This study was performed to evaluate whether vitrification method using ethyle glycol and eletron microscopic (EM) grid could be used far the cryopreservation of human oocytes in ART program. Surplus oocytes were obtained from consented IVF patients. These surplus human oocytes were frozen with our vitrification method, Oocytes were exposed to 1.5M ethylene glycol (EG) in DPBS far 2,5 minutes, followed by 5.5M EG plus 1.0M Sucrose in DPBS for 20 seconds. Then oocytes were transferred onto the EM grid and the grid was plunged into LN2 for storage. For thawing, oocytes containing EM grid were sequentially transferred in 1.0M, 0.5M, 0.25M, 0.125M and 0 M sucrose in DPBS solution at the intervals of 2.5 minutes. Thawed and survived oocytes were provided for ICSI. Embryos from vitrified oocytes were transferred to uterus of the patient on 4 to 5 days after ovulation in natural cycles of on 15 to 17 day of hormone replacement cycles. A total of 370 oocytes from 26 patients were thawed and 159 (43.0%) of them survived. One hundred thirty four oocytes (84.3%) were fertilized normally and 126 pre-embryos were transferred to 26 patients, resulting in 5 clinical pregnancies. The pregnancy rate per transfer was 19.2% and implantation rate was 4.0%. Among the five pregnant, 4 patients delivered 4 healthy babies and the one patient was 32-week ongoing pregnancy. From this results, vitrification using ethylene glycol as cryoprotectant and EM grid is a rapid and simple method that can be effectively applied for the cryopreservation of human oocytes in ART program.

Selection of oocyte cryopreservation method is a prerequisite factor for developing an effective bank system. Compared with slow freezing method, the vitrification has various advantages such as avoiding intracellular ice crustal formation. In our previous, we attempted to employ a vitrification method using ethylene glycol and an electron microscope grid for cryopreservation of mouse oocytes. However, A high incidence of spindle and chromosome abnormalities was detected in thawed oocytes after vitrification. We examined whether the addition of a cystoskeleton stabilizer Taxol , to the vitrification solution could promote the post-thawed survival and subsequent development of stored oocytes. More oocytes developed to the 4-cell (44.7% vs. 69.7%), 8-cell (31.8% vs. 64.2%), morula (24.7% vs. 54.3%), and blastocyst (20.3% vs. 49.2%) stages after the addition of Taxol to the cryoprotectant than after no addition. 21 and 26 mouse pups were born after transfer of blastocyst derived from oocytes vitrified without and with Taxol. The addition of Taxol to vitrification solution greatly promoted post-thaw preimplantation development of ICR morose oocytes.tes.

To develop an effective vitrification method, we examined the use of a conventional straw as vessel fur vitrification of mouse oocytes, and to compare the post-thaw survival and chromosome configuration of these oocytes with those vitrified in grids. Intact cumulus-enclosed oocytes were vitrified with DPBS with 5.5 M ethylene glycol and 1.0 M sucrose, and loaded into straws and onto eletron microscopic copper grid fur storing in liquid nitrogen. Intact vitrified and thawed oocytes were karyotying for chromosome. The rates of post-thawed survival were 88.5% in vitrified oocytes with straws, and 83% in vitrified ooctyes with grids. Vitrified and thawed oocytes with straws and grids were increased chromosomal abnormality (31.4% and 30.9%) compared with fresh oocytes (17.8%). The conventional straws can be used as vessel for vitrification to prevent of inflection in liquid nitrogen.