Open pulled straws for vitrification of mature mouse oocytes preserve patterns of meiotic spindles and chromosomes better than conventional straws

Microsuction of blastocoelic fluid before vitrification increased survival and pregnancy of mouse expanded blastocysts, but pretreatment with the cytoskeletal stabilizer did not increase blastocyst survival

OBJECTIVE

To ascertain effects of thermal change, size of blastocoele, artificial shrinkage, and cytoskeletal stabilizer on survival of blastocysts from vitrification.

DESIGN

In vitro and in vivo study.

SETTING

University infertility clinic and academic research laboratory.

ANIMAL(S)

Female mice of outbred ICR strain, aged 6 to 8 weeks.

INTERVENTION(S)

In experiment 1, various stages of mouse blastocysts were vitrified by using conventional straws or closed pulled straws (CPS). In experiment 2, microsuction was performed of blastocoelic fluid for blastocysts and expanded blastocysts before vitrification. In experiment 3, cytochalasin B (CCB) was used to treat embryos during vitrification. In experiment 4, vitrified expanded blastocysts were transferred to pseudopregnant mice.

MAIN OUTCOME MEASURE(S)

Survival and pregnancy.

RESULT(S)

The survival rates of early blastocysts were high and not different between the conventional straws and the CPS. The survival rates decreased for blastocysts and expanded blastocysts in both of the two methods. But the use of CPS achieved higher survival rates for blastocysts (83% vs. 70%) and expanded blastocysts (60% vs. 39%) than did the conventional straws. Microsuction before vitrification increased the survival rates for blastocysts (92% vs. 80%) and expanded blastocysts (89% vs. 59%). Survival of vitrified embryos was not distinct between CCB treatment and non-CCB treatment. The percentage of live young from vitrified expanded blastocysts using microsuction was greater than that from vitrified expanded blastocysts without microsuction (34% vs. 9%).

CONCLUSION(S)

The size of the blastocoeles influenced survival of blastocysts from vitrification. A rapid thermal change of CPS and effective reduction of blastocoelic fluid by microsuction may facilitate vitrification and reduce ice crystal damage for blastocysts and expanded blastocysts. The microfilament inhibitor of CCB treatment did not increase their survival rates.

Are programmable freezers still needed in the embryo laboratory? Review on vitrification

The predictable answer to the provocative question of whether programmable freezers are still needed in the embryo laboratory is an even more provocative 'no'. However, such a radical statement needs strong support. Based on the extensive literature of the past 5 years, the authors collected arguments either supporting or contradicting their opinion. After an overview of the causes of cryoinjuries and strategies to eliminate them, the evolution of vitrification methods is discussed. Special attention is paid to the biosafety issues. The authors did not find any circumstance in oocyte or embryo cryopreservation where slow freezing offers considerable advantages compared with vitrification. In contrast, the overwhelming majority of published data prove that the latest vitrification methods are more efficient and reliable than any version of slow freezing. Application of the proper vitrification methods increases the efficiency of long-term storage of stem cells and opens new perspectives in cryopreservation of oocytes, both for IVF and somatic cell nuclear transfer. However, lack of support from regulatory authorities, and conservative approachs regarding novel techniques can slow down the implementation of vitrification. The opinion of the authors is that vitrification is the future of cryopreservation. The public have the final say in whether they want and allow this future to arrive.

Successful pregnancy following blastocyst cryopreservation using super-cooling ultra-rapid vitrification

BACKGROUND

Blastocysts were cryopreserved by a new two-step ultra-rapid cooling in super-cooled liquid nitrogen (-205 degrees C).

METHODS

There were 308 mouse blastocysts collected from fertile B6CBF1 mice and 249 human blastocysts collected from 51 couples treated with IVF. The blastocysts were super-cooled by a Vit-Master and cryoloops after treatment in 50 and 100% vitrification solution (VS) for 2 min and 30 s, respectively. The 100% VS was composed of 20% ethylene glycol, 20% dimethylsulphoxide and 0.5 mol/l sucrose in human tubular fluid medium with 20% human serum albumin. The embryos were warmed after treatment in 0.25 and 0.125 mol/l sucrose for 2 and 3 min, respectively. The survival of embryos was observed after re-swell.

RESULTS

The survival rate (SR) and hatching rate (HR) of mouse blastocysts in the super-cooled, the cryosolution-treated and control groups were not significantly different (SR, 87, 95.5 and 100%; HR, 50, 33 and 44.6%, respectively; P>0.05). After 96 super-cooled human blastocysts were warmed, 60 survival blastocysts were transferred into 13 patients. The successful SR and pregnancy rate (PR) for the super-cooled blastocyst group were 77.1% (74 out of 96) and 53.8% (seven out of 13).

CONCLUSION

The ultra-rapid vitrification of blastocysts with a successful SR and PR could be used to replace classical slow cooling.

Fundamentals of cryobiology in reproductive medicine

The aim of this review will be to provide a basic understanding of the biophysical processes that accompany the application of cryopreservation in reproductive medicine. The ability to store cells in 'suspended animation' outside the body has become a keystone practice in the development of many modern clinical therapies, and, in fact, the sciences of cryobiology and IVF have developed in parallel over the past 50 years. During this time, some of the underlying principles of the quantitative biophysical aspects of cryobiology have been clarified. Water is the universal biocompatible solvent, but also possesses unique properties for stability of living cells. Whilst low temperatures themselves have defined effects on cell structure and function, it is the phase transition of water to ice that is the most profound challenge for survival. The thermodynamics of dilute aqueous solutions dictate how cells and tissues respond to the freezing process. Current concepts of nucleation, ice crystal growth and solute exclusion from the ice lattice will be discussed to illustrate what cells must negotiate to avoid lethal damage, and the role of cryoprotectants in enhancing recovery. Quantitative formalisms now exist to model and predict how water and solutes move across cell membranes before and during freezing, or how nucleation events will proceed, and these will be outlined. Cryoprotectants have both positive and negative effects on cell function depending on the kinetics of exposure. The concept of tolerable osmotic excursion of cell volume will be discussed, along with the evidence for a 'pseudo-glassy' state for cells during traditional cryopreservation. This will be compared with the recent interest in promoting glassy states in the whole sample using vitrification protocols, outlining the advantages and drawbacks of each approach. Additional methods for controlling ice nucleation have a role to play here, and a brief outline of current technologies will be given. Finally, issues of safety and stability of cryopreserved samples will be set out.

Effects of cryopreservation on meiotic spindles of oocytes and its dynamics after thawing: clinical implications in oocyte freezing--a review article

Embryo freezing has been a successful practice, but oocyte cryopreservation formerly achieved poorer results. This was mainly due to low rates of survival, fertilization, and development. The major dissimilarities for oocytes to embryos are the character of the plasma membrane, the presence of cortical granules, at the metaphase of meiosis II with the spindle system. In addition, the oocytes must be fertilized by sperm at the appropriate time. To improve the survival rate, a refined slow freezing method with increased sucrose concentration would dehydrate oocytes more sufficiently. Vitrification is another approach to prevent ice crystal formation. Intracytoplasmic sperm injection is used to overcome possible zona hardening from the release of cortical granules. The microtubules of meiotic spindles are vulnerable to the thermal changes and would depolymerize. Cryopreserved oocytes exhibited serious disturbances of the microtubules immediately after thawing. Fertilization of oocytes with disorganized spindles could lead to chromosomal aneuploidy, digyny, and arrest of cleavage. After incubation, the microtubules would repolymerize in a time-dependent way. Normal fertilization and development of cryopreserved oocytes improved after appropriate incubation and timing of insemination, compatible with recovery of the spindles. With the improvement of survival, fertilization, and cleavage, oocyte cryopreservation would gain an imperative role.

Recent developments in human oocyte, embryo and blastocyst vitrification: where are we now?

The target of any cryopreservation procedure should be to ensure high survival rates of living cells after thawing. Two important parameters determine the success of any cryopreservation protocol: the manner in which cells regain equilibrium in response to cooling, and the speed of freezing (cooling rate). Slow-rate freezing protocols result in the formation of ice crystals during cooling and warming. Vitrification, in which high cooling rates in combination with a high concentration of cryoprotectant are used, does not produce any ice crystals during cooling and warming. However, there is a practical limit to the attainable cooling speed, and also a biological limit to the concentration of cryoprotectant tolerated by the cells during vitrification. Although post-warming survival depends on the species, the developmental stage and the quality of the embryos being vitrified, it seems clear that vitrification methods are increasingly successful and might be a better method than slow cooling procedures in the field of cryobiology. Many of the potential problems and benefits underlying vitrification as a method of choice for embryo cryopreservation in clinical embryology will be discussed in this review.

Potential importance of vitrification in reproductive medicine

As early as 1985, ice-free cryopreservation of mouse embryos at -196 degrees C by vitrification was reported in an attempted alternative approach to cryostorage. Since then, vitrification techniques have entered more and more the mainstream of animal reproduction as an alternative cryopreservation method to traditional slow-cooling/rapid-thaw protocols. In addition, the last few years have seen a significant resurgence of interest in the potential benefits of vitrification protocols and techniques in human-assisted reproductive technologies. The radical strategy of vitrification results in the total elimination of ice crystal formation, both within the cells being vitrified (intracellular) and in the surrounding solution (extracellular). The protocols for vitrification are very simple. They allow cells and tissue to be placed directly into the cryoprotectant and then plunged directly into liquid nitrogen. To date, however, vitrification as a cryopreservation method has had very little practical impact on human-assisted reproduction, and human preimplantation embryo vitrification is still considered to be largely experimental. Besides the inconsistent survival rates that have been reported, another problem is the wide variety of different carriers and vessels that have been used for vitrification. Second, many different vitrification solutions have been formulated, which has not helped to focus efforts on perfecting a single approach. On the other hand, the reports of successfully completed pregnancies following vitrification at all preimplantation stages is encouraging for further research and clinical implementation. Clearly, however, attention needs to be paid to the inconsistent survival rates following vitrification.

Advances in the cryopreservation of mammalian oocytes and embryos: Development of ultrarapid vitrification

The cryopreservation of embryos has become a powerful tool in assisted reproduction in several mammalian species. Embryos are cryopreserved by slow freezing or by vitrification. However, consistently high survival has not been obtained in most oocytes and in some embryos. The main reasons for the low survival would be sensitivity to low temperatures, which leads to chilling injury, and low permeability of the cell membrane, which leads to the formation of intracellular ice. As a strategy aiming to overcome these injuries, modified vitrification methods have been devised in which the cooling and warming rate is markedly increased by minimizing the volume of the solution and the container. The modified methods use electron microscope grids, open-pulled straws, cryoloops, or container-less microdrops. In this article, recent developments in the ultrarapid vitrification of mammalian oocytes and embryos are reviewed based on the understanding of the mechanisms of cell injury in cryopreservation. (Reprod Med Biol 2002; 1: 1-9).

Blastocyst development after vitrification of multipronuclear zygotes using the Flexipet denuding pipette

The purpose of this study was to demonstrate the safety and efficacy of vitrification of human pronuclear stage (PN) embryos in the human assisted reproduction laboratory. Using single pronucleate (1PN) and three pronucleate (3PN) zygotes, the impact of vitrification in the Flexipet denuding pipette (FDP) as a carrier was assessed in terms of survival, embryonic development and blastocyst formation when compared according to the PN number, and unvitrified controls. A total of 65 1PN and 152 3PN zygotes were vitrified; after warming 82% (53/65) of 1PN and 90% (137/152) of 3PN survived. The overall percentage of warmed zygotes (1PN and 3PN) that cleaved and reached 2-cell stage did not differ (chi(2); P = 0.32) from the control groups (77%; 147/190 versus 85%; 115/136). In addition, when the cleavage behaviour was examined on day 3 for >or=4-cell stage, no significant differences (chi(2); P = 0.95) were observed between the vitrified group and the unvitrified control groups (74%; 109/147 versus 77%; 89/115). Comparing the developmental potential up to cavitation and blastocyst formation on day 5, the overall outcome of the vitrified PN was 31% compared with 33% for the controls (chi(2); P = 0.76). The simple vitrification protocol used in this study, and these data highlight the usefulness of vitrification using FDP as a consistent and effective cryopreservation method for pronuclear zygotes, and a suitable alternative to slow cryopreservation protocols.

Vitrification of mouse oocytes using closed pulled straws (CPS) achieves a high survival and preserves good patterns of meiotic spindles, compared with conventional straws, open pulled straws (OPS) and grids

BACKGROUND

We modified the loading of pulled straws into a new closed system, called closed pulled straws (CPS) for holding oocytes for vitrification. The morphological survival, dynamics of meiotic spindles, and fertilization in vitro of vitrified oocytes using CPS were compared with conventional straws, open pulled straws (OPS), and grids.

METHODS

Surviving oocytes were stained for spindles and chromosomes after 1, 2 and 3 h incubations, and compared with controls. The capacity of fertilization and embryonic cleavage were examined in vitro.

RESULTS

The survival rates of the CPS (79%) and straw (77%) groups were significantly higher (P < 0.05) than the OPS (63%) and grid (39%) groups. At a 1h incubation, vitrified oocytes of four groups had significantly fewer normal spindles than controls (P < 0.05). The straw group was inferior to the others in spindle morphology (P < 0.05). After a 3 h incubation, recovery of vitrified oocytes with normal spindles was significantly improved in all groups (P < 0.05). The percentages of fertilization and blastocyst formation of vitrified oocytes after a 1 h incubation was significantly lower than controls (P < 0.05), but they were improved after 2 or 3 h incubations (P < 0.05).

CONCLUSIONS

Oocytes vitrified using CPS, OPS or grids could lessen spindle injuries and expedite recuperation. The survival using OPS or grids is lower. Sufficient culture time for recovery of meiotic spindle would be imperative for fertilization events of vitrified oocytes. CPS has the advantages of achieving a high survival and preserving good spindles.

Effective cryopreservation of human embryonic stem cells by the open pulled straw vitrification method

BACKGROUND

Human embryonic stem (ES) cells originate from the inner cell mass of the blastocyst, and retain in culture the properties of pluripotent cells of the early embryo. The study aim was to determine whether the open pulled straw (OPS) vitrification method, which is highly effective for the cryopreservation of embryos, might be also efficient for human ES cells.

METHODS AND RESULTS

All human ES cell clumps that were vitrified by the OPS method could be recovered upon thawing, and gave rise to ES cell colonies after plating. Vitrified colonies were significantly smaller and showed an increased level of background differentiation compared with control colonies. However, these unwanted effects could be overcome by additional cultivation of the colonies for 1 and 2 days respectively. The vitrified human ES cells were cultivated for prolonged periods and retained the properties of pluripotent cells, including a normal karyotype, expression of the transcription factor Oct-4 and surface markers that are characteristic to human ES cells. When grafted into SCID mice, the vitrified cells gave rise to teratomas containing derivatives of all three embryonic germ layers.

CONCLUSIONS

Vitrification by the OPS method is reliable and effective for the cryopreservation of human pluripotent embryonic stem cells.