一种非手术性小鼠胚胎移植技术

为了提高非手术性小鼠胚胎移植技术的成功率,利用塑料移植导管模拟非手术胚胎移植过程,通过观察染料在子宫角的分布而评估胚胎移植效果,并在此基础上将自然妊娠3.5 d的小鼠囊胚经子宫颈移植受体小鼠。结果表明:将CD-1小鼠囊胚移植假孕2.5 d小鼠单侧子宫角,平均70.9%的胚胎能够发育至成活新生仔鼠,建立了高效非手术性小鼠胚胎移植技术。该方法简便快捷、不易污染、费用低,无需专业的手术器械,且符合实验动物伦理原则,完全可以取代手术法胚胎移植技术,更重要的是,它为人类和其他大动物的胚胎移植提供了研究模型。     

A simple technique for nonsurgical embryo transfer in mice

A simple method was developed for nonsurgical transfer of mouse embryos which enabled transfer to both uterine horns. Embryos were picked up in a modified capillary tube and transferred through the cervix into each uterine horn of an unanesthetized mouse. A glass speculum was used to facilitate location of the cervix. The technique was found to be as successful (up to 60% of embryos transferred developed to term) as surgical methods yet was simpler and eliminated surgical trauma to the recipient mouse.     

A study of nonsurgical embryo transfer in the mare

The success rate of nonsurgical embryo recovery was influenced neither by year nor by season within years. The preferred method of nonsurgical embryo transfer was by Cassou pistolette. From a total of 15 attempts to transfer embryos nonsurgically, 9 (60%) were successful. Of the five attempts during February through April 1982, only one was successful in producing a live foal. The degree of synchrony between the ovulations of the donors and recipients in these five attempts ranged from +3 to -3 d. The recipient of the successful transfer ovulated on the same day as the donor. Eight of the ten attempts during September through December 1982 produced live foals. Synchronization of ovulations between the donors and recipients in these transfers ranged from 0 to -2 d. Repeated attempts to recover embryos had no deleterious effects on fertility of the donors.     

Successful nonsurgical deep uterine embryo transfer in pigs

At present, it is possible to transfer pig embryos directly into the uterine body of sows by nonsurgical procedures. The aim of this study was to develop a procedure for nonsurgical embryo transfer (ET) into the upper part of one uterine horn in gilts and sows. In experiment 1, 29 gilts and 43 sows were used. Intrauterine insertions took place for each female at days 4-6 of the estrous cycle (D0 = onset of estrus). An artificial insemination (AI) spirette was inserted into the cervix to assist with the guidance of a modified flexible catheter originally developed for deep intrauterine insemination in pigs. The flexible catheter length inserted anterior to the inserted AI spirette was 43.0 +/- 1.7 cm. The time required to complete the procedure was affected by the type of female (P < 0.001) and by the difficulties encountered for inserting the catheter (P < 0.001). However, when no or minor difficulties were encountered during the insertion of the catheter (in approximately 70 and 80% of gilts and sows, respectively), the time required to complete the procedure did not differ between gilts (2.5 +/- 0.1 min) and sows (2.3 +/- 0.1 min). In experiment 2, 24 to 31 fresh morulae and/or blastocysts were transferred to each of 24 recipients. Seventeen animals (70.8%) farrowed an average of 6.9 +/- 0.7 piglets, of which 0.6 +/- 0.3 piglets were born dead. In conclusion, the procedure described in this study offers new possibilities to transfer embryos nonsurgically to the uterine horn of pigs.     

Improving successful pregnancies after embryo transfer

Over the past 20 years the rate of blastocyst development in vitro has improved through the development of sequential defined media, refining the oxygen concentrations during culture and providing substrates to ameliorate free radical accumulation. Despite these advances there has been little progress in improving calving rates after the transfer of in vitro produced embryos. This suggests that the culture conditions have been very effective in enabling those fertilised oocytes to reach the blastocyst stage that otherwise would not occur in vivo.We suggest that the next advance by which the embryo transfer technology gains more acceptance in cattle production will be identifying those cows which are intrinsically superior recipients. This must be coupled to the development of non-invasive assessments of the developmental competence of both the oocyte and the blastocyst. Until these two goals are achieved the ET industry will remain static and unable to overcome the economic loss caused by embryo mortality occurring 7-10 days after transfer.     

Successful nonsurgical embryo transfer in buffalo (Bubalus bubalis ) in Bulgaria

Forty-one Day 5.0 to Day 5.5 embryos and one unfertilized ovum were recovered nonsurgically from 24 superovulated, parous buffalo (Bubalus bubalis ) and transferred nonsurgically to 28 synchronized recipients by a team of Bulgarian and American scientists. Five pregnancies were established and four live buffalo calves were born at the end of normal gestation periods.     

Factors affecting the success of surgical and nonsurgical equine embryo transfer

Nonsurgical embryo recovery was attempted from light-horse and draft mares. Embryo recovery rates were not affected (P>.05) by technician or stallion but were lower (P<.05) from draft mares (44%) than light-horse mares (67%). Sham transfer of embryos on day 8 post-ovulation did not (P>.05) increase the number of mares returning to estrus by 22 days post-ovulation. Method of embryo transfer greatly affected pregnancy rates. Embryos transferred surgically during March–June resulted in 0 of 12 pregnancies versus 13 of 25 pregnancies obtained during July–September, This strongly suggests a seasonal influence on pregnancy rates. Technician influenced (P<.05) the success of nonsurgical transfer (46.2% vs. 7.7%). In addition, protection of the insemination rod with a sheath (guarded method) appeared to provide some advantage over an unguarded method of nonsurgical transfer (54% vs. 23%). Lastly, a preliminary experiment was conducted to evaluate transfer of embryos via flank incision. Four of 5 embryos transferred by this method resulted in a pregnancy at 50 days post estrus.     

Improved pregnancy and birth rates with routine application of nonsurgical embryo transfer

Nonsurgical embryo transfer (NSET) of blastocysts to pseudopregnant female recipients provides many benefits over surgical implantation with less distress for the mice, no anesthesia or analgesia required and a considerable reduction in implantation time per mouse. Although a disposable device to perform NSET is on the market since 2009, it is not generally used in transgenic facilities, most likely because surgical implantation is efficient and inexpensive. Here, we report that with several refinements to the original protocol, the NSET method becomes very attractive and outperforms the traditional surgical transfer on basis of pregnancy rate, birth rate and implantation-related discomfort. Furthermore, repeated use of the same NSET device on several recipient females reduces the costs to a reasonable level. The data presented covers all embryo transfers over the last 5 years at the transgenic facility of the Netherlands Cancer Institute, of which the last 2 years were performed exclusively with NSET.     

Embryo recovery rate and recipients’ pregnancy rate after nonsurgical embryo transfer in donkeys

Sixty-three embryos were recovered out of 83 estrous cycles (75.9%) and 98 ovulations (64.3%) of five Pantesca jennies, 2 to 5 yr old, naturally mated or artificially inseminated with fresh semen. Embryo recovery rate was influenced by number of ovulations per cycle (133% and 63% for double and single ovulations, respectively), by the day of embryo recovery attempt (12%, 83%, and 75% at Days 7, 8, and 9 after ovulation, respectively), and by the repetition of the embryo recovery attempt on successive cycles (60%, 79%, and 100% for cycles 1 to 7, 8 to 14, and 15 to 24, respectively). All recovered embryos but three were classified as good or excellent. Of 58 nonsurgical embryo transfers to Ragusana jenny recipients, 13 (22.4%), 10 (17.2%), and 9 (15.5%) resulted in a pregnancy at Days 14, 25, and 50, respectively. Recipients’ pregnancy rate was not influenced by the evaluated parameters: embryo quality and age, media employed to wash embryos, days after ovulation of the recipient, experience of the operator. Between 14 and 50 d of pregnancy, 4 of 13 (30.7%) embryos were lost with an influence of the days from ovulation of the recipient: recipients at Days 5 or 6 kept all pregnancies (N = 7), whereas recipients at Days 7 or 8 lost 3 of 4 pregnancies, as one of the two recipients at Day 3. More studies are needed before embryo transfer could be considered a reliable tool to preserve endangered donkey breeds.     

The effects of superovulation of donor sows on ovarian response and embryo development after nonsurgical deep-uterine embryo transfer

This study aimed to evaluate the effectiveness of superovulation protocols in improving the efficiency of embryo donors for porcine nonsurgical deep-uterine (NsDU) embryo transfer (ET) programs. After weaning (24 hours), purebred Duroc sows (2–6 parity) were treated with 1000 IU (n = 27) or 1500 IU (n = 27) of eCG. Only sows with clear signs of estrus 4 to 72 hours after eCG administration were treated with 750 IU hCG at the onset of estrus. Nonhormonally treated postweaning estrus sows (n = 36) were used as a control. Sows were inseminated and subjected to laparotomy on Days 5 to 6 (Day 0 = onset of estrus). Three sows (11.1%) treated with the highest dosage of eCG presented with polycystic ovaries without signs of ovulation. The remaining sows from nonsuperovulated and superovulated groups were all pregnant, with no differences in fertilization rates among groups. The number of CLs and viable embryos was higher (P < 0.05) in the superovulated groups compared with the controls and increased (P < 0.05) with increasing doses of eCG. There were no differences among groups in the number of oocytes and/or degenerated embryos. The number of transferable embryos (morulae and unhatched blastocysts) obtained in pregnant sows was higher (P < 0.05) in the superovulated groups than in the control group. In all groups, there was a significant correlation between the number of CLs and the number of viable and transferable embryos, but the number of CLs and the number of oocytes and/or degenerated embryos were not correlated. A total of 46 NsDU ETs were performed in nonhormonally treated recipient sows, with embryos (30 embryos per transfer) recovered from the 1000-IU eCG, 1500-IU eCG, and control groups. In total, pregnancy and farrowing rates were 75.1% and 73.2%, respectively, with a litter size of 9.4 ± 0.6 piglets born, of which 8.8 ± 0.5 were born alive. There were no differences for any of the reproductive parameters evaluated among groups. In conclusion, our results demonstrated the efficiency of eCG superovulation treatments in decreasing the donor-to-recipient ratio. Compared with nonsuperovulated sows, the number of transferable embryos was increased in superovulated sows without affecting their quality and in vivo capacity to develop to term after transfer. The results from this study also demonstrate the effectiveness of the NsDU ET procedure used, making possible the commercial use of ET technology by the pig industry.     

A one-step method for direct nonsurgical transfer of frozen-thawed bovine embryos

One impediment to the more widespread use of freezing as an adjunct to embryo transfer in cattle has been the method used to remove the protective compound from the thawed embryos. Recently, a method has been developed that permits bovine embryos to be diluted out of the protective solution within the plastic straw in which the embryos were originally rrozen and thawed. The method requires only about 10 minutes to perform and does not require a microscope or other laboratory equipment. Therefore, frozen bovine embryos can be thawed, diluted, and transferred nonsurgically into recipient cattle under conditions quite similar to those used for artificial insemination. A large number of field trials of this method have been performed during the past 2 1 2 years. A total of 327 pregnancies have been established by the nonsurgical transfer of 1259 embryos that had been frozen, thawed, and diluted by this method.     

Embryo survival in pseudopregnant and in pregnant but genetically semi-sterile recipients after nonsurgical embryo transfer in the mouse

A new nonsurgical embryo transfer technique was used in the mouse that yielded survival rates of between 40 and 70% depending on embryo stage and, possibly, on the degree of synchrony between the embryo and recipient. Three variables were tested using this embryo transfer technique: a) pseudopregnant recipients vs pregnant but genetically semi-sterile recipients, b) embryos resulting from superovulation vs embryos from natural ovulation, and c) 12-hour vs 24-hour asynchrony between donors and recipients. None of these variables significantly affected the pregnancy rate or the percentage of transferred embryos developing to term. The pregnancy rates were between 77 and 90% in 6 experimental groups of 8 to 13 females. Survival rates were between 41 and 63% when all recipients were considered and between 53 and 68% when only the pregnant recipients were included. The embryo transfer procedure influenced litter size composition of the endogenous conceptuses of the semi-sterile recipients. Too many females were devoid of these. Recipients of expanded blastocysts had significantly better transfer results than recipients that also received morulae and early blastocysts. It was concluded that the transfer success rates were influenced by the recipients and possibly by their preparation for transfer.     

Factors affecting pregnancy rate following nonsurgical embryo transfer in buffalo (Bubalus bubalis): a retrospective study

The objectives of this study were to determine the pregnancy rate and factors affecting it following nonsurgical embryo transfer in buffalo. Donor buffalo were superovulated with FSH, and embryos collected nonsurgically were evaluated for stage of development and quality. They were transferred nonsurgically to 91 recipients on Days 5 to 7 of the natural (n = 52) or induced (n = 39) estrus (estrus = Day 0). The overall pregnancy rate of 24/91(26.4%) was higher than in earlier reports for buffalo but was much lower than in cattle. Pregnancy rates were not affected by season (autumn vs winter), side of transfer (right vs left uterine horn), or type of estrus (spontaneous vs induced). The pregnancy rate was high 11/27(40.7%) when donors and recipients were closely synchronized, while it was compromised when recipients were in estrus at +12 h (1/7, 14.3%) and at -12 h (5/27, 18.5%). Asynchrony beyond 12 h on either side resulted into conception failure. The pregnancy rate tended to increase with the increase in CL size of recipients, while stage of embryonic development had no effect. The transfer of an 8-cell embryo with a 16-cell embryo led to the birth of heterosexual twins, indicating that the uterine milieu of Day 5 to 6 recipients may be tolerated by the out-of-phase 8-cell embryo, at least in the presence of a more mature embryo. Embryo quality had the greatest effect on pregnancy rate as it was higher (P < 0.005) after the transfer of Grade I than Grade III embryos (6/10, 60.0% vs 3/36, 13.9%). Assessment of returns to estrus indicated that among nonpregnant recipients, 17/67 (25.4%) embryos never matured sufficiently to prevent luteolysis through maternal recognition of pregnancy (MRP), while 14/67 (20.8%) embryos probably died following MRP. These results indicate that efforts to increase pregnancy rate following embryo transfer in buffalo should include prevention of luteolysis during the first week of transfer and a reduction in the incidence of embryonic mortality.     

A consistently successful procedure for in vitro fertilization of golden hamster eggs

Complete details are described for the first time of the procedures used in the author's laboratory for obtaining in vitro fertilization (IVF) of golden hamster eggs leading to the first cleavage division. These IVF procedures have been developed during the past 20 years and are very reproducible: IVF of at least 75% of eggs is routinely achieved, and on average 65% of inseminated eggs undergo the first cleavage division in vitro. These results can easily be obtained by inexperienced investigators. The ease and reproducibility of the hamster IVF procedures make them very suitable for studies of sperm:egg interaction and associated events. Studies in the author's laboratory have included analysis of sperm fertilizing ability under chemically defined conditions, the presence of sperm acrosome reaction stimulating factors in the egg investments, maturation of oocytes in vitro, the block to polyspermy, and the contribution of egg aging to fertilization anomalies. In addition, the motility of hamster sperm under chemically defined conditions is used in a routine screening protocol for detecting contaminants in the culture milieu. Golden hamster gametes of Ter several distinct advantages for IVF studies, including the large size of the sperm acrosome, the persistence of the very large sperm tail in the ooplasm for many hours following fertilization, and the translucence of the ooplasm, which facilitates observation of the sperm tail and pronuclei. The female golden hamster exhibits a regular 4 day estrous cycle, with distinctive indications of estrus and postestrus phases. Because of the advantages of using the golden hamster, the procedures described in this report may be useful to other investigators wishing to conduct research using IVF. Essentially the same IVF procedures can be used with monkey and bovine gametes.