水牛分离精子与不同来源卵母细胞体外受精的效果研究

本研究的目的是探讨水牛分离精子与不同来源(活体采卵或屠宰场卵巢采卵)卵母细胞体外受精的效果。活体采卵是选用20头空怀河流型母水牛(其中摩拉母牛12头,尼里-拉菲母水牛8头)每间隔3 d采卵1次,连续采卵5~6周,活体采集卵母细胞;屠宰场卵巢采卵是收集屠宰场水牛卵巢,用10 mL注射器连接18 G针头吸取水牛卵巢上可视的卵泡来收集卵母细胞。将收集的AB级水牛卵母细胞在相同的条件下进行体外成熟、然后用分离或未分离精子进行体外受精以及体外培养至囊胚。结果发现:活体采卵组和屠宰场收集的水牛卵母细胞组用分离精子受精分裂率和囊胚率没有差异(P>0.05);分离精子和未分离精子的体外受精分裂率和囊胚率也没有差异(P>0.05)。由此说明,水牛分离精子可以用于体外生产性控胚胎。     

Effect of aspiration pressure during oocyte harvesting on oocyte recovery and in vitro development of ovine oocytes.

Oocytes from abattoir-sourced ovine ovaries were aspirated from 2- to 4-mm follicles using 25, 50 or 100 mmHg pressure and an aspiration pump, or a needle (20-G) and syringe (2.5 ml) and subjected to in vitro maturation, fertilization and culture to determine the effect of aspiration pressure on the number and quality of oocytes recovered, and early embryonic development. Oocyte recovery rate was similar between groups (range: 57.1-73.1%; p > 0.05). The number and percentage of grade I and II oocytes recovered was reduced for 100 mm (24.5 +/- 3.6 and 31.1 +/- 6.1%) compared with 25 mm (51.4 +/- 7.0 and 60.2 +/- 7.8%) and 50 mm pressure (40.8 +/- 5.6 and 50.3 +/- 4.4%) and a syringe (40.3 +/- 12.0 and 45.2 +/- 2.1%; p < 0.05). Oocyte cleavage was similar for all groups at 24 (range: 30.9-49.6%) and 48 h post-insemination (49.7-65.5%), but blastocyst formation (% cleaved oocytes) was lower for oocytes aspirated with 25 mm (37.8%) than 50 (69.2%) or 100 mm (67.2%) pressure, and a syringe (72.0%; p < 0.05). Embryo production efficiency (% of oocytes cultured developing to the blastocyst stage) was higher for oocytes aspirated with 50 mm (45.4%) and 100 mm pressure (43.8%) and a syringe (45.0%) than 25 mm pressure (18.8%; p < 0.05). These results demonstrate that the aspiration of ovine oocytes with an aspiration pressure of 50 mm, or aspiration with a needle and syringe are equally efficacious for the in vitro production of embryos.     

Ovum Pick-up in Cycling and Lactating Postpartum Swamp Buffaloes (Bubalis bubalis)

The objective of this study was to evaluate the efficiency of Ovum Pick Up (OPU) in cycling (n = 5) and lactating, postpartum, swamp buffaloes (n = 6) with and without gonadotropin stimulation. The OPU was performed every two weeks in all groups of animals, for a total of six sessions. Thirty collections were performed in five cycling buffaloes and 36 collections in six lactating postpartum buffaloes. Buffaloes that received hormonal stimulation were given a total of 400 mg, follicle stimulating hormone (FSH), administered twice daily over 3 days in decreasing doses, together with 100 microg of GnRH, 24 h after the last FSH injection. Following a resting period of 1 month, the two groups of buffaloes, were subjected to the same OPU regimen, but without any hormonal treatment for an additional six OPU sessions. The number of aspirated follicles recorded from the hormonal stimulated, cycling animals and lactating, postpartum buffaloes was not significantly different, 7.2 +/- 3.7 and 9.0 +/- 3.2, respectively (p > 0.05). Recovered oocytes collected from the two groups of hormonally stimulated animals were also not statistically different: 3.7 +/- 2.7 in the cycling and 5.9 +/- 3.5 in the lactating postpartum group (p > 0.05). In the two groups of buffaloes not receiving hormonal stimulation, the number of aspirated follicles was not significantly different: 2.1 +/- 1.4 and 1.4 +/- 0.7 in cycling and lactating postpartum buffaloes respectively (p > 0.05). Recovered oocytes in the non-treated groups were also similar: 1.4 +/- 1.3 vs 0.7 +/- 0.8 in cycling and lactating buffaloes (p > 0.05). Among stimulated buffaloes, most aspirated follicles were small in size (< or =5 mm), whereas they were mostly medium and large sizes in the non-treated buffaloes. The oocyte recovery rate in both the groups, cycling and lactating postpartum, were 51.6% and 69.5% in stimulated groups and 55.0% and 53.1% in non-stimulated groups (p > 0.05). The majority of recovered oocytes were single- and multi-layered, and the number was greater in the cycling than in the lactating, postpartum buffaloes. The number and quality of recovered oocytes was similar in all groups of buffaloes whether they were received or did not receive hormonal stimulation. Moreover no difference was found in multi- and single-layered oocytes between cycling and lactating, postpartum buffaloes. In conclusion, OPU can be performed successfully in swamp buffalo in different reproductive status and FSH administration was shown to increase the number of aspirated oocytes in both cycling and lactating, postpartum buffaloes.     

Maturation competence of swamp buffalo oocytes obtained by ovum pick-up and from slaughterhouse ovaries

This study was designed with the final goal of improving in vitro embryo production in the Thai swamp buffalo (Bubalus bubalis carabensis). Oocytes were collected by ovum pick-up (OPU) from six non-lactating multiparous swamp buffalo twice per week for 10 consecutive sessions followed by once-weekly collection for 10 consecutive sessions without hormone stimulation. In addition, oocytes were collected from slaughterhouse ovaries that were classified as follows: ovaries from non-pregnant cows with a visible corpus luteum (NPCL); pregnant cows with a corpus luteum (P); and non-pregnant cows without a corpus luteum (NP). Follicles in each group of ovaries were categorized as small (2-4 mm), medium-sized (5-8 mm) or large follicles (≥ 9 mm). The quality of the oocytes was assessed by their capacity to undergo in vitro maturation. The total number of observed follicles per session (all sizes combined) was larger in the once-weekly OPU group compared with the twice-weekly OPU group. In particular, the numbers of small and large follicles were higher in the once-weekly OPU group (5.2 ± 0.7 and 0.9 ± 0.2, respectively) than in the twice-weekly OPU group (3.9 ± 0.5 and 0.5 ± 0.1). The number of medium-sized follicles did not differ between the groups. The percentages of oocytes with an abnormal spindle morphology were not different between oocytes from the twice-weekly (30.0%) and the once-weekly (28.6%) OPU groups. A higher percentage of oocytes obtained in vitro (49.5%) exhibited nuclear abnormalities compared with those obtained in vivo (≤34.8%) after in vitro maturation. In conclusion, oocytes can be successfully collected by OPU in the swamp buffalo, without hormonal pretreatment, and per week more good-quality oocytes can be collected by twice-weekly OPU. In addition, oocytes collected from slaughterhouse ovaries can be used with the reproductive status of the cow having no influence on the maturation competence of oocytes.     

Oocyte transfer in the mare: Preliminary observations

Six oocytes were aspirated from preovulatory follicles of 18 mares via surgical exposure of the ovary (5/13) or percutaneous needle aspiration (1/5). Surgical transfer of the oocytes into the oviduct of mares previously inseminated with 500 × 10⁶ progressively motile spermatozoa resulted in no embryos recovered by uterine lavage 8 days afteroocyte transfer. Corpora luteal function and formation from aspirated follicles appeared normal, based on progesterone analysis, ultrasound morphological assessment and cyclic behavioral changes.     

Effects of follicle‐stimulating hormone followed by gonadotropin‐releasing hormone on embryo production by ovum pick‐up and in vitro fertilization in the river buffalo (Bubalus bubalis)

In this study, we examined the effects of superstimulation using follicle‐stimulating hormone (FSH) followed by gonadotropin‐releasing hormone (GnRH) on buffalo embryo production by ultrasound‐guided ovum pick‐up (OPU) and in vitro fertilization (IVF). Nine Murrah buffaloes were subjected to OPU‐IVF without superstimulation (control). The morphologies of the oocytes collected were evaluated, and oocytes were then submitted to in vitro maturation (IVM). Two days after OPU, same nine buffaloes were treated with twice‐daily injections of FSH for 3 days for superstimulation followed by a GnRH injection. Oocytes were collected by OPU 23–24 hr after the GnRH injection and submitted to IVM (the superstimulated group). The total number of follicles, number of follicles with a diameter > 8 mm, and number of oocytes surrounded by multi‐layered cumulus cells were higher in the superstimulated group than in the control group (p ≤ 0.05). After IVF, the percentages of cleavage and development to blastocysts were higher in the superstimulated group than in the control group (p < 0.05). In conclusion, superstimulation improved the quality of oocytes and the embryo productivity of OPU‐IVF in river buffaloes.     

高产奶牛连续活体采卵及卵母细胞体外受精

在超声波扫描仪的指导下,用双孔型采卵针以 １４．７ ｋ Ｐａ 抽吸压经阴道对 ５ 头高产奶牛分别连续实施 ７ 次活体采卵,每 ７ ｄ １ 次,共采集卵子 ２１４ 个,占可见卵泡数的 ５３．９％ ,每次头均采集卵子 ６．１ 个。卵子经过体外培养、体外受精、体外受精胚体外发育培养,于体外受精后 ４８ ｈ 、１６８ ｈ 统计的卵裂率、囊胚发育率分别为 ７５．２％ 和 ２９．７％ 。研究结果表明,在超声波扫描仪指导下对奶牛连续进行活体采卵是可行的,所得卵子应用体外成熟、体外受精、体外培养技术,可生产用于冷冻或移植的胚胎。     

Repeat Ovum Pick-up and In Vitro Embryo Production from Adult Ewes with and without FSH Treatment

Ovum pick-up (OPU) was performed three times on adult ewes after synchronization with (n = 4) or without (n = 4) FSH treatment to investigate the effects of FSH treatment on the number of ovarian follicles, oocytes recovered, oocyte quality and development in vitro. FSH treatment increased the number of ovarian follicles (85 vs 162) and oocytes recovered (33 vs 91), although recovery rate was similar for ewes with and without FSH (91/162, 56.2% and 33/85, 38.8% respectively). Of the oocytes recovered, those classified as grades I and II were similar between ewes with (78/91, 85.7%) and without FSH treatment (27/33, 81.8%). The number of ovarian follicles was similar after repeated OPU for ewes treated with FSH, but for ewes not treated with FSH the number of ovarian follicles decreased with repeated OPU. The number of oocytes recovered decreased for FSH-treated ewes only, while the oocyte recovery rate and proportion of oocytes classified as grades I and II were not affected by repeated OPU. Oocyte cleavage (46/78, 58.9% and 19/24, 79.2%) and blastocyst formation (35/46, 76.1% and 12/19, 63.2% respectively) were similar for ewes with and without FSH treatment. The number of ovarian follicles varied between ewes (p < 0.05) although the number of oocytes recovered and oocyte development in vitro were similar between ewes.     

Influence of follicle size,methods of retrieval on oocytes yield and morphology in Egyptian Jennies ovaries with special reference to maturation rate in vitro

This work was designed to evaluate the ovarian follicular development, oocytes morphology, methods of oocytes reterival, and the effect of different in vitro maturation (IVM) media on cumulus cell expansion and nuclear maturation of Jennies oocytes. Experiment 1, the number of small (<6 mm), medium (6 to 9 mm) and large size (>10 mm) ovarian follicles was recorded. Cumulus-oocyte-complexes (COCs) were reterived and classified into 4 Grades based on their cumulus-cells investment and the homogenous of the ooplasm. In Experiment 2, COCs were recovered by using 18-G, 20-G needle or slicing and scraping of ovarian follicles to determine the number and morphology of the recovered COCs. In Experiment 3, Grade A and B COCs were IVM in DMEM-HG, DMEM-LG, DMEM-F12, TCM199, TCM199-F12 or CR1aa media supplemented with 10 % FCS?+?10 μg FSH/mL?+?10 IU hCG/mL?+?50 μg/mL gentamicin. Maturation was performed for 36 h at 38.5 °C under 5 % CO₂ in humidified air. After IVM, cumulus cell expansion and oocytes nuclear canfiguration were determined. An average of 6.40?±?0.26 follicles was recorded per Jenny ovary, representing 3.37?±?0.46, 1.89?±?0.14 and 1.14?±?0.16, for the small, medium and large size follicles, respectively. Oocyte recovery was higher (P?P?P?P?P?P?P?P?Conclusion: Slicing and scraping or aspiration of follicles using 18-G needle increased the number and percentage of Grade A Jennies oocytes. TCM199-F12, CR1aa and TCM199 medi are more suitable for IVM of Jenny oocytes by promoting cumulus cells expansion and nuclear maturation to M II stage.     

Optimization of recovery and maturation methods for cumulus-oocyte complexes in jennies

Embryo production in donkeys is inefficient compared with that in other livestock. Obtaining a sufficient number of MII oocytes is the first step to solving this problem. In this study, the number, morphology and maturation rates of cumulus-oocyte complexes (COCs) obtained from abattoir-derived ovaries or live jennies were compared. The diameter of follicles from abattoir-derived ovaries was measured and divided into group 1 (2–6 mm), group 2 (6–10 mm), group 3 (10–20 mm), group 4 (20–28 mm) and group 5 (>28 mm). The results showed that the number of follicles per ovary in group 2 (3.6 ± 0.28) and 3 (4.2 ± 0.90) was higher than that in the other groups (p < .05). The recovery rate in group 3 was higher than group 1 (48.8% vs. 26.8%, p = .00), but lower than group 5 (48.8% vs. 76.5%, p = .025). The percentage of grade A COCs in group 3 was higher than group 2 (59.3% vs. 39.5%, p = .00) and group 1 (59.3% vs. 26.7%, p = .00). Moreover, the percentage of grade A COCs in group 4 (55.0%, p = .710) and group 5 (46.2%, p = .351) was reduced compared with that in group 3. From the above results, the developing follicles (group ovum pick-up [OPU], 10–20 mm) and preovulation follicles (group OPU-Preov, >35 mm) were aspirated from live jennies using OPU. Although there was no difference in the recovery rates of COCs between group 3 and OPU (48.8% vs. 43.0%, p = .184), the percentage of grades A COCs in group OPU was higher than group 3 (72.5% vs. 59.3%, p = .036). There was no difference in the maturation rate between group 3 and OPU (60.3% vs. 69.3%, p = .171) after the COCs matured in vitro. The rates of recovery (72.2%) and maturation (92.3%) in group OPU-Preov were higher than those in other groups (p < .05). Moreover, the effects of maturation time and serum type on maturation rates were evaluated in groups B44 (44 h, FBS), B36 (36 h, FBS) and D44 (44 h, foetal donkey serum, FDS). These results indicated that the maturation rate in group B36 was lower than group B44 (13.1% vs. 47.0%, p = .00) and group D44 (13.1% vs. 53.3%, p = .00). In conclusion, the quality of donkey COCs from OPU was higher than that from abattoir-derived ovaries, the suitable time of donkey in vitro maturation (IVM) was 44 h, and FBS could be replaced with FDS in donkey IVM medium.     

Influence of Superovulatory Protocols on In Vitro Production of Nellore (Bos indicus) Embryos

There are indications in the literature that delaying the period between ovarian superestimulation and ovum pick up (OPU) would induce follicles to a condition of initial atresia, which could be beneficial to oocyte development. In this work, we compared three protocols for OPU and in vitro production (IVP) of embryos, in Nellore cattle. Nellore cows (n = 18) were randomly allocated in three groups: Group 1 (OPU), Group 2 [Follicle stimulating hormone (FSH) and OPU] and Group 3 (FSH deprivation and OPU). Three OPUs were performed, and the animals were switched to a different group each time (crossover), in such a way that at the end of the experiment all cows received the 3 protocols. At random stage of the oestrous cycle (D‐2), all follicles ≥ 6 mm were aspirated to induce a new follicular wave 2 days afterwards (D0). In Group 1, OPU was performed on D2 and oocytes were processed to IVP. In Group 2, starting on D0, cows were superstimulated (FSH, Folltropin^®, 30 mg administered daily, i.m., during three consecutive days, total dose = 180 mg), and 6 h after the last FSH dose, they received exogenous luteinizing hormone (LH) (12.5 mg, i.m., Lutropin^®, D3). The OPU was performed 6 h after LH administration, i.e. 12 h after the last dose of FSH. Animals in Group 3 received the same treatment as those in Group 2, except that LH was administered 42 h after the last dose of FSH, and OPU occurred 6 h later. Therefore, in this group, follicles were deprived of FSH at 48 h. Both cleavage and blastocyst rates were similar (p > 0.05, anova ) among oocytes from Groups 1, 2 and 3, respectively: 77.4% (144/185) and 42.70% (79/185); 75.54% (105/139) and 31.65% (44/139); 63.52% (101/159) and 33.33% (53/159). However, hatched blastocyst rate was higher (p < 0.01) in Group 1 (30.27%, 56/185) when compared with Group 2 (11.51%, 16/139) or 3 (15.72%, 25/159). It is concluded that, contrary to previous work on European breeds (Bos taurus), ovarian superstimulation associated with deprivation of FSH and OPU (Group 3) did not increase IVP of Nellore embryos (Bos indicus). On the contrary, the highest hatched blastocyst rates were observed in oocytes from non‐superstimulated cows.     

The effects of twisting and type of aspiration needle on the efficiency of transvaginal ultrasound-guided ovum pick-up in cattle

The effects of twisting and type (single- or double-lumen) of aspiration needle on the efficiency of transvaginal ultrasound-guided ovum pick-up (US-guided OPU) were investigated in cattle. The first study using slaughterhouse ovaries revealed that twisting of the needle during follicle aspiration improved the oocyte recovery rate without deleterious effects on the attachment of cumulus layers. Vacuum pressure affected the oocyte recovery and cumulus attachment, regardless of the needle type. The needle type did not affect the oocyte recovery or cumulus attachment with an optimized vacuum pressure. In the second study, US-guided OPU was performed in live cows using two types of needles with a vacuum pressure of 75 mmHg. The needle type did not affect the oocyte recovery or cumulus attachment of the recovered oocytes. The results revealed that twisting of the needle is effective in follicle aspiration, and suggested that a single-lumen needle is as useful as a double-lumen needle for US-guided OPU in cattle.     

Collection and in Vitro Maturation of Equine Oocytes from Estrus,Diestrus and Pregnant Mares

Two experiments were conducted to evaluate oocyte collection rates and in vitro nuclear maturation rates of equine oocytes obtained during diestrus and pregnancy, and to compare these rates with maturation rates in oocytes derived from preovulatory follicles. In Experiment I, transvaginal ultrasound-guided aspiration of follicle was performed during estrus and diestrus in 14 mares over four consecutive cycles. Follicular aspirations during estrus were performed 24 to 27 hours after injection of 2500 IU of hCG given when the largest follicle reached 35 mm in diameter. Oocyte recovery rate from preovulatory follicles was 51% (33/65) in 49 aspiration sessions. Cumulus-oocyte complexes from preovulatory follicles were cultured for 12-15 hours in TCM199 + 10% (NCS) at 38.5°C in 5% CO₂ in air, and 22/33 (67%) were in metaphase II. During diestrus, mares were treated (Group I) or not treated (Group II) daily with equine pituitary extract (EPE) during alternate cycles from days 1 to 14 after the preovulatory aspiration. Diestrous follicles were aspirated when four or more follicles greater than 12 mm in diameter were present. EPE had no effect on the number of follicles that developed during estrus or diestrus (p>0.05). Oocytes were recovered from 119 of 383 diestrous follicles (31 %)in 75 sessions. There was no difference in recovery rates between Groups I and II (p>0.05). Maturation rates for oocytes collected during diestrus, after 42 hours of culture in TCM 199 + 1 μg/ml of Estradiol and lnl/ml of EPE, were not significantly different (p>0.05) between Groups I and II (49% vs. 53%). In Experiment II, mares between 50 and 85 days of pregnancy were used as oocyte donors. The oocyte recovery rate was 53% (66/125). After in vitro maturation for 40 hours (compact COC) or 15 hours (expanded COC), 22% (7/32) and 22% (7/32), respectively, of the oocytes were in metaphase II. It was concluded that: 1) Preovulatory follicles yield a higher percentage of oocytes with a higher rate of maturation to metaphase II than follicles of diestrus and pregnant mares. 2) Diestrous follicles yielded fewer oocytes than follicles of pregnant mares but with a higher percentage of oocyte maturation. Further studies are necessary to determine if oocytes recovered from diestrous follicles and matured in vitro can be fertilized successfully.     

卵母细胞来源对水牛体细胞核移植胚胎发育潜能的影响

[目的] 探索不同来源卵母细胞对体细胞核移植（SCNT）重构胚的发育能力及发育潜能关键蛋白表达水平的影响。[方法] 试验分为活体采卵（OPU）和屠宰场（SLH）卵巢2组,OPU组用超声波活体采卵仪穿刺抽吸10头非泌乳期经产水牛卵巢的卵泡采卵,SLH组从屠宰场卵巢抽吸卵泡采卵。获得的卵母细胞分别进行体外成熟,体外成熟22~24 h后,吹打去除卵丘细胞,挑选具有第一极体的卵母细胞,去核后与水牛耳部成纤维细胞进行SCNT,分别统计SCNT重构胚的融合率、分裂率和囊胚率,用免疫荧光检测2种SCNT重构胚的E-钙黏蛋白（E-cadherin）和转录因子Sox2蛋白的表达水平。[结果] OPU组卵母细胞成熟率及其SCNT重构胚的囊胚率均显著高于SLH组（P<0.05）,但2组SCNT重构胚的融合率和分裂率均无显著差异（P>0.05）;免疫荧光结果显示,E-cadherin蛋白定位于细胞膜上,Sox2蛋白分布在细胞核膜及细胞质中,OPU组SCNT重构胚中E-cadherin和Sox2的表达水平均显著高于SLH组（P<0.05）。[结论] 活体采集的水牛卵母细胞更适合用于SCNT重构胚的构建。     

Follicular development after ovum pick-up and fertilizability of retrieved oocytes in postpartum dairy cattle

This study aimed to evaluate gonadotropin secretion and the developmental competence of follicular oocytes in dairy cattle during the early postpartum (PP) period. The number of follicles developed after transvaginal ultrasound-guided ovum pick-up (OPU) and fertilizability of retrieved oocytes were compared between cows in which the first dominant follicle (DF) ovulated (ovulated group, n=4) and did not ovulate (non-ovulated group, n=3), and between early PP (early PP group, n=2) and after the resumption of the estrous cycle (cyclic group, n=2). Follicular ablation was performed 2-4 days after the detection of DF in the second follicular wave PP. OPU was repeated 3-5 times at 3 or 4-day intervals from 3-4 days after the follicular ablation. At OPU, the follicles were enumerated and all those > or = 5 mm in diameter were aspirated. Recovered oocytes were subjected to in vitro maturation and fertilization. Both criteria were similar between ovulated and non-ovulated groups, and between early PP and cyclic groups. These results suggest that FSH/LH secretions required for follicle recruitment and subsequent follicular growth during the early PP period are similar to those after resumption of the estrous cycle. They also indicate that follicular oocytes during the early PP period have developmental competence.     

Collection of Oocytes Through Transvaginal Ovum Pick-up for In Vitro Embryo Production in Nanyang Yellow Cattle

The objectives of this study were to use ultrasound-guided transvaginal follicular aspiration to develop a technique for preservation of Nanyang Yellow cattle germ plasm. In Nanyang Yellow heifers, aspiration twice per week yielded a higher mean numbers of aspirated follicles, recovered oocytes and viable oocytes per session than once-weekly aspiration. Intriguingly, twice-weekly aspiration from Holstein heifers yielded a higher mean numbers of aspirated follicles, recovered oocytes and viable oocytes per session than in Nanyang Yellow heifers. Moreover, the oocyte recovery rate was significantly higher in Holstein heifers than in Nanyang Yellow heifers. Importantly, similar rates of embryos undergoing cleavage division were observed in Nanyang Yellow and Holstein, as was the number of viable day 8 blastocysts. These observations demonstrate that twice-weekly aspiration harvested the similar proportions of viable oocytes from Nanyang Yellow and Holstein follicles, and that twice-weekly aspiration yields a higher number of viable oocytes than once-weekly aspiration in Nanyang Yellow heifers. The results also suggest that the combination of ultrasound-guided transvaginal follicular aspiration and in vitro production is an effective and practical strategy for establishment of a germ plasm preservation programme for Nanyang Yellow cattle.     

Anti-Muellerian hormone levels in plasma of Holstein-Friesian heifers as a predictive parameter for ovum pick-up and embryo production outcomes

The aim of this study was to investigate whether plasma anti-Muellerian hormone (AMH) levels of Holstein-Friesian heifers could be used to predict ovum pick-up (OPU) and embryo production outcomes. Plasma samples and data were collected from 64 heifers, which underwent repeated OPU with subsequent in vitro embryo production followed by embryo flushing after superovulation. AMH levels were significantly positively correlated with the number of follicles aspirated per OPU session (r = 0.45), recovered oocytes per OPU (r =0.43) and in vitro produced embryos per OPU (r = 0.28). No significant correlations between AMH and in vivo produced embryos were ascertained. Our results suggest that correlations between AMH and outcomes of an OPU-IVF program are too low to use AMH as a precise predictive parameter for the success of a particular OPU procedure in Holstein-Friesian heifers. However, AMH can help to identify groups of very good or very poor oocyte donors.     

Effects of Ovum Pick-up Frequency and FSH Stimulation: A Retrospective Study on Seven Years of Beef Cattle In Vitro Embryo Production

The aim of this retrospective study was to compare the number of follicles, cumulus oocyte complexes (COCs) and cultured In Vitro Produced (IVP) embryos obtained from 1396 non‐stimulated Ovum Pick‐up (OPU) sessions on 81 donor animals in a twice weekly OPU scheme. Results were obtained from 640 sessions following FSH‐LH superstimulation, on 112 donors subjected to OPU once every 2 weeks. The stimulation protocol started with the insertion of an ear implant containing 3 mg norgestomet (Crestar, Intervet, Belgium) 8 days before puncture (day ?8). The dominant follicle was ablated by ultrasound‐guided follicle puncture on day ?6. On day ?3 and day ?2, cows were injected with FSH (Ovagen, ICP) twice daily (8 am to 8 pm ), i.e. a total dose of 160 μg FSH and 40 μg LG per donor per stimulation cycle. Animals were punctured 48 h after the last FSH injection (day 0). Progesterone implants were removed the next day. Stimulated donor cows were treated with this protocol at 14‐day intervals. Follicles were visualized with a Dynamic Imaging ultrasound scanner, equipped with a 6.5 MHz sectorial probe. Follicles were punctured with 55 cm long, 18 gauge needles at an aspiration pressure corresponding to a flow rate of 15 ml/min. Cumulus oocyte complexes were recovered and processed in a routine IVF set‐up. Results demonstrate that, expressed per session, FSH stimulation prior to OPU increases production efficiency with significantly more follicles punctured and oocytes retrieved. However, when overall results during comparable 2‐week periods are considered (four non‐stimulated sessions vs one stimulated), more follicles are punctured and more oocytes are retrieved using the non‐stimulated protocol. No significant differences in the number of cultured embryos could be detected, indicating that FSH/LH stimulation prior to OPU might have a positive effect on in vitro oocyte developmental competence as more embryos are cultured with less, presumably better‐quality, oocytes.     

Effects of Follicular Fluid on the Transport of Porcine Oocytes into the Oviduct at Ovulation

Contents Three experiments were conducted to determine whether follicular fluid (FF) enters the oviduct and plays any role in the transport of oocytes into the oviduct. Experiment 1: Oestrus and ovulation were synchronized in cycling gilts (n = 21) over a 15 day period of feeding Regumate^® and injections of 1000 IU pregnant mare’s serum gonadotrophin (PMSG) 24 h after the last Regumate^® feed and 500 IU human chorionic gonadotrophin (hCG) 80 h after PMSG. Ipsi-lateral aspiration of FF and salpingectomy (group 1, n = 7), aspiration of FF without salpingectomy (group 2, n = 7) or ligation of the oviduct between the ampulla and infundibulum (group 3, n = 7) was performed endoscopically prior to ovulation (34–36 h after hCG). Ipsi-lateral (group 2 and 3) and contra-lateral salpingectomy was carried out in all gilts post ovulation, 42–44 h after hCG. The oviducts were flushed with 1 ml saline and the samples as well as the aspirated FF were analysed for progesterone and estradiol by RIA methods. In group 1 both progesterone and estradiol concentrations did not differ before and after ovulation. Withdrawal of FF from the ipsi-lateral ovary by aspiration (group 2) or ligation of the oviduct (group 3) did not influence the steroid content within the oviducts. Similarly low progesterone concentrations were measured in ipsi- and contra-lateral oviducts after ovulation (group 2: 0.29 ± 0.17 versus 0.24 ± 0.35 ng/ml and group 3: 0.22 ± 0.19 versus 0.21 ± 0.22 ng/ml). The high content of progesterone of FF (269.7 ± 67.9 and 389.6 ± 226.5 ng/ml in group 1 and 2, respectively) was not reflected in the oviductal fluid. Experiment 2: In five gilts 0.06 ml ³H-progesterone (30 000 dpm) were applied via a fine 27 G injection needle into the largest three follicles of the ipsi-lateral ovary prior to ovulation (34–36 h after hCG). The oviducts were flushed following ovario-salpingectomy 42–44 h after hCG. All follicles had ovulated. The oviductal flushings and oviductal and ovarian tissue were analysed for labelled progesterone. No differences were measured in the content of ³H-progesterone of oviductal flushings and of both oviductal and ovarian tissues between the ipsi-lateral injection and contra-lateral control sides. The main part of the counts detected was within the range of background dpm values. Only 2.4% of the initial counts were recovered from fluid and tissue samples. Experiment 3: In a subsequent study FF was cautiously aspirated by endoscopy from follicles of the ipsi-lateral ovary 34–36 h after hCG (n = 12 gilts). Postovulatory (58 h after hCG), both oviducts were flushed and the oocytes were recovered. To test the influence of follicle puncture alone on the process of ovulation (n = 8 gilts), the aspiration needle alone was pricked into the follicles of the ipsi-lateral ovary, without any fluid aspiration. Despite the cautious aspiration of FF from 89 follicles, 26 oocytes were recovered together with the FF. Eighty-six postovulatory follicles were observed on the ipsi-lateral ovary. Out of 57 oocytes able to reach the oviduct, 29 oocytes were flushed from the oviduct (50.4 ± 28.1%). From the contra-lateral control oviduct 71 oocytes out of 91 ovulations (69.0 ± 33.9%) were recaptured. Puncture of follicles without aspiration did not influence ovulation compared with the control (recovery rate 68.2 and 79.6%, respectively). Results indicate (1) on the basis of the low progesterone level within the oviductal fluid that only a small amount of FF seems to reach the oviduct at ovulation, and (2) FF does not appear to be a compulsory carrier of the porcine oocyte at ovulation.