新生小鼠卵巢移植雄鼠肾囊下卵泡的生长发育

将1日龄小鼠卵巢移植入成年雄鼠肾囊下,分别于移植后18d、36d回收移植卵巢进行形态学、组织学观察,以评价卵巢移植体在成年雄性受体小鼠体内生长及卵泡发育潜能。结果表明:移植体生长增大,有各级生长卵泡发育;18日龄移植体平均直径为1881.1μm±204.7μm,与1日龄卵巢相比差异极显著(P<0.01),卵泡发育到有腔卵泡阶段;36日龄移植体平均直径达2575.3μm±466.4μm,显著大于18日龄移植体(P<0.01),有成熟卵泡出现,未观察到黄体;从移植体分离到GV期卵母细胞和卵丘卵母细胞复合体。研究表明1日龄小鼠卵巢移植体在雄性受体生理环境中具有正常生长发育和形成成熟卵泡的潜能。     

人胎儿卵巢异种移植的组织学研究

目的探讨人胎儿卵巢组织异体移植的最佳条件。方法观察胎儿卵巢进行异种移植后的组织学变化,并计算各组移植卵巢内各期卵泡的发育情况及卵泡构成比。结果新鲜的卵巢组织、体外培养的卵巢组织以及冷冻复苏后经体外培养的卵巢组织移植后,其内有原始卵泡发育,而且可见丰富的血管网;未见明显的淋巴细胞浸润现象。结论人胎儿卵巢组织(包括新鲜的卵巢组织、体外培养的卵巢组织以及冷冻复苏后经体外培养的卵巢组织)异种移植后原始卵泡在受体体内能进一步发育,生长卵泡分泌的雌激素有调节子宫内膜周期性变化的作用。     

雄性受体小鼠性腺对移植卵巢卵母细胞生长发育的影响

目的探索雄性受体性腺对移植卵巢卵母细胞生长发育的影响。方法将1日龄小鼠卵巢移植入成年雄鼠肾囊下,将雄性受体小鼠分为性腺摘除组和性腺在位组,于21d回收移植卵巢,以评价雄性小鼠性腺对新生小鼠卵巢移植体卵母细胞生长发育的影响。结果移植后21d,性腺摘除组和性腺在位组卵巢回收率分别为80.0%和92.9%,移植体生长增大;每个卵巢平均回收卵母细胞数分别为(30.4±4.3)和(42.4±11.1)个,两者差异不显著(P0.05);性腺摘除组回收的均为GV期卵母细胞,性腺在位组大部分为GV期卵母细胞,有的达到MII期。结论雄性受体小鼠能够支持移植卵巢卵母细胞的生长发育,雄性受体的性腺对其影响不明显。     

小鼠移植卵巢的生长及功能初探

实验对小鼠单侧和双侧自体异位移植的卵巢,运用组织学、组织化学和放射免疫技术,探讨其生长规律。结果表明：移植卵巢的生长可分三个阶段：（１）坏死期：移植第２～４天,卵巢的原有组织处于退化状态,仅边缘可见原始卵泡和窦前卵泡;（２）恢复期：移植第７～１４天,卵巢逐渐恢复正常结构,血清孕酮水平开始上升,大多数动物出现动情周期;（３）发育成熟期：移植第１４天以后,卵巢内含发育不同阶段的卵泡、黄体和大量间质腺,孕酮水平接近正常。单侧移植卵巢的生长比双侧推迟约７天。本研究显示自体异位移植卵巢能够生长发育并分泌雌性激素     

小鼠卵巢几个重要发育事件的初步研究

选定多个阶段小鼠卵巢进行切片染色和生殖细胞计数统计等分析,以发现该阶段小鼠卵巢的发育特点。结果显示在胚胎发育第12.5 d的生殖嵴中,大部分的生殖细胞正进行有丝分裂增殖,并以生殖包囊的形式存在;在出生后第2 d的小鼠卵巢中,有大量紧密接触的原始卵泡,表明生殖包囊刚完成重组形成原始卵泡;在第5 d的小鼠卵巢中,原始卵泡仍占有大部分比例,但也有大量的初级卵泡处于发育之中;在出生后第10 d的卵巢中同时有原始卵泡、初级卵泡和次级卵泡的发育;老年小鼠(16个月大)卵巢中已基本没有卵母细胞。     

哺乳动物卵母细胞异位发育技术及其研究进展

综述了哺乳动物卵巢移植在生物医学上的应用,及借助卵巢异位发育研究卵巢卵母细胞发育机制的研究进展;详细介绍了卵巢移植的不同技术方法,及移植后卵巢卵母细胞的发育、激素的调节机制,分析了卵巢移植早期卵泡生长和凋亡的分子机理及其在移植医学中的应用前景,并就新鲜和冻融卵巢如何用于动物辅助生殖进行了阐述.特别关注卵巢卵母细胞异种移植的潜在价值,卵巢异种移植不仅可以保存稀有和濒危物种,还可以为当前辅助生殖技术提供一个理想的实验手段.     

两种冷冻保护剂对小鼠2-细胞胚冷冻效果的比较

乙二醇（ETG）和1,2-丙二醇（PROH）具有高细胞渗透性和低毒性特点,常被用于人及多种哺乳动物早期胚胎冷冻保存。为了比较ETG和PROH对小鼠2-细胞胚的冷冻保护效果,本试验分别采用这两种冷冻保护剂,对小鼠2-细胞胚进行冷冻保存,并采用冻后体外培养和囊胚移植进行冷冻效果检测。结果表明,PROH组胚胎解冻后胚胎存活率与ETG组无显著差异,但PROH组4-细胞胚发育率和囊胚发育率显著高于ETG组（82．7％vs．64．6％,61．2％vs．29．1％,P〈0．01）。囊胚移植结果表明,2-细胞胚胎冻存后能够发育为正常的后代,PROH组和ETG组的囊胚移植后妊娠产仔率无统计学差异（P〉0．05）,但均显著低于对照组（P〈0．05）。为了分析两组胚胎冻存后损伤情况,埘解冻后的胚胎细胞微丝进行检测,结果显示ETG组微丝受损的胚胎数高于PROH组。本研究结果证明采用PROH作为冷冻保护剂冷冻保存小鼠2-细胞胚的冻存效果优于ETG[动物学报54（6）：1098—1105,2008]。     

人重组卵泡刺激素和表皮生长因子对性未成熟小鼠卵母细胞和颗粒细胞复合体体外发育的作用

卵泡刺激素（FSH）对有腔卵泡和排卵前卵泡的促生命作用已被普遍接受,但关于其对腔前卵泡发育的作用报道结果不尽相同,关于表皮生长因子（EGF）对腔前卵泡的作用尚不确切,本研究目的在于探讨人重组卵泡刺激素（rechFSH)和EGF对早期卵泡发育的作用,利用胶原酶消化法从12日龄的小鼠卵巢中分离得到卵母细胞－颗粒细胞复合体（OGCs)(Fig.1)。体外每孔30－40个培养物并分别添加胎牛血清（FBS）,rechFSH和EGF。培养物每4天测量卵母细胞和OGCs直径,并每天照相,结果显示,rechFSH显著促进小鼠OGCs 及其卵母细胞的体外发育,这一作用可被EGF进一步增强（P＜0．05）（Fig.2),但到第八天培养结束时,培养后的OGCs卵母细胞要显著小于体内期生长对照组（P＜0．05）（Fig.3),说明FSH和EGF在卵泡早期发育中起重要作用。     

应用乙二醇冷冻小鼠胚胎：优化和简化程序的探索

提高解冻胚胎的发育能力和简化冷冻解冻程序是胚胎冷冻研究的两大永恒的主题。尽管乙二醇（EG）广泛用于家畜胚胎冷冻,但很少用于冷冻小鼠和人胚胎。为数很少的以EG慢冻小鼠或人胚胎的研究均采用较为复杂的人胚冷冻程序,未见简化程序和用EG冷冻小鼠桑椹胚的报道。采用简单的牛胚胎冷冻程序研究了发育时期、EG浓度、平衡方法、添加蔗糖以及解冻后脱除EG等对小鼠胚胎冻后发育能力的影响。结果显示：（1）致密晚期桑椹胚冻后体外培养囊胚发育率（81.92%±2.24%）和孵出率（68.56％±2.43%）显著（P＜0.05)高于4-细胞、8-细胞胚胎和致密早期桑椹胚胎;（2）1.8mol/L EG冷冻小鼠致密晚期桑椹胚的囊胚发育和孵出率显著高于其它浓度;（3）在EG中平衡10min的冻后囊胚发育显著好于平衡5、20或30min;（4）两步平衡冷冻胚胎的囊胚发育率和孵出率显著高于一步平衡;（5）用EG冷冻小鼠胚胎无需添加蔗糖;（6）解冻后可不脱除EG;（7）冻后发育的早期囊胚和囊胚细胞数明显少于体内发育胚胎。因此,用EG冷冻小鼠胚胎的最佳方案为：致密晚期桑椹胚用1.8mol/L EG不添加蔗糖、两步平衡15min、以简单的牛胚胎冷冻程序冷冻解冻、解冻后不脱除EG直接培养或移植。     

小鼠卵巢组织的超速冻存法研究

目的　本实验通过对小鼠卵巢组织进行冻存研究 ,掌握卵巢的低温生物学特性 ,摸索出一种简便有效的组织器官冻存法 ,为卵巢移植及器官冷冻提供有用的技术方法。方法　通过对小鼠卵巢组织进行慢速程序法与快速液氮蒸汽法冻存 ,比较分析了不同方法所需保护剂种类、浓度、渗透平衡时间。采用对解冻后卵巢组织超微结构观察、组织化学染色、激素测定及自体、异体移植后动情期的恢复作为评价指标。结果与结论　通过上述实验表明用同种冷冻保护剂 ,液氮蒸汽法冻存的卵巢组织超微结构保存良好 ;组织化学染色示其活性与程序法冻存组织相同 ;自体、异体移植后 ,小鼠动情周期的恢复率及血清雌二醇水平各项指标均与慢速程序法冷冻无显著性差异     

Live offspring by in vitro fertilization of oocytes from cryopreserved primordial mouse follicles after sequential in vivo transplantation and in vitro maturation

The objectives of the present study were to achieve 1) oocyte maturation, 2) oocyte competence of fertilization, and 3) oocyte competence of embryogenesis with oocytes from primordial follicles obtained from cryopreserved newborn mouse ovaries by using a two-step method. In the first step, frozen-thawed newborn mouse ovaries were transplanted under the kidney capsule of recipients for the initiation of growth from the primordial follicle stage on. In the second step, growing preantral follicles in the ovarian grafts were recovered and cultured. The results demonstrated that primordial follicles were able to be recruited to preantral follicles during the period of transplantation, and preantral follicles could be mechanically isolated from ovarian grafts. Under the present in vitro culture conditions, 85.8% of the isolated follicles (n = 332) from ovarian grafts survived the 12-day in vitro culture process, 84.9% of the recovered oocytes (n = 285) were germinal vesicle breakdown (GVBD)-competent, and 76% of the oocytes that underwent GVBD (n = 242) developed to the metaphase II (MII) stage. In the in vitro fertilization experiments, 75.4% of 142 inseminated MII oocytes underwent fertilization and cleavage to the 2-cell stage. Subsequently, 79.7% of the 2-cell-stage embryos (n = 69) progressed to the late morula-early blastocyst stage. Transfer of late morula-early blastocyst embryos resulted in the production of live offspring. From our experiments, it may be concluded that in vivo maturation by grafting followed by in vitro maturation of frozen-thawed primordial follicles can restore fertility in mice. This model could be useful for a similar application in the human.     

Maturation of mouse primordial follicles by combination of grafting and in vitro culture

Cryopreservation of ovarian cortical tissue and subsequent transplantation or in vitro culture of follicles are technologies under development with the aim to safeguard fertility in patients with gonadal failure. In the present study, we investigated whether primordial follicles could be triggered to full maturation by a combination of in vivo transplantation and in vitro culture in a mouse model. In a first step, newborn mouse ovaries containing only primordial follicles were allotransplanted under the renal capsule of ovariectomized recipient mice. The second step was to mechanically isolate growing preantral follicles from the graft and culture these in vitro to maturity. In our experiment, one newborn mouse ovary was transplanted under the renal capsule of each 8- to 12-wk-old F1 (C57Bl/6j x CBA/Ca) female ovariectomized recipient (n = 26). Two weeks after transplantation, all 26 grafts were recovered. Four grafts were processed for histology and showed that developmental stages of follicles in 14-day-old ovarian grafts were comparable to those in 14-day-old mouse ovaries. The 22 remaining grafts were used for mechanical isolation of preantral follicles. As a control group, preantral follicles isolated from ovaries of 14-day-old mice were used. The mean preantral follicle yield per ovary was 11 in the transplant group versus 33 in the control group. Follicles were cultured individually in 20-microliter droplets of alpha-MEM supplemented with 100 mIU rFSH and 5% fetal bovine serum for 12 days under an atmosphere of 5% CO(2) in air at 37 degrees C. By Day 12 of culture, 66.5% of follicles retained their oocytes in the grafting group versus 97.5% in the control group (P < 0.001). Final oocyte maturation was induced by addition of 2.5 IU/ml hCG. At 14-16 h post-HCG, the percentages of oocytes showing germinal vesicle breakdown and polar body extrusion were significantly higher in the control group (90.6% and 82.8%) compared to the grafting group (60% and 45%). The mean diameter of the mature oocytes of the grafting group (69.9 +/- 4.45 micrometer) was similar to that of oocytes from the control group (70.5 +/- 2.35 micrometer). Our results suggest that maturation of mouse primordial follicles is feasible by combination of in vivo transplantation and in vitro culture. This two-step strategy may be an attractive model for promoting the growth and maturation of primordial follicles from other species.     

Cryopreservation of equine oocytes by 2-step freezing

Immature equine oocytes were frozen-thawed with ethylene glycol (EG), 1,2-propanediol (PD) or glycerol (GL) in PBS and cultured to assess the rate of in vitro maturation (Experiment 1). Compact-cumulus oocyte complexes were collected from slaughterhouse ovaries and equilibrated for 10 min in the freezing medium containing 10% (V/V) cryoprotectant and 0.1 M sucrose. The 0.25-ml straws, loaded with 10 to 30 oocytes, were seeded at -6 degrees C and cooled to -35 degrees C at 0.3 degrees C/min before being plunged into liquid nitrogen. The straws were thawed rapidly in a 37 degrees C waterbath for 20 sec. The proportions of frozen-thawed oocytes reaching Metaphase II (MII) stage after in vitro maturation of 32 h were 15.8% (EG), 5.8% (PD) and 0% (GL), while 63.3% of the nonfrozen control oocytes matured in vitro. The fertilizing ability of immature and mature oocytes after freezing in EG was tested by the insemination of zona-free oocytes with stallion spermatozoa (Experiment 2). Spermatozoa were preincubated for 3 h with 5 mM caffeine, treated with 0.1 mu M ionophore A23187, and inseminated for 20 h at the concentration of 1 to 2 x 10(7)/ml with 6 to 10 oocytes in 50 mu l of Brackett and Oliphant (BO) medium. Immature oocytes (Group 1) were matured in vitro after thawing and then their zona pellucida removed using 0.5% protease. The zona of mature oocytes were removed immediately after thawing (Group 2) or maturation (nonfrozen controls). The oocytes, which had mechanically damaged plasma membrane or lost by artifact, were not examined for insemination. Significantly more control oocytes exhibited a polar body at the time of insemination (53.5%) than either frozen-thawed immature or mature oocytes (25.8 and 27.3%, respectively). Similar proportion of frozen-thawed and control oocytes were penetrated by spermatozoa (71.8 to 79.1%) and exhibited 2 or more pronuclei (73.6 to 80.8%). The mean numbers of spermatozoa per penetrated oocyte were 1.9, 3.0 and 2.5, respectively, for Groups 1 and 2 and for the control oocytes. These results indicate that immature equine oocytes mature to the MII stage in vitro following freezing and thawing in EG or PD but not in GL. Stallion spermatozoa can penetrate zona-free immature and mature oocytes following freezing/thawing in EG and form morphologically normal pronuclei.     

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.     

Growth of mouse oocytes to maturity from premeiotic germ cells in vitro

In the present study, we established an in vitro culture system suitable for generating fertilizable oocytes from premeiotic mouse female germ cells. These results were achieved after first establishing an in vitro culture system allowing immature oocytes from 12-14 day- old mice to reach meiotic maturation through culture onto preantral granulosa cell (PAGC) monolayers in the presence of Activin A (ActA). To generate mature oocytes from premeiotic germ cells, pieces of ovaries from 12.5 days post coitum (dpc) embryos were cultured in medium supplemented with ActA for 28 days and the oocytes formed within the explants were isolated and cocultured onto PAGC monolayers in the presence of ActA for 6-7 days. The oocytes were then subjected to a final meiotic maturation assay to evaluate their capability to undergo germinal vesicle break down (GVBD) and reach the metaphase II (MII) stage. We found that during the first 28 days of culture, a significant number of oocytes within the ovarian explants reached nearly full growth and formed preantral follicle-like structures with the surrounding somatic cells. GSH level and Cx37 expression in the oocytes within the explants were indicative of proper developmental conditions. Moreover, the imprinting of Igf2r and Peg3 genes in these oocytes was correctly established. Further culture onto PAGCs in the presence of ActA allowed about 16% of the oocytes to undergo GVBD, among which 17% reached the MII stage during the final 16-18 hr maturation culture. These MII oocytes showed normal spindle and chromosome assembly and a correct ERK1/2 activity. About 35% of the in vitro matured oocytes were fertilized and 53.44% of them were able to reach the 2-cell stage. Finally, around 7% of the 2-cell embryos developed to the morula/blastocyst stage.     

Live offspring produced by mouse oocytes derived from premeiotic fetal germ cells

Mature mouse oocytes currently can be generated in vitro from the primary oocytes of primordial follicles but not from premeiotic fetal germ cells. In this study we established a simple, efficient method that can be used to obtain mature oocytes from the premeiotic germ cells of a fetal mouse 12.5 days postcoitum (dpc). Mouse 12.5-dpc fetal ovaries were transplanted under the kidney capsule of recipient mice to initiate oocyte growth from the premeiotic germ cell stage, and they were recovered after 14 days. Subsequently, the primary and early secondary follicles generated in the ovarian grafts were isolated and cultured for 16 days in vitro. The mature oocytes ovulated from these follicles were able to fertilize in vitro to produce live offspring. We further show that the in vitro fertilization offspring were normal and able to successfully mate with both females and males, and the patterns of the methylated sites of the in vitro mature oocytes were similar to those of normal mice. This is the first report describing premeiotic fetal germ cells able to enter a second meiosis and support embryonic development to term by a combination of in vivo transplantation and in vitro culture. In addition, we have shown that the whole process of oogenesis, from premeiotic germ cells to germinal vesicle (GV)-stage oocytes, can be carried out under the kidney capsule.     

Vitrification of immature and mature equine and bovine oocytes in an ethylene glycol, ficoll and sucrose solution using open-pulled straws

Studies were conducted to compare viability of immature and mature equine and bovine oocytes vitrified in ethylene glycol. Ficoll using open-pulled straws. Oocytes from slaughterhouse ovaries (N=50/group) with >2 layers of compact cumulus cells were vitrified immediately after collection (immature groups) or vitrified after 36 to 40 (equine) or 22 to 24 (bovine) h of maturation (mature groups). Immature oocytes were matured after thawing. Before vitrification, oocytes were exposed to TCM-199 + 10 FCS + 2.5 M ethylene glycol + 18% Ficoll + 0.5 M sucrose (EFS) for 30 sec and then to 5 M ethylene glycol in EFS for 25 to 30 sec at 37 degrees C. Oocytes were loaded into straws in approximately 2 microL of cryoprotectant and plunged directly into LN2. Warming straws and dilution of cryoprotectant was at 37 degrees C in TCM-199 + 10% FCS + 0.25 M sucrose for 1 min and then TCM-199 + 10% FCS + 0.15 M sucrose for 5 min. Non-vitrified oocytes undergoing the same maturation protocol for both species were used as controls. Oocytes were stained with orcein for nuclear maturation and live/dead status was determined using Hoechst 33342. Maturation of oocytes to MII after thawing was similar (P>0.05) among groups within species. All equine treatment groups had lower (P<0.01) maturation rates than bovine groups. Live/dead status did not differ among vitrification treatments within species. The percentage of oocytes that survived and reached MII did not differ (P>0.05) within treatment groups of each species. Rates of mature cortical granule distribution did not differ (P>0.05) within species; however, more bovine oocytes (P<0.05) had mature cortical granule distribution and nuclear maturation than equine oocytes. When concurrent cortical granule distribution and nuclear maturation were examined, there was no difference within species; however, only 30% of equine oocytes had nuclear and cytoplasmic maturation compared with 70% of bovine oocytes (P<0.05). In summary, both immature and mature equine and bovine oocytes survived cryopreservation using vitrification in open-pulled straws. However, survival rates were lower for equine than for bovine oocytes.     

Mouse oocytes derived from fetal germ cells are competent to support the development of embryos by in vitro fertilization

Mouse oocyte development in vitro has been studied in the past several years, but no evidence showed that the fertilizable oocytes could be obtained from the fetal mouse germ cells before the formation of the primordial follicles. In this study, an efficient and simple method has been established to obtain the mature oocytes from the fetal mouse germ cells at 16.5 days post-coitum (dpc). For the initial of follicular formation, fetal mouse 16.5 dpc ovaries were transplanted to the recipient under the kidney capsule, and the ovaries were recovered after 14 days. Subsequently, the growing preantral follicles in the ovarian grafts were isolated and cultured in vitro for 12 days. Practically, the mature oocytes ovulated from the antral follicles were able to be fertilized in vitro and support the embryonic development. The results demonstrate that the fetal mouse 16.5 dpc germ cells are able to form primordial follicles with the ovarian pregranulosa cells during the period of transplantation in the ectopic site, and the oocytes within the growing follicles are able to mature in vitro, then are able to support the embryonic development.     

Establishment of a novel method for cryopreservation and thawing of the mouse ovary

During cryopreservation of ovarian tissue, the conditions of freezing and thawing are big factors controlling the survival rate of oocytes obtained. However, the conditions and procedures as they pertain to ovarian follicles and oocytes have not been established. Thus, we tried to determine the appropriate freeze-thaw times using the vitrification method with ethylene glycol and DMSO as cryoprotective agents and dd Y female mouse ovaries. The maturity rate from GV to the metaphase-II (MII) stage was 62.8% with ethylene glycol and 69.3% using DMSO, while the controls (GV oocytes obtained from a fresh ovary) showed a maturation rate of 83.6% (46/55). MII oocytes obtained by culturing GV oocytes in vitro showed a 64.3% (18/28) fertility rate via in vitro fertilization and a developmental rate into a 2 cell stage embryo of 35.7% (10/28) and into a 4-cell stage, 7.1% (2/28). However, development beyond the 8 cell stage embryo was not observed. A significant difference was not recognized between control (fresh) and ovarian tissues that had been frozen/thawed with respect to their ability to produce hormones. It is concluded that the vitrification method was effective for both freezing ovarian tissues and preserving its functional ability (maturation and capacitation).