Ultrasound-guided follicle aspiration: effect of the frequency of a linear transvaginal probe on the collection of bovine oocytes

The effect of the frequency of an ultrasonic linear transvaginal probe on the collection of bovine oocytes by transvaginal ultrasound-guided follicle aspiration was investigated. Probes with different frequencies (7.5 or 5.0 MHz) were applied to examine the clarity of follicles on the monitor using ovaries of slaughtered cows in Experiment 1. The follicles were visualized on the monitor and divided into small (3- to 5-mm diameter) and large (6- to 10-mm) groups. They were also divided into 2 groups according to the clarity of their outline (clear or obscure). The number of small follicles visualized with a clear outline was greater (P < 0.01) with the 7.5 MHz probe than with the 5.0 MHz probe (9.0 vs 3.2). Oocyte aspiration from live cows was performed using the 7.5 or 5.0 MHz probe in Experiments 2 and 3. The recovered oocytes were divided into 3 categories: cumulus-oocyte-complexes (COCs), denuded oocytes and all others. In Experiment 2, the number of oocytes collected per donor cow was assessed, and in Experiment 3 the number of oocytes per aspirated follicle was examined by aspirating a constant number of follicles per aspiration session. The numbers of oocytes and COCs per donor cow obtained with the 7.5 MHz probe (11.2 and 9.0, respectively) were greater (P < 0.01) than those obtained with the 5.0 MHz probe (4.3 and 3.5). This difference between probes was due to the greater clarity of the follicle images obtained with the 7.5 MHz probe.     

Effects of repeated ultrasound-guided transvaginal follicular aspiration on bovine oocyte recovery and subsequent follicular development

We wished to compare cumulus oocyte complex (COC) recovery and follicle development after single and repeated ultrasound-guided transvaginal follicle aspiration (aspiration). Aspirations were performed in Holstein-Friesian heifers every once weekly (every 7 d; n = 12) or twice weekly (every 3 or 4 d; n = 6) starting on Days 3 or 4 of the estrous cycle (estrus = Day 0) and continuing for 4 wk. During each session, all visible follicles > 2 mm were aspirated using an 7.5 MHz transducer to guide an 18 ga x 60 cm single lumen needle and applying 50 mm Hg vacuum which generated 25 mL/min. The COC's harvested from each follicle were counted and classified into 4 categories. Post-aspiration follicle wave emergence was traced by daily ultrasound examinations. A total of 1410 follicles were aspirated during 96 sessions, yielding 632 (45%)oocytes. There was no difference in average COC/follicle recovered between the single vs the repeated aspiration treatment. However, ovaries of heifers subjected to two aspirations per week yielded more follicles (17.2 +/- 5.7 vs 12.4 +/- 6.1; P < 0.01) and COC's (7.7 +/- 4.5 vs 5.4 +/- 3.7; P < 0.01) per session than those subjected to a single aspiration. Ovaries of heifers subjected to twice weekly aspirations at 4-d intervals resulted in a higher recovery rate (51.1 vs 38.6%), yielded more COC's (9.3 +/- 4.7 vs 6.2 +/- 3.8) and a higher number of viable COC's recovered per session (7.6 +/- 3.8 vs 5.2 +/- 3.3) than those aspirated every 3 d, all P < 0.01. Aspiration-induced follicle waves were indicated by an increased number of follicle > or = 4 mm seen within 2 d of the procedure. We conclude that follicle aspiration appears to induce and synchronize follicle waves, and when it is done twice a week it is associated with higher number of harvestable follicles and more oocytes recovered than when done once a week. These results can be attributed to the aspiration of a newly recruited pull of follicles 3 or 4 d after the first aspiration and before the establishment of follicular dominance and regression of subordinate follicles.     

Relationship between follicle size and ultrasound-guided transvaginal oocyte recovery.

We evaluated the relationship between follicle size and oocyte recovery (OR) using ultrasound-guided follicle aspiration. Thirty Holstein cows were subjected to OR without gonadotrophic therapy. Oocytes were recovered two to four times from each cow in a total of 67 aspiration sessions. Ovarian follicles with diameters < or =4 mm and >4 mm were aspirated in separated groups. Recovered oocytes from each group were kept separate and submitted to in vitro maturation, fertilization, and culture to the blastocyst stage. A total of 430 follicles were aspirated, of which 154 (35.8%) were from follicles >4 mm and 276 (64.2%) were from follicles < or =4 mm. Seventy-seven oocytes (50%) were recovered from follicles >4 mm and 200 (72.2%) were from follicles < or =4 mm. Nineteen blastocysts were obtained from follicles >4 mm, whereas 45 blastocysts were obtained from follicles < or =4 mm. Recovery rate was greater (P<0.01) in follicles < or =4 mm. Oocyte quality, cleavage rate and blastocyst development did not differ between different follicle sizes. Routine aspiration of small follicles (< or =4 mm) could increase the number of oocytes available for in vitro development.     

Recovery of mare oocytes on a fixed biweekly schedule, and resulting blastocyst formation after intracytoplasmic sperm injection

Oocytes may be collected from live mares from either the stimulated preovulatory follicle or from all visible immature follicles. We evaluated the yield of mature oocytes, and of blastocysts after intracytoplasmic sperm injection (ICSI), for both follicle types. In Experiment 1, mares were assigned to Progesterone (1.2 g biorelease progesterone weekly) or Control treatments. Transvaginal aspiration of all follicles was performed every 14 d. Overall, 596 follicles were aspirated, with a 54% oocyte recovery rate. There was no difference between treatments in number of follicles punctured (9.0 to 9.1) or oocytes recovered (4.8 to 5.0) per mare per aspiration session. Of 314 oocytes recovered, 180 (57%) matured in culture. Thirty-six mature oocytes were subjected to ICSI; 33% formed blastocysts (63% per mare per aspiration session). In Experiment 2, the preovulatory follicle was aspirated every 14 d for three to four cycles. Prostaglandin F_2α was given on Days 6 and 7 after aspiration. A follicle ≥25 mm in diameter was present on Day 13, the day of deslorelin administration, in 23 of 24 cycles, and ovulatory response (granulosa expansion) was seen in 24 of 25 follicles aspirated. Blastocyst development after ICSI was 41% per injected oocyte, or an estimated 33% per mare per aspiration session. We concluded that both aspiration of immature follicles and aspiration of the preovulatory follicle can be performed effectively every 14 d without monitoring ovarian follicular growth. As performed in these separate experiments, aspiration of immature follicles provided more blastocysts per aspiration session.     

Ultrasound-guided transvaginal oocyte collection in prepubertal calves

The present study was designed to develop a technique for oocyte collection using an ultrasound-guided transvaginal approach in prepubertal calves too small to accommodate manual transrectal manipulation. A commercially available, 5 MHz, convex-array ultrasound transducer designed for intravaginal use in women was custom-modified for use in calves. In Experiment 1, calves 10 to 16 wk old (n = 10) were restrained in the standing position in an adjustable squeeze chute with regional anesthesia. In Experiment 2, the follicle aspiration procedure was performed in 6 wk-old calves (n = 20) in dorsal recumbency after tranquilization and caudal epidural anesthesia. Ovarian superstimulation was induced in half of the calves using 750 IU eCG (Experiment 1) or 200 mg Folltropin (Experiment 2). Consistent visualization of both ovaries using the transvaginal approach was accomplished after considerable practice. Two methods of ovarian immobilization were attempted, but both interfered with the ultrasound image and were consequently abandoned. The inability to immobilize the ovary resulted in attempts to spear the intended follicle "free-hand." The contents of follicles >or= 6 mm in diameter were aspirated, filtered, and oocytes were located using a stereomicroscope. Although ovarian superstimulation did not resolve the problem of ovary movement, the number of follicles of adequate size to aspirate was dramatically increased. Extremely sharp needles were found to be very important in the free-hand technique. A total of 232 follicles was aspirated, and 100 oocytes were collected (43%). In summary, a transvaginal ultrasound-guided technique for oocyte collection was developed for young calves in a standing position (10 to 16 wk of age) and dorsal recumbency (6 wk of age). Results demonstrate the potential utility of this approach for deriving oocytes from young calves.     

Transvaginal collection and ultrastructure of llama (Lama glama) oocytes

Ultrasound-guided transvaginal follicle aspiration has been described as a noninvasive and repeatable procedure for oocyte collection in several species, but its use has not been described for any of the members of the family, Camelidae. A study was designed to determine the feasibility of an ultrasound-guided transvaginal approach for oocyte collection in llamas. Fifteen non-pregnant, adult female llamas (10 non-stimulated and 5 superstimulated) were examined by transrectal ultrasonography with a 7.5-MHz linear-array transducer to determine the number and diameter of follicles available for aspiration. After caudal epidural anesthesia was induced, the 7.5-MHz linear-array transducer was fastened to a long rigid handle and inserted intravaginally. The free hand was placed into the rectum to manipulate the ovaries, one at a time, in position against the vaginal wall over the face of the transducer. A 20-gauge, 55-cm-long, single-lumen needle was advanced through the vaginal fornix and into follicles > or = 3 mm in diameter. Follicular contents were aspirated using a regulated vacuum pump (flow rate = 33 mL/min; approximately 150 mm Hg) into a tube containing 3 mL of phosphate buffered saline and 0.2% BSA. Fluid was filtered (75 microm mesh), and oocytes were located and morphologically evaluated using a stereomicroscope. Overall, 134 follicles were aspirated, and 76 oocytes were collected (collection rate = 57%). Thirty-two oocytes (42%) were surrounded by multiple layers of compacted granulosa cells and had homogenous dark ooplasm; 13 oocytes (17%) were surrounded by the corona radiata layer only and had heavily granulated ooplasm; 9 oocytes (12%) were denuded and had homogenous dark ooplasm; and 22 oocytes (29%) were denuded and displayed signs of ooplasm degeneration. The ultrastructure of llama oocytes was similar to that of cattle except for conspicuous accumulation of large lipid droplets in the cytoplasm. Twenty-four hours after follicle aspiration, the ovaries were examined by transrectal ultrasonography and intrafollicular hematomas were detected in 3 llamas (9 of 48 follicles aspirated). Results demonstrate the potential utility of a transvaginal ultrasound-guided technique for oocyte collection and in vitro embryo production in llamas. Oocytes of llamas bear an ultrustructural resemblance to those of cattle, but are distinguished by a predominance of cytoplasmic lipid.     

Effect of frequency of follicle aspiration on oocyte yield and subsequent superovulatory response in cattle

The effect of frequency of transvaginal follicular aspiration on oocyte yield and subsequent superovulatory response was studied in 2 experiments. In Experiment 1, 32 primiparous Hereford x Friesian cows were assigned to 4 treatments (n = 8 per treatment). Oocyte recovery was carried out once a week for 12, 8, 4 or 0 (control) wk. Embryo recovery for all animals was 7 wk after the completion of the aspiration schedules. In Experiment 2, the effects of oocyte recovery once or twice a week (n = 8 per treatment; control n = 18) for 12 wk and response to superovulation 4 wk after the last aspiration were compared using nulliparous purebred Simmental heifers. Increasing the period of once weekly aspirations from 4 to 12 wk (Experiment 1) did not affect the number of follicles observed per session (mean +/- SEM; 10.0 +/- 0.82) or aspirated (7.8 +/- 0.71), but the recovery rate of oocytes from follicles aspirated was greater for donors aspirated for either 4 or 8 wk than for 12 wk (32.3 +/- 3.73 vs 28.4 +/- 2.61 vs 20.1 +/- 2.13 %; P < 0.05). Following the last aspiration and prior to commencing superovulatory procedures, estrus or estrous activity was observed in 7 8 , 8 8 , 7 8 and 6 8 of the animals aspirated over 12, 8, 4 or 0 wk, respectively. Subsequent superovulatory responses and in vivo embryo recoveries were similar for all aspiration treatments and for control animals. Changing the frequency of oocyte recovery from once to twice weekly (Experiment 2) did not affect the numbers of follicles observed (9.1 +/- 0.63 vs 8.3 +/- 0.85), follicles aspirated (5.9 +/- 0.56 vs 6.2 +/- 0.69), oocytes recovered (1.7 +/- 0.27 vs 1.9 +/- 2.0) per session or the oocyte recovery rate (29.4 +/- 2.4 vs 30.4 +/- 2.4 %); nor was there any effect of frequency of aspiration on subsequent superovulatory response and embryo recovery. In conclusion, increasing the period of aspiration from 4 to 12 wk and the frequency from once to twice a week over 12 wk did not reduce the number of follicles observed or aspirated, or number of oocytes recovered per donor per session. Subsequent estrous cyclicity and responses to superovulation were unaffected by the periods or frequencies of oocyte recovery examined here.     

Collection of oocytes from cattle via follicular aspiration aided by ultrasound with or without gonadotropin pretreatment and in different reproductive stages

Ultrasound-guided follicular aspiration was performed on 29 Holstein-Friesian cows/heifers twice weekly at 3- to 4-d intervals over a period of 2 consecutive estrous cycles (total 42 d). For visualization of the ovaries and guidance of the aspiration needle, a 6.5 MHz fingertip probe on a 62 cm probe carrier was inserted into the vagina. The disposable aspiration needle was connected to a permanent rinse tubing system, thus ensuring minimum death of oocytes in the aspiration processs. After penetration of the vaginal wall, the needle was inserted into a follicle of the rectally fixed ovary. Cumulus oocyte complexes (COC) were aspirated at a pressure of 100 mm Hg. In the first experiment, the effect of an additional gonadotropin treatment 4 d prior to aspiration was investigated in 8 lactating cows. Following FSH-treatment, the number of aspirated follicles was higher (P < 0.05) than in the nontreated animals (10.6 +/- 0.7 vs 8.9 +/- 0.5). The number of recovered COC (7.0 +/- 0.6 vs 5.8 +/- 0.5), the recovery rate (COC per aspirated follicle) (66.6% vs 65.4%), the percentage of viable COC (56.8% vs 52.1%), the cleavage rate upon in vitro maturation and in vitro fertilization (56.7% vs 59.8%) as well as the rate of morula/blastocyst formation (3.8% vs 2.9%) were similar in both groups. In the second experiment, follicles were aspirated in 4 lactating cows, 6 dry cows, 4 pregnant cows (first 35 d of pregnancy), and 4 heifers. The average number of aspirated follicles and recovered COC was higher (P < 0.05) in the first 2 groups (10.6 +/- 0.6 and 9.3 +/- 0.7 follicles; 7.2 +/- 0.5 and 6.9 +/- 0.7 oocytes) than in trie 2 other treatment groups (7.3 +/- 0.5 and 8.1 +/- 0.5 follicles; 5.0 +/- 0.4 and 5.7 +/- 0.5 oocytes). The percentage of viable COC was higher (P < 0.05; 68.3%) in lactating animals than in all the other groups (49.7, 52.5 and 57.4%, respectively). Similarly, upon in vitro fertilization, cleavage rate was higher (P < 0.05; 63.4%) in lactating cows than in the other groups (43.7, 50.5, 55.1%, respectively). A total of 21.5, 22.7, 11.9 and 13.5%, respectively, in the 4 groups of the in vitro fertilized oocytes reached the morula and blastocyst stages. After transfer of a total of 48 embryos 22 pregnancies (45.8%) were established as detected on Day 65. We conclude that 1) repeated aspiration of viable COC at short intervals is possible, 2) additional FSH-treatment does not increase oocyte yields, and 3) viable blastocysts can be produced from cattle at various reproductive phases irrespective of the reproductive phase.     

Effect of ultrasonically-guided follicle aspiration on estrous cycle and follicular dynamics in Holstein cows

Two experiments were conducted to test the effect of ultrasonically-guided follicle aspiration on estrous cycle and follicular dynamics in Holstein cows. The objective of the first experiment was to determine if aspiration of all visible follicles would influence the estrous cycle. All visible follicles > or = 5 mm in diameter were punctured and the oocytes aspirated once during the second and fourth cycle, with no aspirations occurring during Cycles 1, 3 and 5 in 4 Holstein cows. Between aspirations the follicles were scanned ultrasonically every 2 to 3 d to monitor follicular waves. Estrus was monitored twice daily and plasma progesterone concentrations were measured daily. The inter-estrus periods were significantly longer when aspiration was performed than in the 3 cycles in which aspiration did not occur (25.0 vs 21.1 d; P < 0.01). To determine the maximum number of follicles harvestable on a continuing basis, a second experiment was conducted to contrast unstimulated cows subjected to ultrasonically-guided oocyte collection twice-weekly with animals from which oocytes were collected once a week after gonadotrophin stimulation. All visible follicles of multiparous Holstein cows were aspirated every 3 or 4 d (unstimulated group, n = 4), and the total number of follicles was compared with the number of follicles in cows that were aspirated weekly after 400 mg FSH were administered over 2 d (stimulated, n = 6). The study continued for 8 consecutive weeks. The weekly mean number of follicles available for aspiration in the unstimulated cows was 15.7 +/- 3.3 (mean +/-SEM), which was not different from the 14.2 +/- 1.9 follicles available for aspiration from the FSH-stimulated cows. Within the unstimulated cows, there was an increased number of follicles available for aspiration over time during the period of study (P < 0.001). The number of follicles available for aspiration from the stimulated cows did not change, but plasma concentrations of progesterone increased over time as persistent luteal tissue developed on the ovaries.     

Transvaginal ultrasound guided follicular aspiration of bovine oocytes

A transvaginal ultrasound guided follicular aspiration technique was developed for the repeated collection of bovine oocytes from natural cycling cows. In addition, the feasibility of using this method for collecting immature oocytes for in vitro embryo production was also evaluated. Puncturing of visible follicles for ovum pick-up was performed in 21 cows over a three month period. All visible follicles larger than 3 mm were punctured and aspirated three times during the estrous cycle on Day 3 or 4, Day 9 or 10 and Day 15 or 16. The mean (+/- SEM) estrous cycle length after repeated follicle puncture was 22.2 +/- 0.3 days. The mean total number of punctured follicles per estrous cycle was 12.6 +/- 0.3. The largest (P<0.05) number of follicles punctured (5.1 +/- 0.3) for ovum pick-up was on Day 3 or 4 of the estrous cycle. The overall recovery rate of 541 punctured follicles was 55%. Most oocytes (P<0.05) were aspirated from follicles smaller than 10 mm. Following in vitro maturation and fertilization (IVM/IVF), 104 oocytes were transferred to sheep oviducts. Six days later, 75 ova/embryos were recovered, after flushing the oviduct of the sheep, of which 24% developed into transferable morulae and blastocysts. In this study, a reliable nonsurgical, follicular aspiration procedure was used for the repeated collection of immature oocytes which could be used successfully for in vitro production of embryos. This procedure offers a competitive alternative to conventional superovulation/embryo collection procedures.     

Fertility in the mare after repeated transvaginal ultrasound-guided aspirations

Ovum pick-up (OPU) by transvaginal ultrasound guided aspiration (TUGA) is a procedure applied in equine-assisted reproduction programs such as oocyte transfer and in vitro embryo production. Despite a large number of studies reporting that it is a repeatable and safe technique, little information is available about the effect of repeated punctures on fertility of mares. Moreover, even if flushing follicles improves the oocyte recovery rate, to our knowledge the efficiency of flushing estrous and diestrous follicles has not been evaluated. The aims of the present study were (1) evaluate if repeated TUGAs negatively effects fertility and (2) investigate the influence of flushing the follicular cavity (as compared to aspiration only-unflushed) on the recovery rate from follicles of different sizes and in different stages of the estrous cycle. Seventy-six TUGAs were carried out on 20 mares during the breeding season; 153 follicles were aspirated and 31 oocytes were recovered (20.3% per follicle; 40.8% per TUGA attempt). Of the 76 aspirations, 52 were carried out during estrus and 24 in diestrus. Flushing the follicular cavity significantly increased (P < 0.01) the oocyte recovery rate from estrous follicles (13/28, 46.4% flushed versus 3/24, 12.5% aspirated only) but not (P > 0.05) from diestrous follicles of different diameters (3/30, 10% flushed versus 2/36, 5.6% aspirated only for follicles <2 cm in diameter; 6/20, 30% flushed versus 4/15, 26.7% aspirated only for follicles > or =2 cm in diameter). Mares underwent ultrasonic examinations after every aspiration and no alteration was found with the exception of two mares in which the corpus luteum (CL) did not form following aspiration of estrous follicle. Of the 20 mares involved in this study, 10 were artificially inseminated with fresh semen from a single fertile stallion at the first spontaneous heat following the previous aspiration. Of the 10 inseminated mares, 7 were found to be pregnant 16, 30 and 50 days after artificial insemination (AI), indicating that repeated TUGAs did not adversely affect fertility.     

A comparison of a mechanical sector and a linear array transducer for ultrasound-guided transvaginal oocyte retrieval (OPU) in the cow

A comparison was made between a linear array and a mechanical multiple angle sector (MAP) transducer for ultrasound-guided transvaginal oocyte retrieval (ovum pick-up, OPU) in the cow. The ovaries of five dairy cows were punctured, in a twice-weekly OPU program lasting for 4 weeks, using two different 5.0-MHz transducers equipped with an identical disposable needle-guidance system. Both ovaries were visualized using each transducer before puncture and the number of follicles with a diameter of less than 5 mm (small) and with a diameter equal to or greater than 5 mm (large) was recorded. Subsequently, one ovary of the pair was punctured guided by the MAP, while the other was punctured using the linear array transducer. During the next puncture session on a given animal, the two systems were switched and used on the alternate ovary in a crossover design. Parameters assessed for each system were: the total number of follicles visualized in each diameter class, and the total number of retrieved oocytes per cow. A significant difference was found for the ability to visualize smaller follicles in favor of the MAP transducer, with an average visualization of 71.6 +/- 30.3 small follicles per cow during the 4-week trial period, compared to 59.8 +/- 25.7 for the linear array transducer (t-test for paired samples, P = 0.007). No differences were found in the visualization of large follicles. A numerically greater number of oocytes were retrieved using the MAP transducer, compared to the linear array, (averages of 14.2 +/- 7.2 versus 7.4 +/- 6.1, respectively), although these differences were not statistically significant. In conclusion, both systems can be effectively used for oocyte retrieval in the cow, however, the MAP transducer demonstrated superior visualization of small follicles.     

Effect of unilateral ovariectomy, gonadotropin stimulation and immunization against a synthetic peptide of the inhibin alpha-subunit on follicular development and oocyte recovery in cattle

Nulliparous Holstein cows were randomly distributed among 4 treatment groups to test the effects of treatments, including unilateral ovariectomy, anti-inhibin immunization and gonadotropin stimulation on ovarian follicle population and oocyte recovery. The Control treatment consisted of intact cows (I-Control). Unilaterally ovariectomized cows were included in the 3 remaining treatments consisting of ovariectomy alone (U-Control), cows immunized against a synthetic peptide of the alpha(c)-subunit of bovine inhibin (alpha(c)I; U-IH), and cows stimulated with FSH (Super-Ov; 75 units/female/week) and also immunized with alpha(c)I as in the previous treatment (U-IH/FSH). Oocytes were collected by transvaginal ultrasound-guided aspiration on a weekly basis from cows in each treatment for 5 consecutive weeks. Intact Control cows had a greater (P<0.05) number of follicles > or = 3 mm per female (4.7) than the U-Control and U-IH cows (2.6 and 2.9, respectively), and had a similar number of follicles as the U-IH/FSH treatment group (3.5). The numbers of follicles aspirated (2.7 to 3.6) and oocytes recovered/cow (1.6 to 2.6) were similar for cows in the I-Control, U-IH and U-IH/FSH treatment groups. Cows in the U-Control treatment group had a lower (P<0.05) number of aspirated follicles (2.0) and recovered oocytes (1.1) than the I-Control cows. Cows in the U-IH/FSH and U-IH treatments had follicles with larger (P<0.01) diameters (8.7 and 8.2 mm, respectively) than cows in the I-Control (6.6 mm) and U-Control (5.7 mm) treatments. In conclusion, unilateral ovariectomy did not result in compensatory increase of follicle number or size in the intact ovary; cows in the U-IH/FSH treatment group had a greater number of follicles aspirated than the U-Control cows. In addition, the anti-alpha(c)I immunization may have played a role in increasing the number and diameter of the follicles. None of the treatments evaluated in this study improved oocyte retrieval over that of the intact, nontreated cows.     

Transillumination increases oocyte recovery from ovaries collected at slaughter. A new technique report

An inexpensive and convenient method of collecting large number of oocytes for in vitro procedures is by aspiration of follicles visible on the surface of isolated ovary. This method yielded only moderate numbers of oocytes per ovary, and it was found that the yield could be improved by slicing the tissue to reach deep, cortical follicles. However, slicing was time consuming and increased chances for sepsis. We developed a new technique that allows direct viewing of cortical follicles for aspiration of oocytes by transillumination of the ovarian medulla and cortex with a Plexiglas rod inserted through a small incision at the hilus. The technique, called "Transillumination-Aspiration Ovary" (TAO), increased the oocyte yield by 50% per ovary. The oocytes are probably recovered from deeper follicles which are difficult to identify during regular oocyte aspiration. The oocytes had a normal grading and exhibited normal in vitro development efficiency. Using the "TAO" technique we recovered 777 oocytes from 2160 follicles in 106 ovaries, a recovery rate of 36% from follicles and a mean of 7.3 oocytes/ovary. When we aspirated only surface follicles, we obtained 523 oocytes in 1384 visible follicles in 107 ovaries, for a recovery rates of 37% but a mean yield of 4.9 oocytes per ovary. Mean number of follicles were 20.5% with TAO and 12.8% without, thus recovery rates of oocytes per follicle were similar with both methods, but yield of oocytes per ovary was higher with TAO, thus showing that the difference between the two methods lies in higher numbers of visible follicles with TAO. Moreover, with the TAO technique 71% of the total oocytes we recovered (n=551) were grade I or II oocytes, in which 52% cleaved to the 2 to 4-cell stage and 26% had reached the blastocyst stage. We conclude that the method is effective for accurately locating cortical and peripheral follicles that contain oocytes suitable for IVF and in vitro embryo production (IVP).     

Collection of oocytes through transvaginal ultrasound-guided aspiration of follicles in an Indian breed of cattle

The present study was undertaken in Karan Fries, an Indian breed of cattle to (1) determine the number of follicles available for puncture and (2) explore the potential of this breed as a donor of developmentally competent oocytes. Ovum pick-up (OPU) was performed using an ultrasound machine with a transvaginal convex transducer (5 MHz) with a needle guide, single lumen 19-gauge 60 cm long needle and a vacuum pressure of 90 mmHg. The number and size of follicles in each ovary was determined before puncture. The follicles were characterized on the basis of their diameter as small (3-5 mm), medium (6-9 mm) and large (>/=10 mm). The oocytes recovered were classified by quality. They were matured in vitro, irrespective of their grade, in 50 microl droplets of the in vitro maturation (IVM) medium (TCM-199+10% fetal bovine serum(FBS)+5 microg/ml follicle stimulating hormone (folltropin)+1 microg/ml estradiol-17beta+0.2 mM sodium pyruvate), covered with paraffin oil, in 35 mm petridish for 24 h in a CO(2) incubator (5% CO(2) in air) at 38.5 degrees C. The cleavage rate was recorded at day 2 post-insemination after subjecting the oocytes to in vitro fertilization (IVF). The differences in follicular populations of all size categories among individual donors were not significant. A total of 92 oocytes were recovered by aspiration of 157 follicles, with an overall recovery rate of 59% (range 35-79%). Of these, 32% were of grades A and B and the rest of grades C and D. The mean numbers of total follicles and the oocytes recovered per session did not differ significantly among individual donors. Out of the 73 oocytes subjected to IVM and IVF, 24 reached 2-4 cell stage at day 2 post-fertilization, with a cleavage rate of 33%. The total number of oocytes recovered was correlated with the number of small (R=0.54, P<0.01) but not with the number of medium and large follicles. This study demonstrates the use of OPU as a means of obtaining developmentally competent oocytes from an Indian breed of cattle for obtaining cattle oocytes in India where cow slaughter is not allowed for religious reasons.     

In vivo oocyte recovery and in vitro embryo production from bovine oocyte donors treated with progestagen, oestradiol and FSH

The effect of treatment of donor cattle with progestagen and oestradiol or FSH on in vivo oocyte recovery and in vitro embryo production was studied. Forty-eight beefxFriesian cows formed eight replicates of six treatments in a 2 (no steroid versus steroid)x3 (none, single or multiple dose(s) of FSH) factorial design in which follicles were aspirated once weekly for 3 weeks. Oocytes were graded, washed, matured for 20-24h and then inseminated with frozen/thawed semen from a single sire followed by coculture on granulosa cell monolayers.Treatment with steroid had no significant effect on any follicular, oocyte or embryo production variate other than to reduce the number (P<0.05) and the diameter of large follicles>10mm (P<0.01) present at aspiration. FSH increased numbers of medium (6-10mm) and large follicles (P<0.01) and there was a corresponding decrease in the number of small follicles (2-5mm; P<0. 01). The total number of follicles at aspiration increased from 17. 7+/-1.60 for animals not treated with FSH to 23.6+/-1.97 following multiple dose treatment with FSH (P<0.05). Significantly, more follicles were aspirated following FSH treatment (no FSH 9.7+/-1.09, single dose FSH 13.6+/-1.30, multiple dose FSH 17.3+/-1.52; P<0.05) and numbers of oocytes recovered per cow per week increased (no FSH 4.1+/-0.76, single dose FSH 5.3+/-0.87, multiple dose FSH 5.9+/-0. 94) but the differences were not significant. Significantly, more good oocytes (Category 1) were recovered from animals treated with FSH (P<0.05). There was no overall significant effect of FSH on embryo production rate or the total number of transferable embryos produced but the number of transferable embryos was highest following administration of multiple doses of FSH.In conclusion, progestagen plus oestradiol 17beta treatment did not affect follicle, oocyte and embryo production of oocyte donors aspirated once per week. FSH treatment, however, significantly increased the number of follicles aspirated and Category 1 oocytes recovered. Multiple dose administration of FSH resulted in the production of the highest number of transferable embryos but this effect was not significant.     

Utilization of the growth phase of the first follicular wave for bovine oocyte collection improves blastocyst production

Characteristics of the follicle population and oocyte developmental competence at selected stages of follicular development were studied in cows with the aim to increase embryo production derived from oocytes collected by transvaginal aspiration. In Experiment 1, the growth phase before dominant follicle selection and the low dominant phase during dominant follicle regression were compared. Twenty-four cyclic Holstein cows, 4 to 6 yr of age, were divided into 2 groups. Animals were synchronized using two injections of prostaglandin F2alpha at 11 d intervals, and onset of estrus was determined (Day 0). Using ultrasonography, all follicles were counted and classified. Oocytes were aspirated once on Days I through 3 (Group 1, n=5) or Days 15 and 16 (Group 2, n=3) of the estrus cycle. The experiment was carried out in 3 replicates. In Experiment 2, the growth phase of the first follicular wave before dominant follicle selection was characterized in detail. Twelve cows of the same breed and age were divided into 3 groups. Their first estrus was synchronized as in Experiment 1, and each following estrus was induced using one injection of prostaglandin F2alpha administered 4 to 6 d after each aspiration performed. The ovaries were examined, and oocytes were collected repeatedly (total of 5 times per cow) on Days 1 (Group 3, n=4), 2 (Group 4, n=4) or 3 (Group 5, n=4) after estrus at 10 d intervals during a 40 d period. Viable oocytes were matured, fertilized and cultured using the standard methods. In Experiment 1, the mean numbers (+/-SD) of all follicles and of recovered and viable oocytes per donor were higher in Group 1 than in Group 2, but only the mean numbers (+/-SD) of larger follicles and recovered oocytes were statistically significant (8.0 +/- 0.6 and 6.2 +/- 0.6.vs. 3.3 +/- 0.5 and 2.8 +/- 0.2; P< 0.05). In Experiment 2, the percentage of larger follicles out of all visible follicles and the mean numbers (+/-SD) of larger follicles per donor were significantly higher (P<0.05) in Groups 4 (75.7 and 9.1 +/- 2.7) and 5 (66.3 and 8.5 +/- 2.9) when compared to Group 3 (27.9 and 3.8 +/- 0.8). The development rate of fertilized oocytes was significantly higher (P<0.05) in Groups 4 (27.8) and 5 (27.5) than in Group 3 (12.8). It can be concluded that it is possible to improve the efficiency of transvaginal aspiration and in vitro embryo production by utilization of the growth phase of the first follicular wave before dominant follicle selection.     

Effect of mare's age and recovery methods on the recovery rate of equine follicular oocytes for IVM procedures

Mares (n = 39) were classified according to age as young (less than 1.5 yr, n = 17) or old (more than 1.5 yr, n = 22) and sacrificed. Ovaries were measured and weighed, and the number of follicles and CL were counted. Follicle size and distribution were recorded (external: > 20 mm, < 20 mm; internal: > 5 mm, < 5 mm). External follicles were aspirated while internal follicles were sliced. The number and Type of oocytes recovered using each method were recorded. Oocyte recovery rates (oocytes/ovary) resulted in a mean of 0.92 oocytes by aspiration and 1.36 oocytes by additional slicing. The mean numbers of available follicles (8.11 and 5.02) oocytes recovered (4.94 and 3.02) and oocytes selected per ovary (3.29 and 2.32) were not significantly different in the young or old mares, respectively.     

Changes in the cumulus-oocyte complex of subordinate follicles relative to follicular wave status in cattle

We investigated factors that affect cumulus-oocyte complex (COC) morphology and oocyte developmental competence in subordinate follicles on different days after follicular wave emergence in beef heifers. In Experiment 1, heifers (n = 13) were assigned at random to COC aspiration during the growing/static (Days 1 to 3) or regressing (Day 5) phase of subordinate follicle development (follicular wave emergence = Day 0). Follicular wave emergence was induced by transvaginal ultrasound-guided follicular ablation, ovaries were collected at slaughter, all follicles > or = 2 mm except the dominant follicle were aspirated, and COC were microscopically evaluated for morphology. There was a greater percentage of COC with expanded cumulus layers on Day 5 (42.4%) than on Days 1 to 3 (2.2%). In Experiment 2, heifers (n = 64) at random stages of the estrous cycle had all follicles > or = 5 mm ablated and 4 d later, 2 doses of PGF were injected 12 h apart; heifers were monitored daily by ultrasonography for ovulation (Day 0 = follicular wave emergence). Heifers were assigned to the following time periods for oocyte collection from subordinate follicles: Days 0 and 1 (growing phase), Days 2, 3 and 4 (static phase), and Days 5 and 6 (regressing phase). Ovaries were individually collected at slaughter, and all follicles > or 2 mm except for the dominant follicle were aspirated. The COC were morphologically evaluated and then matured, fertilized and cultured in vitro. Expanded COC were more frequent during the regressing phase (53.4%) than the growing or static phase (14.4 and 17.8%, respectively; P < 0.05). While the proportions of COC with > or = 4 layers of cumulus cells and denuded oocytes were higher (P < 0.05) in the growing and static phases, the production of morulae was highest (P < 0.05) with COC collected from subordinate follicles during the regressing phase. In Experiment 3, heifers (n = 18) were assigned at random to oocyte collection from subordinate follicles 3 and 4 d (static phase) or 5 and 6 d (regressing phase) after follicular wave emergence. The heifers were monitored ultrasonically for ovulation (Day 0 = follicular wave emergence); COC were collected from all follicles (> or = 5 mm) except for the dominant follicle by transvaginal ultrasound-guided follicle aspiration 3 to 6 d later. Recovered oocytes were stained and examined microscopically to evaluate nuclear maturation. A higher proportion of oocytes collected on Days 5 and 6 showed evidence of nuclear maturation (50%) than on Days 3 and 4 (8.3%; P < 0.05). Results support the hypothesis that COC morphology and oocyte developmental competence change during the growing, static and regressing phases of subordinate follicle development.     

Transvaginal ultrasound-guided oocyte retrieval following FSH stimulation of domestic goats

The objectives of this study were to evaluate different ovarian stimulation protocols on donor goats and to develop a safe, repeatable method for harvesting oocytes from FSH-treated does (Experiment I). Based on the preliminary findings of the first experiment, 32 crossbred does were used in a second experiment (Experiment II), 16 that had not been previously aspirated and 16 that had undergone one previous aspiration, were used to fine tune the procedure. Females were randomly subjected to 1 of the 2 ovarian stimulation protocols: Treatment (A) does were implanted with a norgestomet ear implant. Starting 10 d post-implantation, does were administered FSH daily for 4 d. Does in Treatment (B) were treated similarly to those in (A) but were implanted for only 3 d before starting the FSH injections and implants were not removed prior to aspiration. Using a 2 x 2 factorial arrangement, fresh does (n=16), not previously aspirated, were then further randomly assigned to either a laparoscopic aspiration procedure (LAP) or a transvaginal ultrasound-guided aspiration procedure (TUGA).The LAP procedure was performed using a fiber optics. For the TUGA, the doe was placed in dorsal recumbency, and a 5 MHz human transvaginal transducer, attached to the ultrasound unit, was positioned vaginally for oocyte aspiration. In summary, there was no significant difference among treatment groups for parameters evaluated, with the exception of methods for oocyte collection. The number of follicles detected and oocytes harvested using TUGA (9.5 and 4.3, respectively) was less than for females obtained by LAP (17.4 and 14.4, respectfully). The percentage of oocytes recovered from does subjected to the TUGA (68%), however, was similar to those subjected to the LAP (69%). Unlike donor does subjected to a repeated LAP, there was no evidence of adhesions in donor does from the repeated TUGA group. The TUGA approach to oocyte collection should not be overlooked in an effort to decrease the chances of adhesions in valuable donor goats.