Abstract
The aim of this study was to evaluate the fertilization rate of cows that were superovulated and artificially inseminated with sex-sorted semen. Cows were treated with an intravaginal progesterone device plus estradiol benzoate (day 0). Superstimulation treatments began four days after with eight applications of FSH at 12 h intervals. D-Cloprostenol was administered on day 6. Progesterone device was removed on day 7, and LH was administered on day 8. The treatments were divided as follows: NonSx, two AI with non-sorted semen were conducted 12 and 24 h after LH; Sx12&24, two AI with sex-sorted semen were conducted 12 and 24 h after LH; and Sx24&36, two AI with sex-sorted semen were conducted 24 and 36 h after LH. Embryos were recovered on day 16 and were evaluated and classified. Percentage of fertilized embryos tended to be greater for the non-sorted semen than the sex-sorted semen. The number of unfertilized oocytes was smaller when the non-sorted semen was used relative to the sex-sorted semen. There was no difference between the treatments that used sexed semen. In conclusion, the use of sex-sorted semen in superovulated dairy cows results in greater numbers of unfertilized oocytes than non-sorted. However, when only sorted semen is used AI should be performed 24 and 36 h after LH.
Highlights
Sperm that is separated according to the sex chromosomes (X or Y) can prevent sex-linked genetic diseases, save endangered animals and increase productive efficiency (Seidel and Johnson, 1999)
The use of sex-sorted semen in embryo production by SOV is an important tool for genetic improvement in dairy farms, increasing milk production
This research evaluated the use of sexed semen in the in vivo embryo production during modifications at the time of artificial insemination
Summary
Sperm that is separated according to the sex chromosomes (X or Y) can prevent sex-linked genetic diseases, save endangered animals and increase productive efficiency (Seidel and Johnson, 1999). Despite considerable advances in the sexsorted semen process, the fertilization rates are not the same as those obtained from non-sorted semen (Garner, 2006; Seidel and Schenk, 2008; Karakaya et al, 2014). The use of timed AI (TAI) requires hormonal treatments that ensure adequate control of follicular development and luteolysis for ovulation synchronization. These aspects have been controlled in superovulation (SOV) protocols in which the use of GnRH or LH for ovulation induction has been widely used (Nogueira et al, 2002; Chesta et al, 2005; Bo and Mapletoft, 2014), reducing the interval between the first and last ovulations (Chesta et al, 2005). Seventy-five percent of the ovulation in superovulated Bos taurus cows occurred between 24 and 36 h after administration of 25 mg of LH (Martins, 2007)
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