Effect of advancing the breeding season on reproductive performance of dromedary camels.

This study examines the effect of advancing the breeding season on the reproductive performance of dromedary camels under an intensive management system. Using a synchronization protocol, timed natural mating in female camels was carried out either in September (2 months ahead of the natural breeding season, n = 182) or December (peak breeding season, n = 115). The ovarian responses (size of the dominant follicle at the time of mating and ovulation), pregnancy rate, and pregnancy losses were evaluated using ultrasonography. Blood samples were collected after mating to assess progesterone concentrations by RIA. The libido of male camels (n = 13) was evaluated objectively. Results showed that the percentage of female camels with an optimal sized follicle (11-17 mm) for breeding at the time of mating was lower in September compared to December (81.9 vs 91.3%, P = 0.03). The libido of male camels was lower in September than in December (P <0.001). The ovulation rate (86.3 vs 93.9%, P = 0.04), size of the ovulated follicle (12.7 ± 0.1 vs 13.7 ± 0.2 mm, P <0.001), pregnancy rates on Day 14 (47.8 vs 72.2%, P <0.001) and Day 90 (38.5 vs 60.9%, P <0.001) after mating was lower in September compared to December. However, pregnancy loss was not affected between months (15.7 vs 19.5%, P = 0.3). Among pregnant camels, the progesterone concentrations on Days 6, 8, 10, 12 and 14 after mating were lower in September as compared to December (P <0.001). In non-pregnant camels, the progesterone concentrations on Days 6, 8 and 10 after mating were also lower in September as compared to December (P <0.001). In conclusion, advancing the breeding season by two months, significantly affects the reproductive performance of dromedary camels, yet, acceptable pregnancy rates can be achieved.

Superovulation of dromedary camels with eCG: An effective and practical technique.

This study was conducted to develop simple superovulation protocols for dromedary camels using eCG. In experiment 1, camels received either 1000, 2000, 3000, 4000, 5000 or 6000 IU eCG. In experiment 2, camels received either 400 mg FSH (Folltropin-V) twice-daily over 5 days or 3000 IU eCG. In experiment 3, camels received 3000 IU eCG either at 2, 3, 4 or 5 days after ovulation induction. Ovarian response and embryo yield were evaluated in all experiments and embryos collected from camels treated with FSH and eCG were transferred to recipients to examine pregnancy rates. The mean number of ovulations (12.6 ± 1.5 and 13.3 ± 1.2 vs 3.4 ± 0.3, 6.2 ± 0.6 and 9.3 ± 1.0, respectively) and transferable embryos (4.6 ± 1.3 and 4.8 ± 1.0 vs 1.6 ± 0.2, 2.2 ± 0.4 and 1.1 ± 0.4, respectively) with 3000 and 4000 IU eCG doses were higher compared to 1000, 2000 and 6000 IU eCG doses (P < 0.05). Doses of 5000 and 6000 IU eCG resulted in a higher number of unovulatory follicles than other doses (P < 0.05). The FSH treatment resulted in higher number of ovulatory follicles (21.8 ± 1.3 vs 14.8 ± 1.7) and ovulations (18.5 ± 1.1 vs 13.9 ± 1.4) compared to eCG (P < 0.05). However, the number of transferable embryos and pregnancy rates were similar in these treatments. The timing of eCG treatment after ovulation induction did not affect the number of ovulatory follicles and transferable embryos but eCG treatment at 5 days after ovulation induction reduced the number of ovulations (P < 0.05). In conclusion, the optimal dose of eCG to induce superovulation is 3000-4000 IU and it produces a comparable embryo yield to FSH, and can be administered at 2-4 days after ovulation induction.

Liquid storage of dromedary camel semen in different extenders.

This study was conducted to assess the effects of commercial extenders and storage temperature on dromedary camel sperm quality during liquid preservation. In Experiment 1, ejaculates (n = five males; replicated seven times) were split and diluted with synthetic (OPTIXcell, EquiPlus, INRA96, Bioxcell or AndroMed; Experiment 1a) or egg-yolk based (Biladyl, Green buffer or Triladyl; Experiment 1b) extenders and stored for 48 h at 4 °C. In Experiment 2, split ejaculates (n = five males; replicated six times) were used to directly compare Green buffer, OPTIXcell and Triladyl extenders over 48 h of storage at 4 °C. Ejaculates collected in Experiment 3 (n = five males; replicated five times) were diluted with Green buffer or Triladyl before chilled storage for 48 h at 4 or 15 °C. Sperm kinematics, viability and acrosome integrity were assessed during liquid storage. In Experiment 1a, there was the greatest total sperm motility (TM) in the OPTIXcell group following 24 and 48 h of storage, while in Experiment 1b, there was the greatest TM after 48 h of storage with Triladyl and Green buffer. In Experiment 2, there were greater TM and viable acrosome intact spermatozoa in the Triladyl and Green buffer than with OPTIXcell group. In Experiment 3, there was a greater TM in the Triladyl than Green buffer group at 24 and 48 h of storage regardless of storage temperature (which had no effect on sperm quality). In conclusion, camel sperm have greater viability when preserved in liquid form for 48 h following dilution with Triladyl and storage at either 4 or 15 °C.

Reproductive seasonality of male dromedary camels.

Reproductive seasonality has been reported in numerous species, including male dromedary camels, yet investigations into seasonal changes in camel semen quality have yet to be conducted. The aim of this study was to characterise the seasonal changes in camel semen quantity and quality as well as correlate these changes to testis and accessory sex gland morphology, sexual behaviour, libido and environmental factors such as day length and ambient temperature in Oman. Semen was collected twice a month for a year and testicular and accessory sex organ biometry recorded once a month via ultrasonography (n = 8 bulls). Blood samples were collected monthly to assess testosterone levels. Results indicated that testes and accessory sex glands size increased during October-April, peaking with testosterone concentrations during January (P<0.05). The sexual behaviour and libido of camels was also greater during the months of October-April (P<0.05). Attempts to collect semen were 100% successful during November-February. Semen volume, as well as sperm gross activity, concentration, motility, average path velocity and percentage with intact acrosomes were the greatest during January and decreased from May-September (P<0.05). Changes in values for semen variables, testosterone concentrations and sex organ anatomy were also highly correlated with seasonal changes in day length and ambient temperatures. In conclusion, a clearly defined reproductive season was observed in male camels in Oman ranging from December-March, with peak reproductive function occurring during December-January. To increase the success of breeding programs, matings or semen collections should be timed to occur when reproductive function is maximal.

Simplified superovulation protocols in dromedary camels (Camelus dromedarius).

This study was conducted to develop simple superovulation protocols in dromedary camels. Using two commercial FSH products, a series of experiments was conducted to evaluate the effect of different superovulation protocols on ovarian response and embryo production. In experiment 1, camels in control group (n = 15) received 400 mg Folltropin-V in a traditional protocol (FSH diluted in saline and given twice daily in decreasing doses over 5 days) and camels in split-injection (2 doses 48 h apart) groups received either 400 (n = 16, first dose: 320 mg, second dose: 80 mg) or 200 mg (n = 16, first dose: 120 mg, second dose: 80 mg) of slow-release (SR) preparation of Folltropin-V [Folltropin-V diluted in hyaluronan (5 mg/mL) solution]. In experiment 2, camels in control group (n = 13) received 2000 IU Pluset in a traditional protocol and camels in split-injection groups received either 2000 (n = 14, first dose: 1600 IU, second dose: 400 IU) or 1000 IU (n = 16, first dose: 600 IU, second dose: 400 IU) of SR preparation of Pluset (Pluset diluted in hyaluronan solution). In experiment 3, camels received SR preparation of 200 mg Folltropin-V (n = 45, first dose: 120 mg, second dose: 80 mg) or 1000 IU Pluset (n = 42, first dose: 600 IU, second dose: 400 IU) in a split-injection protocol. In experiments 1 and 2, the mean number of ovulations, corpora lutea, transferable embryos and unfertilized ova were similar (P > 0.05) between groups. In experiment 3, there was no difference (P > 0.05) between SR preparations of Folltropin and Pluset on the number of ovulatory sized (≥9 mm) follicles (15.8 ±â€¯0.9 vs 16.7 ±â€¯0.9) and transferable embryos (5.0 ±â€¯0.4 vs 5.2 ±â€¯0.5). In conclusion, split-injection of SR preparation of FSH resulted in a similar superovulatory response compared to a traditional protocol and a similar superovulatory response can be achieved with SR preparations of Folltropin-V and Pluset in a split-injection protocol.

Effect of semen collection frequency on the semen characteristics of dromedary camels.

The effect of semen collection frequency (once or twice per week) on the sexual behaviour, libido and semen characteristics (volume, colour, gross activity, viscosity, sperm concentration, morphology, motion characteristics and membrane viability and acrosome integrity) of dromedary camels (n = 7) was investigated over the course of 8 weeks. Results showed that frequency of collection influenced male camel libido (P < 0.05) but not sexual behaviour. Once per week collection frequency resulted in greater gross activity (2.7 ± 0.1 compared with 1.7 ± 0.1, P < 0.001) and greater sperm concentration (403 ± 16 compared with 261 ± 18 × 106 spermatozoa/mL, P < 0.001) compared to ejaculates collected twice per week. When collected twice per week, ejaculates collected during the first 3 weeks had a greater sperm concentration than those collected from week 4 onwards (P < 0.001). All ejaculates (100%) collected once per week 'qualified' (Criteria: > 60% total motility or > 100 × 106 spermatozoa/mL) for subsequent processing, but when collected twice per week the percentage of qualified ejaculates dropped sharply after three weeks (P < 0.001; 69% of ejaculates qualified over 8- week collection period). Twice weekly collection frequency caused a reduction (P < 0.001) in progressive motility, path velocity, track speed, lateral head amplitude, beat cross frequency and straightness. In conclusion, during the peak breeding season, semen can be collected twice per week from dromedary male camels for a period of 3 weeks only or once per week for 8 weeks without affecting semen quality.

Resynchronization of synchronized follicular wave in dromedary camels of unknown pregnancy status (Camelus dromedarius).

This study was designed to evaluate the use of resynchronization (Resynch) protocol in dromedary camels. In experiment 1, the effect of initiation of Resynch protocol with GnRH treatment on Day 14 ±â€¯2 after timed breeding (TB) in camels of unknown pregnancy status on pre-established pregnancy and resynchronized fertility, was examined. The camels (n = 201) were divided into two groups after synchronized TB. Control (n = 98) group camels were examined for early pregnancy on Day 21 ±â€¯2 after TB and second mating in nonpregnant camels was done when a dominant follicle of 11-17 mm in diameter was present. Resynch (n = 103) group camels received GnRH treatment on Day 14 ±â€¯2 after TB and PGF2α treatment upon nonpregnancy diagnosis (7 days later) and second mating (resynchronized TB) was done (12 days after GnRH). The pregnancy diagnosis and losses were monitored using ultrasonography. The pregnancy rate on Day 90 (61.2 vs. 59.2%) after TB and pregnancy loss (14.3 vs 11.6%) were similar between control and Resynch groups (P >0.05). There was also no difference in the pregnancy rate (57.1 vs 52.9%) after second mating between the groups (P >0.05). In experiment 2, the reproductive performance following synchronized and resynchronized timed natural services was evaluated in camels under farm (n = 120) and field conditions (n = 214) conditions. Acceptable pregnancy rates were recorded after synchronized TB-1, resynchronized TB-2 and TB-3 under farm and field conditions. After 3 timed services, a cumulative pregnancy rate of 82.5 and 79.7% was recorded under farm and field conditions respectively. In conclusion, the Resynch protocol initiated with GnRH treatment on Day 14 ±â€¯2 after breeding, with unknown pregnancy status, was effective in resynchronizing the follicular wave for subsequent TB, without having any effect on the pre-established pregnancy in dromedary camels.

Synchronisation of the follicular wave with GnRH and PGF2α analogue for a timed breeding programme in dromedary camels (Camelus dromedarius).

This study was conducted to develop a hormone protocol that precisely synchronises follicular development for a timed breeding (TB) programme in dromedary camels. To examine the effect of GnRH treatment at four known stages of follicular development, animals were treated with GnRH when the largest follicle of the wave was 4-7, 8-11, 12-17 and 18-27 mm in diameter. Transrectal ultrasonography was carried out daily up to 20 days after treatment. A hormone protocol (FWsynch) for the synchronisation of follicular wave and TB consisting of GnRH-1 (GnRH) on Day 0, PG-1 (PGF2α) on Day 7, GnRH-2 on Day 10 and PG-2 on Day 17 was initiated at four known stages of follicular development. Ovarian structures were monitored by ultrasonography. The FWsynch protocol was initiated at random stages of follicle development and animals were bred by natural mating at a fixed time at the research facility and in field. The pregnancy was diagnosed by ultrasonography. GnRH treatment in animals with a dominant follicle (DF) of ≥ 11 mm in diameter resulted in synchronous new follicular wave emergence, whereas in animals with a DF ≤ 10 mm, the treatment did not alter the development of the existing follicular wave. The FWsynch protocol was effective in synchronising the follicular wave for TB irrespective of the stage of follicular development at the beginning of the protocol. TB using FWsynch protocol resulted in a pregnancy rate of 60.2% in a research facility and 53.6% and 45.6% in normal and infertile camels respectively under field conditions.

Ultrasonographic characterization of follicle deviation in follicular waves with single dominant and codominant follicles in dromedary camels (Camelus dromedarius).

Follicular wave emergence was synchronized by treating camels with GnRH when a dominant follicle (DF) was present in the ovaries. Animals were scanned twice a day from day 0 (day of GnRH treatment) to day 10, to characterize emergence and deviation of follicles during the development of the follicular wave. Follicle deviation in individual animals was determined by graphical method. Single DFs were found in 16, double DFs in 9 and triple DFs in two camels. The incidence of codominant (double and triple DFs) follicles was 41%. The interval from GnRH treatment to wave emergence, wave emergence to deviation, diameter and growth rate of F1 follicle before or after deviation did not differ between the animals with single and double DFs. The size difference between future DF(s) and the largest subordinate follicle (SF) was apparent from the day of wave emergence in single and double DFs. Overall, interval from GnRH treatment to wave emergence and wave emergence to the beginning of follicle deviation was 70.6 ± 1.4 and 58.6 ± 2.7 h, respectively. Mean size of the DF and largest SF at the beginning of deviation was 7.4 ± 0.2 and 6.3 ± 0.1 mm, respectively. In conclusion, the characteristics of follicle deviation are similar between the animals that developed single or double DFs.

Characterization of ovarian follicular dynamics in dromedary camels (Camelus dromedarius).

Ovarian follicular dynamics was monitored by transrectal ultrasonography, for a period of 60 to 90 days, and its correlation with plasma estradiol-17ß (E2) and progesterone (P4) were studied in seventeen, multiparous, non-lactating, 12 to 20-year-old dromedary camels. The average number of follicles recruited (12.77 ± 0.93) in each wave between animals varied (P < 0.001). The number of follicles recruited during different follicular waves was highly repeatable (0.95) within individual animals. The growth and mature phase periods of the dominant follicle (DF) were 6.10 ± 0.15 and 10.20 ± 0.47 days, respectively with a linear growth rate of 1.17 ± 0.02 mm/day between Day 0 and 10 of the follicular wave. There was an inverse relationship between the diameter of the largest DF and number of follicles (r = -0.95, P < 0.001). The DF development did not regularly alternate between the ovaries and the incidence of codominance was 45%. The mean maximum diameter of DF during its mature phase was 27.30 ± 0.78 mm and oversized follicle was 38.43 ± 1.41 mm. In 73.3% waves, the DF continued its growth for a period of 10.64 ± 1.53 days even after losing its dominance and developed into oversized follicle. The duration of the regression phase of DF and oversized follicle were 24.71 ± 3.79 and 18.50 ± 2.23 days. The mean duration of a complete follicular wave was 47.11 ± 2.94 days with an interwave interval (IWI) of 16.36 ± 0.37 days. The IWI within an individual was repeatable (0.88) and between the animals was variable (P < 0.001). Plasma E2 concentration profiles showed a wave like pattern. The peak plasma E2 concentrations were attained approximately 12 days after beginning of the growth phase, when the largest DF grew to a diameter of 18.7 mm. Plasma concentration of P4 was below 1.0 ng/mL in 85% of waves and above 1.0 ng/mL in 15% of the waves for a period of 3 to 6 days in the absence of spontaneous ovulation. It is concluded that ovarian follicular development and plasma E2 concentrations occurs in a wave like pattern in dromedary camels and the IWI and follicle numbers recruited per wave are variable between the animals and repeatable within an individual animal.

Effect of progesterone from induced corpus luteum on the characteristics of a dominant follicle in dromedary camels (Camelus dromedarius).

The present study was carried out to elucidate the effect of progesterone (P4) from the induced corpus luteum (CL) on the characteristics of the dominant follicle (DF) in dromedary camels (Camelus dromedarius). Ovarian follicular and induced CL dynamics were monitored by transrectal ultrasonography in eight camels during the peak breeding season. The characteristics of the DF were monitored daily from the day of emergence into a wave, until it appeared to lose its dominance and the DF of a subsequent wave grew to a diameter of 13-17 mm. At this stage ovulation was induced by hCG and the DF was monitored every 8 h for 48 h. After ovulation, CL dynamics and follicular development (emergence of a new wave, growth and mature phase of the selected DF) were monitored daily. Blood samples were collected during each ultrasound examination to study the P4 profile in these animals. The CL developed to a maximum size (22.55 ± 3.24 mm) with a peak concentration of P4 (4.60 ± 2.57 ng/ml) 7 days after ovulation. The size of the CL was positively correlated with the P4 concentration (r = 0.612) during the different stages of the CL dynamics. The presence of CL did not affect the linear growth rate, duration of growth and mature phases of the DF. The development of the DF to its maximum size during its mature phase and inter-wave interval were not affected by the P4 secreted by the induced CL. In conclusion, there is no evidence from this study to suggest that P4 from induced CL altered the characteristics of a DF in dromedary camels.

Post-thaw development of in vitro produced buffalo embryos cryopreserved by cytoskeletal stabilization and vitrification.

The present study was conducted to examine post-thaw in vitro developmental competence of buffalo embryos cryopreserved by cytoskeletal stabilization and vitrification. In vitro produced embryos were incubated with a medium containing cytochalasin-b (cyto-b) in a CO(2) incubator for 40 min for microfilament stabilization and were cryopreserved by a two-step vitrification method at 24 degrees C in the presence of cyto-b. Initially, the embryos were exposed to 10% ethylene glycol (EG) and 10% dimethylsulfoxide (DMSO) in a base medium for 4 min. After the initial exposure, the embryos were transferred to a 7 microl drop of 25% EG and 25% DMSO in base medium and 0.3 M sucrose for 45 sec. After warming, the embryos were cultured in vitro for 72 h. The post-thaw in vitro developmental competence of the cyto-b-treated embryos did not differ significantly from those vitrified without cyto-b treatment. The hatching rates of morulae vitrified without cyto-b treatment was significantly lower than the non-vitrified control. However, the hatching rate of cyto-b-treated vitrified morulae did not differ significantly from the non-vitrified control. This study demonstrates that freezing of buffalo embryos by cytoskeletal stabilization and vitrification is a reliable method for long-term preservation.

Isolation and culture of ovine and bubaline small and large pre-antral follicles: effect of cyclicity and presence of a dominant follicle.

Studies were conducted to examine the effects of the cyclicity and the presence of a dominant follicle (DF) in ovary on the recovery and in vitro growth of pre-antral follicles (PFs) in sheep and buffalo. Small pre-antral follicles (SPFs, 100-250 microm) and large pre-antral follicles (LPFs, 250-450 microm) were isolated from slaughterhouse ovaries in the breeding seasons by a mechanical and enzymatic method. The sheep and buffalo PFs were cultured in vitro for 6 and 15 days, respectively, and examined for their growth, survival and antrum formation rates and growth rates of oocytes in cultured pre-antral follicles. The follicles of the sheep and buffalo were recovered and cultured simultaneously within replicates. The recovery rates (number per ovary) of both SPFs and LPFs were significantly (p < 0.05) higher in cyclic ewes (SPFs: 22.0 +/- 3.3 vs 12.1 +/- 2.6 and LPFs: 16.0 +/- 3.6 vs 9.2 +/- 1.8) and buffaloes (SPFs: 9.2 +/- 1.3 vs 4.1 +/- 1.0 and LPFs: 10.3 +/- 2.7 vs 5.4 +/- 0.7) compared with those recovered from acyclic ones. Presence of a DF in ovary significantly (p < 0.05) reduced the recovery rates of LPFs in ewes (9.06 +/- 2.7 vs 16.4 +/- 3.8) but had no effect in buffalo. Cyclicity of animals or follicular dominance had no effects on in vitro growth, survival and antrum formation rates and growth rates of oocytes in cultured PFs of SPFs and LPFs in both sheep and buffalo. The in vitro growth, survival and antrum formation rates of LPFs and growth rates of oocytes in cultured LPFs were significantly (p < 0.05) higher than those observed in SPFs in both sheep and buffalo. The overall recovery and growth rates of the PFs were lower in buffaloes compared with ewes.

Effect of vitrification medium composition and exposure time on post-thaw development of buffalo embryos produced in vitro.

This study examined the effects of different vitrification medium compositions and exposure times (2, 4 and 6min) on the post-thaw development of buffalo embryos produced in vitro (IVP). The compositions were (1) 40% ethylene glycol (EG); (2) 25% glycerol (G)+25% EG, and (3) 25% EG+25% dimethylsulfoxide (DMSO). The base medium was 25mM Hepes-buffered TCM-199+10% steer serum +50microg/mL gentamycin. The IVP embryos were cryopreserved by a two-step vitrification method at 24 degrees C. After warming, the embryos were cultured in vitro for 72h. The vitrification of morulae and blastocysts in 25% EG+25% DMSO with an exposure time of 2 and 4min, respectively, resulted in a better hatching rate than other combinations. The hatching rate of morulae vitrified in 25% EG+25% G, 25% EG+25% DMSO, and blastocysts vitrified in 40% EG, 25% EG+25% DMSO were negatively correlated with exposure time. However, the hatching rate of blastocysts vitrified in 25% EG+25% G was positively correlated with exposure time. The study demonstrated that the post-thaw in vitro development of IVP buffalo embryos was affected by the vitrification medium composition and exposure time.

Effect of breeding season on in vivo oocyte recovery and embryo production in non-descriptive Indian river buffaloes (Bubalus bubalis).

The present study was carried out to examine the effect of season on in vivo oocyte recovery and embryo production in non-descriptive, Indian river buffaloes (Bubalus bubalis). Ovum pick up (OPU) was conducted twice a week for 8 weeks during peak (October-March) and low (April-September) breeding season in live buffaloes (n=6). OPU was performed using ultrasound equipment with a 5MHz transvaginal transducer, a single lumen 18-gauge, 55-cm long needle and a constant vacuum pressure of 110mmHg. The number and size of follicles was determined before puncture. The recovered oocytes were graded and only grade A and grade B oocytes were used for in vitro production (IVP) of embryos. The mean number of follicles observed per animal per session did not differed (P<0.05) between animals or between puncture sessions in both low and peak breeding seasons. Higher (P<0.05) number of follicles were observed (4.8+/-0.2 versus 3.1+/-0.3) and punctured (4.0+/-0.2 versus 2.4+/-0.2) during peak breeding season when compared to low breeding season. Oocytes recovered (1.6+/-0.1 versus 1.0+/-0.3) per animal per session were higher (P<0.05) in peak breeding season than low breeding season. During the peak breeding season, the blastocyst yield per animal per session (0.3+/-0.4 versus 0.18+/-0.4) was higher (P<0.05) than the low breeding season. However, season did not significantly affect the percentage of oocytes suitable for IVP (grade A+B) and blastocyst production rate. In conclusion, the efficiency of OPU combined with IVP was higher during the peak breeding season than the low breeding season in buffaloes.

Effect of taurine and melatonin in the culture medium on buffalo in vitro embryo development.

This study was carried out to investigate the effect of supplementing culture medium with different concentrations of taurine and melatonin, on buffalo oocyte in vitro meiotic maturation and embryo development. In experiment 1, oocytes were matured in vitro and the cleaved embryos were cultured in the same following seven culture medium; (i) control (TCM 199 + 10% SS); (ii) control + 0.5 mM taurine; (iii) control + 1 mM taurine; (iv) control + 3 mM taurine; (v) control + 5 microM melatonin; (vi) control + 10 microM melatonin and (vii) control + 50 microM melatonin. In experiment 2, based on the results of experiment 1, to examine the synergistic effect of antioxidants, the oocytes were matured in culture medium (TCM199 + 10% SS), supplemented with both taurine at 1 mM and melatonin at 10 microM concentration and the cleaved embryos were cultured in the same medium. Supplementation of taurine at 1 mM concentration in the culture medium resulted in a higher (p < 0.05) transferable embryo (TE) yield when compared with control (20.6% vs 14.1%). Supplementation of melatonin at 10 and 50 microM concentration in the culture medium resulted in a higher (p < 0.05) meiotic maturation rate (90.3% and 88.8% respectively) and TE yield (28.4% and 27.2% respectively), than the other treatments. In experiment 2, the TE yield did not improve by supplementing the culture medium with both taurine and melatonin, when compared with melatonin alone. In conclusion, the results of this study demonstrated that, enriching the culture medium with taurine and melatonin, improves in vitro embryo production efficiency in buffaloes. In particular, a high TE yield was obtained by enriching the culture medium with 10 microM melatonin.

Co-culture of buffalo preantral follicles with different somatic cells.

The effect of co-culture of buffalo preantral follicles (PFs) with different somatic cells, i.e, cumulus, granulosa, ovarian mesenchymal and oviductal epithelial cells was studied. Large PFs (250-450 microm) were isolated by microdissecting the trypsin (1%) digested ovarian cortical slices. Cumulus cells were isolated by repeated pipetting of oocytes, granulosa cells were isolated by aspirating from punctured PFs and ovarian mesenchymal cells were isolated from ovarian cortex by scraping the cortical slices and passing through 20 microm filter. Preantral follicles were cultured in standard culture medium without somatic cells or co-cultured with cumulus cells, granulosa cells, ovarian mesenchymal cells and oviductal epithelial cells for 80 days. The growth rate (microm/day) of the PFs was monitored by measuring follicular diameter on day 0, 30, 60 and 80 days of culture. The viability of PFs was evaluated by trypan blue staining. The results indicated that PFs co-cultured with cumulus, granulosa and ovarian mesenchymal cells had a better development and survivality compared with control and those co-culture with oviductal epithelial cells. Maximum growth and survivality of PFs were achieved when cultured with cumulus cells. It is concluded that inclusion of somatic cells in PF culture media had beneficial effect on the growth of PFs and cumulus cells supported maximum growth and survivality of PFs in vitro of all somatic cells tested.

Oocyte recovery by ovum pick up and embryo production in river buffaloes (Bubalus bubalis).

Ovum pick up (OPU) was conducted twice a week for 12 weeks in six cycling, non-descriptive (local breed), Indian buffaloes to study the efficiency of OPU on recovery of oocytes for embryo production. OPU was performed using an ultrasound equipment with a 5-MHz transvaginal transducer, a single-lumen, 18-gauge, 55-cm-long needle and a constant vacuum pressure of 110 mmHg. The number and size of follicles were determined before puncture. The recovered oocytes were graded, washed, matured for 24 h and then fertilized with frozen-thawed semen, followed by embryo culture on the oviductal monolayer. The mean number of follicles observed per animal per session did not differ between animals or between puncture sessions. A mean number of 3.62 +/- 0.32 mm follicles were observed, 2.90 +/- 0.15 mm follicles were punctured and 1.21 +/- 0.07 oocytes were recovered per animal per session, with an average recovery rate of 42%. Of the total oocytes recovered, 64% were suitable for in vitro embryo production (grade A + B) whereas 36% were classified to be of grades C + D. A mean number of 0.25 +/- 0.2 transferable embryos was produced in vitro per buffalo per session with a transferable embryo production rate of 32%. In conclusion, this study demonstrated that twice-a-week OPU could be applied repeatedly, without any adverse effects on the follicular growth and oocyte recovery and that recovered oocytes could be used for in vitro embryo production in buffaloes.

Production of buffalo embryos using oocytes from in vitro grown preantral follicles.

The present study examines the use of buffalo preantral follicles as a source of oocytes for in vitro embryo production. Preantral follicles were isolated from abattoir-derived buffalo ovaries and were grown for 100 days in five different culture systems: (1) minimum essential medium (MEM); (2) coconut water; (3) MEM + ovarian mesenchymal cell (OMC) co-culture; (4) MEM + granulosa cell (GC) co-culture; or (5) MEM + cumulus cell (CC) co-culture. Low growth rates for the preantral follicles were observed when follicles were cultured in MEM or coconut water medium. Moderate growth rates were seen for OMC and GC co-cultures, and high rates of growth were observed when follicles were grown in CC co-culture. The survival of preantral follicles was low in the MEM culture (<25%), but was over 75% in the other culture systems. Oocytes were not recovered from the MEM group, while an oocyte recovery rate of 80-100% was observed when the follicles were cultured with coconut water/somatic cells. Transferable embryos could be produced only with the oocytes obtained from preantral follicles grown in the OMC and CC co-culture systems. This study demonstrates, for the first time, that it is possible to produce buffalo embryos by in vitro fertilization of oocytes derived from in vitro grown preantral follicles.

In vitro embryo development and blastocyst hatching rates following vitrification of river buffalo embryos produced from oocytes recovered from slaughterhouse ovaries or live animals by ovum pick-up.

The present study was undertaken to determine whether the source of oocytes (ovum pick up versus slaughterhouse ovaries) affected in vitro embryo production and embryo survival (as measured by blastocyst hatching rates) following vitrification in buffaloes (Bubalus bubalis). Oocytes recovered from live buffaloes (n=6) by ovum pick up (OPU) and by manual aspiration from slaughterhouse ovaries were in vitro matured, fertilized and cultured to blastocyst stage under same culture conditions. Vitrification of blastocysts was carried out in two steps at 24 degrees C. Embryos were equilibrated in 10% EG+10% DMSO+0.3 M sucrose in base medium for 4 min. Subsequently, the embryos were transferred into 25% EG+25% DMSO+0.3 M sucrose in base medium for 45 s and then the embryos were loaded into straws and immersed in liquid nitrogen. Following warming, blastocysts were cultured in vitro for 48 h to assess hatching. Oocytes derived from live animals by OPU resulted in a significantly higher blastocyst yield then those derived from slaughterhouse ovaries (30.6+/-4.3 versus 18.5+/-1.8). Blastocyst hatching rates following vitrification of buffalo embryos produced from the oocytes collected from live animals by OPU was significantly higher than the oocytes collected from slaughterhouse ovaries (52.8+/-4.2 versus 40.2+/-4.4). In conclusion, the present study showed that source of oocytes (OPU versus slaughterhouse ovaries) affects the in vitro embryo development and blastocyst hatching rates following vitrification of embryos in buffaloes.