猪胚胎玻璃化冷冻保存技术的优化

在以往工作的基础上本研究对现有猪胚胎玻璃化冷冻保存技术进行了优化。以巴马小型猪为供体,采用超数排卵技术,采集5~6日龄的胚胎(囊胚/桑椹胚),比较冷冻方法、胚胎承载工具胚胎、透明带处理和冷冻胚胎移植受体对猪胚胎冷冻效果的影响。结果表明,冷冻方法I[胚胎首先在冷冻液1(TCM199+20%FBS+10%EG+10%DMSO)中平衡3min,然后立即转入冷冻液2(TCM199+20%FBS+20%EG+20%DMSO+0.4mol/LSUC)中并在1min内装管(每管含2~6枚胚胎),直接投入液氮保存]与冷冻方法II[透明带完整的胚胎在NCSU23(含7.5μg/mLCB)培养液中平衡25min,13000×g离心12~13min,然后在含2mol/LEG的NCSU23中平衡5min,再在含8mol/LEG+7%PVP的NCSU23中快速漂洗,装进OPS/GMP管,放入液氮保存]冷冻效果没有显著差异;GMP法能显著提高冷冻胚胎存活率(83.8%vs77.6%,P<0.05)和囊胚细胞数(47.5vs53.1,P<0.05);以0.5%链蛋白酶(Pronase)处理透明带10s,虽然对猪胚胎存活率没有显著影响,但能...     

不同防冻剂对兔胚胎干细胞慢速冷冻保存的影响

干细胞冷冻保存是干细胞研究和临床应用中的必需技术。为提高兔胚胎干细胞在慢速冻存过程中的保存效果,比较了二甲基亚砜(DMSO)和乙二醇(ethylene glycol,EG)对兔胚胎干细胞冷冻保护效果。对冷冻复苏后的细胞进行台盼蓝染色,并研究其胚胎干细胞分子特性,结果表明DMSO比EG具有更好的冷冻保护效果。再在以10%DMSO为基础的防冻液中添加膜稳定剂海藻糖(trehalose)或谷氨酰胺(glutamine),细胞冷冻复苏后结果显示,谷氨酰胺对兔胚胎干细胞有明显的冷冻保护作用,使细胞存活率从71%提高到83.7%。当谷氨酰胺浓度为0、5、10、20、40mmol/L分别加入防冻液中后,20mmol/L的谷氨酰胺具有最佳的冷冻保护效果。以上结果得出兔胚胎干细胞慢速冷冻的防冻液改进配方为:在胚胎干细胞培养液中添加10%DMSO 20mmol/L谷氨酰胺。     

3种玻璃化冷冻液对水牛MⅡ期卵母细胞冷冻-解冻后体外发育的影响

本试验主要探索了3种玻璃化冷冻液对水牛MⅡ期卵母细胞冷冻一解冻后体外发育的影响.水牛MⅡ期卵母细胞经3组玻璃化冷冻液(Ⅰ:20%乙二醇(EG)+20%二甲基亚砜(DMSO);Ⅱ:20%EG+20%丙二醇(PROH);Ⅲ:20%EG+20%PROH+10%DMSO)毒性试验后,Ⅰ、Ⅱ和Ⅲ组体外受精的分裂率、8-细胞率和囊胚率之间差异不显著(P>0.05),分裂率均显著低于对照组(P<0.05),但Ⅱ组8-细胞以后的发育潜力跟对照组无显著差异(P>0.05).进一步比较了3组玻璃化冷冻液对卵母细胞的玻璃化冷冻效果.卵子解冻后进行体外受精后,Ⅰ、Ⅱ和Ⅲ组的发育潜力均显著低于对照组(P<0.05),各组的8-细胞率和囊胚率之间无显著差异(P>0.05),但Ⅱ组卵裂率明显高于Ⅰ组(24.8±4.6%vs12.7±1.5%,P<0.05).结果表明,3种冷冻玻璃化保护液均可用于冷冻水牛MⅡ期卵母细胞,其中Ⅱ组处理的卵母细胞体外受精效果相对较好.     

猪卵母细胞体外成熟与冷冻附睾精子的体外受精

由屠宰母猪卵巢分离得到505枚卵母细胞,经成熟培养,其中468枚卵丘细胞扩张,成熟率为92.7％。采用冷冻的附睾精子授精,受精率为41.9％(57/136),其中单精受精率36.8％(50/136),多精受精率5.1％(7/136)。授精卵体外培养24和48小时后的卵裂率分别为5.3％(15/258)和12.9％(30/232)。把35枚早卵裂期胚胎和250枚未见卵裂的1-细胞期受精卵移入4头受体母猪的输卵管内,其中2头妊娠,分别于1990年4月10日和29日正常分娩,共生产仔猪21头。     

不同防冻剂对兔胚胎干细胞慢速冷冻保存的影响

干细胞冷冻保存是干细胞研究和临床应用中的必需技术。为提高兔胚胎干细胞在慢速冻存过程中的保存效果，比较了二甲基亚砜(DMSO)和乙二醇(ethylene glycol，EG)对兔胚胎干细胞冷冻保护效果。对冷冻复苏后的细胞进行台盼蓝染色，并研究其胚胎干细胞分子特性，结果表明DMSO比EG具有更好的冷冻保护效果。再在以10% DMSO为基础的防冻液中添加膜稳定剂海藻糖(trehalose)或谷氨酰胺(glutamine)，细胞冷冻复苏后结果显示，谷氨酰胺对兔胚胎干细胞有明显的冷冻保护作用，使细胞存活率从71%提高到83.7%。当谷氨酰胺浓度为0、5、10、20、40 mmol/L分别加入防冻液中后，20 mmol/L的谷氨酰胺具有最佳的冷冻保护效果。以上结果得出兔胚胎干细胞慢速冷冻的防冻液改进配方为：在胚胎干细胞培养液中添加10% DMSO＋20 mmol/L谷氨酰胺。     

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。     

三种不同冷冻保护剂对小鼠附睾冷冻效果的比较

目的探讨三种不同冷冻保护剂对C57BL/6J小鼠附睾冷冻的效果。方法性成熟并交配过的6~8周龄C57BL/6J雄鼠附睾,分别用3种不同冷冻保护剂二甲基亚砜(DMSO)、丙二醇(PROH)、R18S3进行玻璃化冷冻、复苏和精子采集,观察比较三个实验组的复苏精子形态、存活率以及生殖能力。结果三组冷冻复苏分离后的精子形态完整,具有镰刀头状结构;荧光染色后PROH组精子存活率为(88.17±3.43)%,明显高于DMSO组:(61.17±10.65)%和R18S3组(16.83±6.49)%(P0.05);经辅助体外受精后均具有受精能力。获得的胚胎移植后可得到正常子代小鼠(DMSO∶PROH∶R18S3=13∶8∶17)。结论 3种冷冻保护剂均适用于C57BL/6J小鼠附睾冷冻,但PROH冷冻效果较好。     

白鹤冷冻精液人工授精实验

为了探索鹤类精液冷冻保存和使用技术,2003～2005年,进行了白鹤(Grus leucogeranus)的冷冻精液保存及人工授精实验。使用Beltsville家禽精液稀释液作为白鹤精液稀释液,12%的二甲基亚砜(DMSO)为冷冻液。精液样本冷冻经过三个阶段的降温,最后保存在液氮中。成功保存了编号93001雄性白鹤精液36 支（0.2 ml/支）。冷冻精液在0~4℃冰水中解冻3~5 min,解冻后白鹤精液精子活率为29.3%±15.5%（n=16）,2004和2005年分别为92101号雌鹤产的两窝卵进行人工授精实验,2年共产卵5枚,其中1枚卵受精并成功孵化。实验发现在雌鹤产卵前一周和产卵期间每天输精,并增加每次输精量,同时在产完1枚卵后4 h内完成一次输精,效果最佳。     

鲈鱼胚胎的玻璃化冷冻保存

本文对鲈鱼(Lateolabrax japonicus)胚胎进行了玻璃化冷冻保存研究,筛选出了浓度较低、玻璃化程度较稳定的5种玻璃化液,冷冻时形成玻璃化的概率在48．1％～100％,在35～43℃的水浴中解冻时保持玻璃化的概率在44．4％～63．0％;玻璃化液VSD2在解冻时保持玻璃化的概率最高。对鲈鱼神经胚、20对肌节胚、尾芽胚、心跳胚、出膜前胚在玻璃化液VSD2中的适应能力及适合于玻璃化冷冻的胚胎时期进行了比较,结果显示：不同时期胚胎对玻璃化液的耐受能力不同,鲈鱼神经胚耐受能力最低,心跳胚耐受能力最强,出膜前期胚次之,心跳胚和出膜前胚适合于进行玻璃化冷冻。对0．5mol/L蔗糖的洗脱时间进行了选择,结果显示,洗脱10～20min效果较好。利用玻璃化程度较好的VSD2对鲈鱼不同时期胚胎进行超低温(-196℃)冷冻,获得了2．1％～27．9％的透明胚。将鲈鱼心跳胚冷冻解冻后获2粒复活胚,培养至出膜期,成活42～50h;出膜前期胚在冷冻解冻后有1粒胚复活,并且孵化出鱼苗[动物学报49(6)：843～850,2003]。     

体细胞核移植克隆民猪: 培养液对卵母细胞成熟及胚胎发育的影响

体外培养成熟的卵母细胞是进行克隆猪研究所需受体卵母细胞的主要来源, 卵母细胞成熟质量与体细胞核移植胚胎发育能力关系密切. 为提高卵母细胞体外成熟率和成熟质量, 进而提高体细胞核移植猪的成功率, 本实验以改进的TCM199培养液为基础液(T), 分别添加10%的猪卵泡液(T+pFF)和 10%的胎牛血清(T+FBS)后进行卵母细胞成熟培养, 以成熟率和体细胞核移植胚胎发育率等重要指标为标准, 研究了pFF和FBS对卵母细胞成熟及核移植胚胎发育能力的影响. T, T+pFF和T+FBS组在成熟培养后42 h卵母细胞成熟率分别为(53.2±3.8)%, (69.7±3.8)%和(70.2±3.7)%, 添加10%的pFF和FBS显著(P<0.05)提高了卵母细胞成熟率; 3组不同成熟培养液获得的成熟卵母细胞在体细胞核移植后囊胚发育率差异不显著, 但T+pFF组的囊胚细胞数(34.5±2.24)显著(P<0.05)高于T组的囊胚细胞数(26.6±1.25). 来自T+pFF组的体细胞核移植胚胎经手术法移植入发情周期为第0天或第1天的18头受体母猪输卵管, 其中有3头受体母猪妊娠发育到期, 获得克隆民猪14头, 其中有6头健康成活至今. 实验结果表明, 培养液中添加10%pFF可以有效提高卵母细胞成熟比例和成熟质量, 在含有10% pFF培养液中获得的成熟卵母细胞具有支持核移植胚胎全程发育的能力.     

Successful vitrification of pronuclear-stage rabbit zygotes by minimum volume cooling procedure

Rabbit zygotes at the pronuclear-stage were cryopreserved by vitrification using a gel-loading tip (GL-tip), Cryoloop or Cryotop. In GL-tip and Cryoloop methods, zygotes were first exposed to 10% ethylene glycol (EG)+10% DMSO in TCM199+20% fetal bovine serum (FBS) for 2 min, and then equilibrated for 30 s in a vitrification solution composed of 20% EG+20% DMSO+0.6 M sucrose in TCM199+20% FBS. In Cryotop method, zygotes were first exposed to 7.5% EG+7.5% DMSO+20% FBS in TCM199 for 3 min, and then equilibrated for 1 min in a vitrification solution composed of 15% EG+15% DMSO+0.5 M sucrose+20% FBS in TCM199. In vitro culture of vitrified-warmed zygotes using GL-tip and Cryoloop resulted in low cleavage rates (2 and 5%, respectively) and no development into blastocysts. In contrast, zygotes vitrified-warmed using Cryotop exhibited higher proportions of cleavage (58%) and development into blastocysts (24%). When compacted morulae or early blastocysts were vitrified by these three procedures, 80-93% of them exhibited blastocoele expansion or zona hatching during the subsequent 48 h of culture. Use of Cryotop instead of GL-tip or Cryoloop for zygote vitrification, without changing conditions of solutions and periods for exposure, equilibration and post-warm dilution, resulted in cleavage and blastocyst development rates of 88 and 45%, respectively. A longer exposure time (10 min) of zygotes to 7.5% EG+7.5% DMSO+20% FBS in TCM199 resulted in higher proportions of zygotes cleaving (94%) and developing into blastocysts (51%) after Cryotop vitrification. Proportions of post-warm zygotes (10-min exposure group) and fresh control zygotes developing into newborn offspring were 36 and 53%, respectively. Pronuclear-stage rabbit zygotes were successfully cryopreserved by vitrification using the Cryotop method.     

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.     

Factors affecting the survival,fertilization, and embryonic development of mouse oocytes after vitrification using glass capillaries

Cryopreservation of mammalian oocytes is an important way to provide a steady source of materials for research and practice of parthenogenetic activation, in vitro fertilization, and nuclear transfer. However, oocytes cryopreservation has not been common used, as there still are some problems waiting to be solved on the repeatability, safety, and validity. Then, it is necessary to investigate the damage occurred from vitrification and find a way to avoid or repair it. In this study, mouse mature oocytes were firstly pretreated in different equilibrium media, such as 5% ethylene glycol (EG) + 5% dimethyl sulfoxide (DMSO), 10% EG + 10% DMSO, and 15% EG + 15% DMSO in TCM199 supplemented with 20% fetal calf serum (FCS), for 1, 3, and 5 min, respectively, and then oocytes were transferred into vitrification solution (20% EG, 20% DMSO, 0.3 M sucrose, and 20% FCS in TCM199, M2, Dulbecco’s phosphate buffered saline, and 0.9% saline medium, respectively) and immediately loaded into glass capillaries to be plunged into liquid nitrogen. After storage from 1 h to 1 wk, they were diluted in stepwise sucrose solutions. The surviving oocytes were stained for cortical granule, meiotic spindles, and chromosomes. Oocytes without treatments were used as controls. The results showed that oocytes pretreated in 5% EG +5% DMSO group for 3–5 min or in 10% EG + 10% DMSO group for 1–3 min were better than other treatments. Oocytes vitrified in TCM199 as basic medium showed higher survival and better subsequent embryonic development than other groups. When the concentration of FCS in vitrification solution reduced below 15%, the rates of survival, fertilization, and developing to blastocyst declined dramatically. The inner diameter (0.6 mm) of glass capillaries and amount of vitrification solution (1–3 μl) achieved more rapid cooling and warming and so reduce the injury to oocytes. Cropreservation led to the exocytosis of cortical granule of oocytes (about 10%) and serious disturbance of microtubules and chromosomes. With 2 h incubation, the microtubules could repolymerize and the rate of fertilization in vitro was much higher than those of 1 and 3 h incubation groups. In conclusion, the protection of basic medium and FCS to oocytes during cryopreservation and sufficient cooling and warming rates using glass capillaries have profound effects on oocytes survival and subsequent embryonic development competence. The appropriate time for fertilization in vitro may be related to the recovery of spindles after incubation and avoiding ageing in the whole process.     

In vitro development of vitrified buffalo oocytes following parthenogenetic activation and intracytoplasmic sperm injection

The objective of this study was to investigate the potential of swamp buffalo oocytes vitrified-warmed at the metaphase of the second meiotic cell division (M-II) stage to develop to the blastocyst stage after parthenogenetic activation (PA) or intracytoplasmic sperm injection (ICSI). In Experiment 1, we examined the effects of exposure time of oocytes to cryoprotectants (CPA) on their in vitro development after PA. In vitro matured (IVM) oocytes were placed in 10% dimethylsulfoxide (DMSO) + 10% ethylene glycol (EG) for 1 min and then exposed to 20% DMSO + 20% EG + 0.5 M sucrose for 30 s, 45 s or 60 s (1 min + 30 s, 1 min + 45 s and 1 min + 60 s groups, respectively). The oocytes were then exposed to warming solution (TCM199 HEPES + 20% FBS and 0.5M sucrose) for 5 min and then washed in TCM199 HEPES + 20% FBS for 5 min. IVM oocytes without CPA treatments served as a control group. The viability assessed by fluorescein diacetate (FDA) staining was 100% in all groups. The developmental rates after PA to the blastocyst stage between 1min+30s (16%) and control (26%) groups did not differ significantly, but they were significantly higher than those in 1 min + 45 s (10%) and 1 min + 60 s (2%) groups. In Experiment 2, we examined the effect of two CPA exposure times, 1 min + 30 s and 1 min + 45 s on the in vitro development after PA of oocytes vitrified by the microdrop method. The viabilities in vitrified 1 min + 30 s, 1 min + 45 s and the control (without CPA treatments) groups were not different (97%, 95% and 100%, respectively). The development of surviving oocytes to the blastocyst stage in the vitrified 1 min + 30 s group (8%) was significantly higher than that in the vitrified 1 min + 45 s group (4%) and significantly lower than those in control group (26%). In Experiment 3, we examined the effect of two CPA exposure times, 1 min + 30 s and 1 min + 45 s on in vitro development after ICSI of vitrified oocytes. Viabilities in vitrified oocytes among 1 min + 30 s, 1 min + 45 s and control groups were not different (96%, 91% and 100%, respectively). After ICSI, vitrified-warmed oocytes were activated and oocytes with the second polar body were cultured for 7 days. The development of ICSI oocytes to the blastocyst stage in the vitrified 1 min + 30 s group (11%) was significantly higher than that in the vitrified 1 min + 45 s (7%) group and significantly lower than those in control group (23%). In conclusion, our study demonstrated that the 1 min + 30 s CPA treatment regimen could yield the highest blastocyst formation rates after PA and ICSI for oocytes vitrified by the microdrop method.     

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.     

Effect of macromolecules in solutions for vitrification of mature bovine oocytes

This study was designed to evaluate vitrification procedures for in vitro matured bovine oocytes for efficient blastocyst production after warming, IVF and culture. A second goal was to replace serum as the macromolecular component of the vitrification solution, without compromising efficacy. The first experiment compared two containers, open pulled straws (OPS) versus cryoloops, and two vitrification protocols: short equilibration (H-TCM-199+10% EG+10% DMSO+20% FCS for 30s, followed by H-TCM-199+20% EG+20% DMSO+20% FCS+0.48M galactose for 20s) versus long equilibration (H-TCM-199+3% EG+20% FCS for 10min, followed by H-TCM-199+31% EG+20% FCS+1M galactose for 20s). Subsequent experiments used only cryoloops and the short equilibration protocol to evaluate the effect of replacing FCS with defined macromolecules (BSA, Ficoll, PVP, and PVA) in vitrification solutions. Cryoloops were superior to OPS for vitrification of oocytes as determined by blastocyst production (P<0.05). The short and long vitrification protocols gave similar results. The presence of macromolecules in vitrification solutions for bovine oocytes was necessary for acceptable post-warming developmental capacity; 20% FCS, 1% and 2% BSA, 6% and 18% Ficoll, 6% and 20% PVP, 1% PVA, and the combinations of 18% Ficoll+1% BSA, and 6% PVP+1% BSA provided similar protection during vitrification of oocytes; development ranged from 14.8% to 23.0% blastocysts/oocyte, which was not different (P>0.05) from non-vitrified controls (26.9-34.0% blastocysts/oocyte). Too much (6%) and too little (0.3%) BSA, and 0.3% PVA for vitrification resulted in lower blastocyst production (P<0.05) relative to unvitrified oocytes.     

Effects of different cryopreservation methods on post-thaw culture conditions of in vitro produced bovine embryos

The aim of this work was to evaluate the effect of cryopreservation protocols on subsequent development of in vitro produced bovine embryos under different culture conditions. Expanded in vitro produced blastocysts (n = 600) harvested on days 7-9 were submitted to controlled freezing [slow freezing group: 10% ethylene glycol (EG) for 10 min and 1.2°C/min cryopreservation]; quick-freezing [rapid freezing group: 10% EG for 10 min, 20% EG + 20% glycerol (Gly) for 30 s]; or vitrification [vitrification group: 10% EG for 10 min, 25% EG + 25% Gly for 30 s] protocols. Control group embryos were not exposed to cryoprotectant or cryopreservation protocols and the hatching rate was evaluated on day 12 post-insemination. In order to evaluate development, frozen-thawed embryos were subjected to granulosa cell co-culture in TCM199 or SOFaa for 4 days. Data were analyzed by PROC MIXED model using SAS Systems for Windows?. Values were significant at p < 0.05. The hatching rate of the control group was 46.09%. In embryos cultured in TCM199, slow freezing and vitrification group hatching rates were 44.65 ± 5.94% and 9.43 ± 6.77%, respectively. In embryos cultured in SOFaa, slow freezing and vitrification groups showed hatching rates of 11.65 ± 3.37 and 8.67 ± 4.47%, respectively. In contrast, the rapid freezing group embryos did not hatch, regardless of culture medium. The slow freezing group showed higher hatching rates than other cryopreservation groups. Under such conditions, controlled freezing (1.2°C/min) can be an alternative to cryopreservation of in vitro produced bovine embryos.     

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.     

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.     

Effects of Nu-Serum® on in vitro development of goat (Capra hircus) embryos

To evaluate the effects of a commercially produced serum substitute on the in vitro development of caprine embryos, registered Nubian doelings were synchronized with norgestomet-impregnated implants (Synchromate-B®: CEVA) and superovulated with descending doses of FSH-p® (Schering). A total of 246 embryos was collected and placed in Tissue Culture Medium 199 (TCM 199, Gibco Laboratories) containing Nu-Serum® (NuS) at concentrations of 2.5%, 5.0%, 10%, or 20%. Control treatments consisted of TCM 199 alone or TCM 199 plus 10% heat-inactivated fetal bovine serum (FBS). Embryos developed in all concentrations of NuS to the morula, blastocyst, and expanded blastocyst stages. The TCM 199 plus 10% NuS had significantly higher percentages of embryos developing to the expanded blastocyst stage than TCM 199 plus 10% FBS. Time to expanded blastocyst development in NuS was shorter than in the TCM 199 plus FBS. No stage-specific block to development was observed with embryos collected and cultured in vitro for any of the treatments. These results demonstrate that NuS, when compared to FBS, allowed a higher percentage (P < 0.05) of caprine embryos to develop to the expanded blastocyst stage, thus providing a valuable substitute for FBS.