45 EFFECT OF VITRIFICATION ON KIDDING OF CAPRINE EMBRYOS
M. M. Toishibekov A , H. Blackburn A B , G. A. Valieva A , S. M. Askarov A and B. B. Molzhigitov AA Institute of Experimental Biology, Almaty, Republic of Kazakhstan, Almaty, Republic of Kazakhstan;
B National Center for Genetic Resource Preservation, ARS, USDA, Fort Collins, CO, USA
Reproduction, Fertility and Development 26(1) 136-137 https://doi.org/10.1071/RDv26n1Ab45
Published: 2 January 2014
Abstract
This work evaluated different methods: vitrification (V) and super-cooling ultra-rapid vitrification (SCURV). The goat morulae were cryopreserved into the High Security Vitrification (HSV) Kit (Cryo Bio System, Paris, France). The vitrification method was applied according to the method described by Vajta et al. (1998). Both treatments used a vitrification solution [VS; 20% (3.6 mol L–1) ethylene glycol (EG), 20% (2.4 mol L–1) dimethyl sulfoxide (Me2SO), and 0.5 mol L–1 of sucrose in Dulbecco's PBS (DPBS) with 10% BSA in both methods]. In our experiment, we used the Vit-Master™ apparatus (MTG GmbH, Bruckberg, Germany). The supercooled LN facilitates heat transmission between LN and the cryosolution interface and this is efficient for bovine semen and blastocyst cryoconservation (Arav et al. 2002). By surgical flushing of 30 superstimulated (1200 IU of Folligon, Intervet International, Boxmeer, the Netherlands) goats, 137 transferable morulae were harvested; 41 morulae were transferred fresh to synchronized recipients (control) and the others were cryopreserved by V (n = 47) or SCURV (n = 49), respectively thawed or warmed, and transferred to recipients. Embryos were vitrified using the HSV Kit. They were first incubated in 50% VS for 2 min and then transferred for 30 s into 100% VS. Each embryo was loaded by HSV Kit, which was immediately submerged into and stored in LN. Warming was done by placing the narrow end of the straw into DPBS + 0.25 M sucrose for 5 min. Embryos were then transferred into DPBS + 0.125 M sucrose for 3 min and finally to DPBS until transfer. The SCURV morulae were then exposed to 50 and 100% VS at 37°C for 2 min and 30 s, respectively. Embryos after saturation in VS were transferred by HSV Kit and using negative pressure of LN in the chamber for freezing with the VIT-Master. Thawing vitrified embryos was accomplished by placing the vitrified embryos in solutions of sucrose 0.25 and 0.125 M, with exposures of 2 and 3 min, accordingly. After thawing embryos, only good-quality embryos were transferred. The kidding rate following transfer of fresh, frozen-thawed vitrification, and SCURV methods were 25, 17, and 19 kids, respectively. No statistical difference was found for the percentage of does kidding following transfer of thawed embryos after vitrification (36.2 ± 4.4%a) and SCURV methods (38.7 ± 6.5%b). The survival rate following transfer of fresh embryos (60.9 ± 5.3c) was higher and in line with previous findings using VS. Differences were statistically significant (ac, bc: P < 0.05). Importantly, our data suggest that the SCURV method can be used for cryopreservation of goat morulae as the vitrification method. Although further work on the developmental competence of embryos cryopreserved with the SCURV method are needed, these data suggest that with SCURV, a faster freeze rate and lower level of cryoprotectants is able to minimize ice crystal formation and should be further evaluated as a routine mechanism for cryopreserving goat embryos.
