically normal primordial follicles was not significantly different in cryopreserved tissue (73.9%+/-17.2%). However, a lower percentage of primary follicles with normal morphology was seen in the cryopreserved group (43.3%+/-25.7% vs 74.8%+/-19.4% for the fresh group). Transmission electron microscopy revealed that the cryopreservation did not appear to affect the structural integrity of primordial follicles; however, varying ultrastructural damage to the cytoplasm was observed in the majority of the cryopreserved primary follicles. Using a DNA fragmentation assay, the percentage of apoptotic primordial and primary follicles in the unfrozen (26.3% and 20%) and frozen (23.3% and 25%) ovarian tissue was similar. A higher proportion of primary follicles, compared to primordial follicles, suffer histological damage after slow freezing.

The effect of osmotic stress on the cell volume, metaphase II spindle and developmental potential of in vitro matured porcine oocytes.

Porcine animal models are used to advance our understanding of human physiology. Current research is also directed at methods to produce transgenic pigs. Cryobanking gametes and embryos can facilitate the preservation of valuable genotypes, yet cryopreserving oocytes from pigs has proven very challenging. The current study was designed to understand the effects of anisotonic solutions on in vitro matured porcine oocytes as a first step toward designing improved cryopreservation procedures. We hypothesized that the proportion of oocytes demonstrating a normal spindle apparatus and in vitro developmental potential would be proportional to the solution osmolality. Oocytes were incubated for 10 min at 38 degrees C in various hypo- or hypertonic solutions, and an isotonic control solution and then assessed for these two parameters. Our results support the hypothesis, with an increasing proportion of spindles showing a disrupted structure as the levels of anisotonic exposure diverge from isotonic. Only about half of the oocytes maintained developmental potential after exposure to anisotonic solutions compared to untreated controls. Oocyte volume displayed a linear response to anisotonic solutions as expected, with an estimated relative osmotically inactive cell volume of 0.178. The results from this study provide initial biophysical data to characterize porcine oocytes. The results from future experiments designed to determine the membrane permeability to various cryoprotectants will allow predictive modeling of optimal cryopreservation parameters and provide a basis for designing improved cryopreservation procedures.

Xenotransplantation of cryopreserved equine squamous cell carcinoma to athymic nude and SCID mice.

Cryopreserved equine ocular squamous cell carcinoma (SCC) was inoculated subcutaneously into 15 athymic nude and 15 SCID mice. Xenotransplantation resulted in tumor growth in two athymic nude mice and 1 SCID mouse. Histological appearance and immunohistochemical characterization using cytokeratin 5/6 markers and p53 markers of the tumor grown in mice was in full accord with the original equine tumors. No evidence of metastasis was noted in any mouse. This model may serve as a relevant in vivo model for studying the biology of equine ocular SCC and for the testing of new therapeutic modalities.

The effect of osmotic stress on the metaphase II spindle of human oocytes, and the relevance to cryopreservation.

BACKGROUND: Knowing osmotic tolerance limits is important in the design of optimal cryopreservation procedures for cells. METHODS: Mature human oocytes were exposed to anisosmotic sucrose solutions at concentrations of 35, 75, 150, 600, 1200, or 2400 (+/-5) milliosmolal (mOsm) at 37 degrees C. A control treatment at 290 mOsm was also utilized. Oocytes were randomly allocated to each experimental treatment. After the treatment, the oocytes were cultured for 1 h, then fixed in cold methanol. Immunocytochemical staining and fluorescence microscopy were used to assess the morphology of the metaphase II (MII) spindle. Logistic regression was used to determine if media osmolality had a significant effect on spindle structure. RESULTS: Osmolality was a significant predictor of spindle morphology. Hyposmotic effects at 35, 75, and 150 mOsm resulted in 100, 67, and 56% of oocytes having abnormal spindles, respectively. Hyperosmotic effects at 600, 1200, and 2400 mOsm resulted in 44, 44, and 100% of the spindles with abnormal structure, respectively. CONCLUSIONS: Anisosmotic conditions lead to disruption of the MII spindle in human oocytes. Applying this fundamental knowledge to human oocyte cryopreservation should result in increased numbers of cells maintaining viability.