The objective of this study was to establish an efficient system of producing early monozygotic twin bovine embryos in vitro using the blastomere separation and coculture technique. In this study, early eight-cell embryos were chosen to optimize the separation method, and multi-coculture tactics were applied to improve the efficiency of this production system. Bovine embryo blastomeres (groups of at least 30 at the eight-cell stage) were separated into eight segments (to regard an eight-cell embryo as a tangerine, a blastomere as one segment) and one, two and four segments (blastomeres) were cultured respectively in microwells on the bottom of the four-well dish (Nunc, Denmark) with 400 μL of culture medium under paraffin oil. Four different types of coculture tactics (cocultured with nothing, intact embryos, bovine cumulus cells (bCCs), intact embryos & bCCs) were applied to the group of four segments (blastomeres). Finally, diameter and inner cell mass (ICM):trophectoderm (TE) cell ratio was measured as a criterion to assess the quality of the twin embryos which were derived from bovine separated blastomeres. Our results showed that rate of blastocyst formation of the four segments group was significantly greater than one or two group (P<0.05). In addition, rate of blastocyst formation was significantly increased when the four segments were cocultured with intact embryo & bCCs (P<0.05). Although the ICM, TE and total cells of blastocysts derived from separated blastomeres was less than the control group from intact embryo (P<0.05), more important quality indicator of the blastocyst diameter and ICM:TE cell ratio was similar between our experimental group and the control group (P>0.05). Thus, these results suggest that combined with intact embryos & bCCs coculture system, culturing four isolated segments (blastomeres) per microwell is an efficient system of producing early monozygotic twin bovine embryos. Furthermore, our results also indicate that the quality of blastocysts derived from separated blastomere may be similar to those derived from intact eight-cell embryos.

To our knowledge, no single study has systemically compared cryopreservation efficiencies of bovine blastocysts derived from in vitro fertilization (IVF), intracytoplasmic sperm injection (ICSI) and somatic cell nuclear transfer (SCNT) by controlled freezing and vitrification. This experiment, therefore, was designed to compare the cryopreservation of these blastocysts with controlled freezing and OPS vitrification. Adenosine-5´-triphosphate (ATP) content and reactive oxygen species (ROS) level in blastocysts were also analyzed. Firstly, for each type of blastocyst (IVF, ICSI or SCNT), significant differences were observed between the survival rates of the controlled freezing ((81.56±2.33), (68.18±4.72) or (47.89±5.83)%) and OPS vitrification groups ((92.24±4.54), (82.40±3.76) or (78.71±5.91)%; P<0.05). Secondly, for each type of blastocyst (IVF, ICSI or SCNT), ATP content was significantly decreased after controlled freezing or vitrification, and the ATP content in the controlled freezing group (0.43±0.06), (0.35±0.05) or (0.21±0.02) pmol) was significantly lower than that found in the OPS vitrification group (0.62±0.04), (0.46±0.03) or (0.30±0.01) pmol; P<0.05). Thirdly, ROS level in fresh IVF ((47.33±3.56) c.p.s (counted photons per second), ICSI ((36.51±2.58) c.p.s) or SCNT blastocysts ((26.44±1.49) c.p.s) was significantly lower than that found in the OPS vitrification group ((72.14±4.31), (58.89±3.89) or (40.11±5.73) c.p.s; P<0.05), but higher than that of the controlled freezing group (34.41±3.32), (23.13±1.26) or (15.46±2.45) c.p.s; P<0.05). The present study indicated that vitrification is more efficient in the cryopreservation of bovine blastocysts derived from IVF, ICSI or SCNT than controlled freezing. Furthermore, both vitrification and controlled freezing significantly altered the ATP content and ROS level in those blastocysts.