Determinants of Trans-Cervical Artificial Insemination Success in Synchronized Ewes Using Frozen Semen
محورهای موضوعی : Camel
N. Naher
1
(Department of Surgery and Obstetrics, Faculty of Veterinary Science, Bangladesh Agricultural University, Mymensingh-2202, Bangladesh)
S. Arif
2
(Department of Surgery and Obstetrics, Faculty of Veterinary Science, Bangladesh Agricultural University, Mymensingh-2202, Bangladesh)
M. Hossain
3
(Department of Surgery and Obstetrics, Faculty of Veterinary Science, Bangladesh Agricultural University, Mymensingh-2202, Bangladesh)
N. Sultana Juyena
4
(Department of Surgery and Obstetrics, Faculty of Veterinary Science, Bangladesh Agricultural University, Mymensingh-2202, Bangladesh)
F. Yeasmin Bari
5
(Department of Surgery and Obstetrics, Faculty of Veterinary Science, Bangladesh Agricultural University, Mymensingh-2202, Bangladesh)
کلید واژه: conception rate, cervical penetration depth, estrus signs intensity, TCAI, VER,
چکیده مقاله :
The study was undertaken to observe the effects of cervical penetration depth, estrus signs intensity and vaginal electrical resistance on conception rate in ewes following trans-cervical artificial insemination with frozen semen. Twenty-four ewes were synchronized using 100 µg Prostaglandin F2α intramuscularly, twice at 9 days interval. Estrus behavior of ewes with teaser ram was observed to determine the estrus onset and intensity. Vaginal electrical resistance was recorded immediately before insemination using electrical heat detector. A 200 µg tablet, Misoprostol was administered intra-vaginally in 10 ewes 11 hours before insemination, and cervical penetration depth was measured by centimeter graduated steel rod. Conception rate was confirmed by ultrasonography at 40-42 days of insemination. The cervical penetration depth was significantly increased (P<0.05) in Misoprostol-treated ewes compared to non-treated ones (3.54±0.10 vs. 0.47±0.04 cm, respectively). Similarly, conception rate was also higher following Misoprostol treatment (60.0 vs. 28.6%, respectively) but no significant difference. Significantly higher (P<0.05) conception rate was found in ewes with high estrous signs intensity compared to medium (70.0 vs. 22.2%) and low intensity (70.0 vs. 20.0%), respectively. Conception rate was tended to be higher (58.3 vs. 37.5%) in low vaginal electrical resistance group (230-280 Ω) compared with the high group (281-330 Ω). Higher conception rate in Misoprostol-treated ewes indicates that the grater cervical penetrability during semen deposition ensures the success of TCAI with frozen semen. Estrus signs intensity and low vaginal electrical resistance could be used as a valuable indicator to select ewes for successful trans-cervical artificial insemination (TCAI) through obtaining higher conception rate.
Aisen E.G., Alvarez H.L., Venutrino A. and Garde J.J. (2000). Effect of trehalose and EDTA on cryoprotective action of ram semen diluents. Theriogenology. 53(5), 1053-1061.
Bartlewski P.M. and Candappa I.B.R. (2015). Assessing the usefulness of prostaglandin E2 (Cervidil) for transcervical artificial insemination in ewes. Theriogenology. 84, 1594-1602.
Buckrell B.C., Buschbeck C., Gartley C.J., Kroetsch T., McCutcheon W., Martin J., Penner W.K. and Walton J.S. (1994). Further development of a Trans-cervical technique for artificial insemination in sheep using previously frozen semen. Theriogenology. 42, 601-611.
Donovan A., Hanrahan J.P., Kummen E., Duffy P. and Boland M.P. (2004). Fertility in the ewe following cervical insemination with fresh or frozen–thawed semen at a natural or synchronised oestrus. Anim. Reprod. Sci. 84(3), 359-368.
Falchi L., Taema M., La Clanche S. and Scaramuzzi R.J. (2012). The pattern of cervical penetration and the effect of topical treatment with prostaglandin and/or FSH and oxytocin on the depth of cervical penetration in the ewe during the peri-ovulatory period. Theriogenology. 78, 376-384.
Fehring R.J. (1997). A comparison of the ovulation method with the CUE ovulation predictor in determining fertile period. J. Am. Assoc. Nurs. Pract. 8, 461-466.
Ferraz P.A., Loiola M.V., Rodrigues A.S., Lima M.C., Bittencourt T.C. and Ribeiro Filho A.D. (2017). The effect of the intensity of estrus expression on the follicular diameter and fertility of Nellore cows managed under a FTAI program. Ciên. Anim. Bras. 18, 1-9.
Fukui F., Kohno H., Okabe K., Katsuki S., Yoshizawa M., Togari T. and Watanabe H. (2010). Factors affecting the fertility of ewes after intrauterine insemination with frozen-thawed semen during non-breeding season. J. Reprod. Dev. 56(4), 460-466.
Garcia E., Hultgren J., Fällman P., Geust J., Algers B., Stilwell G., Gunnarsson S. and Rodriguez-Martinez H. (2011). Oestrous intensity is positively associated with reproductive outcome in high-producing dairy cows. Livest. Sci. 139(3), 191-195.
Gunduz M., Turna O., Cirit U., Ucmak M., Tek C., Sabuncu A. and Bacinoğlu S. (2010). Lambing rates and litter size following carazolol administration prior to insemination in Kivircik ewes. Anim. Reprod. Sci. 118(1), 32-36.
Islam S.S., Hasan M.S., Ghosh N., Islam M.S. and Islam M.M. (2021). Prospects and Problems of Indigenous Sheep Production in South Western Coastal Regions of Bangladesh. J. Agric. Sci. Sri Lanka. 16(1), 54-66.
Jha P.K., Alam M.G.S., Mansur M.A.A., Talukder M.R.I., Naher N., Rahman A.K.M.A., Hall D.C. and Bari F.Y. (2020). Effects of number of frozen-thawed ram sperm and number of inseminations on fertility in synchronized ewes under field. J. Anim. Reprod. Biotechnol. 35(2),190-197.
Khalifa R., Sayre B. and Lewis G. (1992). Exogenous oxytocin dilates the cervix in ewes. J. Anim. Sci. 70, 38-42.
Kozdrowski R., Twardoń J., Dejneka G.J. and Dzięcioł M. (2006). Influence of oestrus intensity and level of physical constitution on results of artificial insemination in cattle. MedWet. 62(9), 1038-1040.
Kumar D. and Naqvi S.M.K. (2014). Effect of time and depth of insemination on fertility of Bharat Merino sheep inseminated trans-cervical with frozen-thawed semen. Anim. Reprod. Sci. 56(3), 801-806.
Leethongdee S., Kershaw-Young C.M., Scaramuzzi R.J. and Khalid M. (2010). Intra-cervical application of Misoprostol at estrus alters the content of cervical hyaluronan and the mRNA ex pression of follicle stimulating hormone receptor (FSHR), luteinizing hormone receptor (LHR) and cyclooxygenase-2 in the ewe. Theriogenology. 73(9), 1257-1266.
Leethongdee S., Khalid M. and Bhatti A. (2007). The effects of prostaglandin analogue misoprostol and follicle-stimulating hormone on cervical penetration in ewes during the peri-ovulatory period. Theriogenology. 67, 767-777.
Li Y.T., Kuo T.C., Kuan L.C. and Chu Y.C. (2005). Cervical softening with vaginal Misoprostol before intrauterine device insertion. Int. J. Gynaecol. Obstet. 83, 67-68.
Mansur M.A.A., Alam M.G.S., Jha P.K., Rimon M.A., Naher N. and Bari F.Y. (2018). Intra-cervical artificial insemination conception rate using frozen semen at field level in indigenous sheep of Bangladesh. Asian J. Med. Biol. Res. 4(1), 55-62.
Masia F., Mayorga I., Mara L., Stelletta C., Chessa F., Casu S. and Dattena M. (2007). Monitoring oestrus in synchronized sarda ewes by vaginal mucus impedance assay: A preliminary study. Pp. 202-212 in Preoc. 23th Sci. Meet. European Embryo Trans. Assoc. Alghero, Italy.
Naher N., Juyena N.S., Jha P.K., Talukder M.R.I., Alam M.G.S. and Bari FY. (2016). Factors influencing the pregnancy rate in indigenous ewes following artificial insemination (AI) using frozen semen. Bangladesh Vet. 33(2), 33-38.
Ortman R. (2000). Monitoring of estrus cycle of ewes by ram-seeking behavior. Small Rumin. Res. 37, 73-84.
Owiny J., Fitzpatrick R. and Spiller D. (1992). Changes in the extensibility of the ovine cervix uteri following infusion of estradiol-17β at term. Small Rumin. Res. 7, 75-83.
Perry G.A., Smith M.F., Lucy M.C., Green J.A., Parks T.E., Macneil M.D., Andrew J.R. and Thomas W.G. (2005). Relationship between follicle size at insemination and pregnancy success. Natl. Acad. Sci. USA. 14, 5268-5273.
Rashidi M. and Cedden F. (2013). Trans-cervical artificial insemination in ewes during out of breeding season. Maced. J. Anim. Sci. 3(2), 143-146.
Rekha A., Zahora B.F., Bari F.Y. and Alam M.G.S. (2016). Comparison of commercial Triladyl extender with a tris-fructose-egg-yolk extender on the quality of frozen semen and pregnancy rate after transcervical AI in Bangladeshi indigenous sheep (Ovis aries). Small Rumin. Res. 134, 39-43.
Salamon S. and Maxwell W.M.C. (1995). Frozen storage of ram semen and processing, freezing, thawing and fertility after cervical insemination. Anim. Reprod. Sci. 37, 185-249.
Sayre B. and Lewis G. (1997). Fertility and ovum fertilization rate after laparoscopic or transcervical intrauterine artificial insemination of oxytocin-treated ewes. Theriogenology. 48, 267-275.
SPSS Inc. (2011). Statistical Package for Social Sciences Study. SPSS for Windows, Version 20. Chicago SPSS Inc., USA.
Theodosiadou E. and Tsiligianni T. (2015). Determination of the proper time for mating after oestrous synchronisation during anoestrous or oestrous by measuring electrical resistance of cervical mucus in ewes. Vet. Med. 60(2), 87-93.
Theodosiadou E., Amiridis G.S. and Tsiligianni T.H. (2014). Relationship between electrical resistance of cervical mucus and ovarian steroid concentration at the time of artificial insemination in ewes. Reprod. Biol. 14, 234-237.
Ustuner H., Ustuner B., Toker M.B., Alcay S., Demir K., Sagirkaya H. and Nur Z. (2018). Administration time of misoprostol affects fertility rate in artificially inseminated Kivircik ewes with frozen-thawed ram semen. Anim. Reprod. 15(2), 156-160.
Yamauchi S., Nakamura S., Yoshimoto T., Nakada T., Ashizawa K. and Tatemoto H. (2009). Prediction of estrous cycle and optimal insemination time by monitoring vaginal electrical resistance (VER) in order to improve the reproductive efficiency of the Okinawan native Agu pig. Anim. Reprod. Sci. 113, 311-316.
