Bovine oocyte vitrification using the Cryotop method: Effect of cumulus cells and vitrification protocol on survival and subsequent development

The ability to successfully cryopreserve mammalian oocytes has numerous practical, economical and ethical benefits, which may positively impact animal breeding programs and assisted conception in humans. However, oocyte survival and development following vitrification remains poor. The aim of the present study was (1) to evaluate the effect of the presence of cumulus cells on the outcome of vitrification of immature (GV) or mature (MII) bovine oocytes, (2) to compare empirical and theoretical vitrification protocols, and (3) to assess the effect of adding ice blockers to vitrification media on survival and development competence of bovine oocytes following vitrification using the Cryotop method. In Experiment 1, cumulus-enclosed and partially-denuded GV and MII oocytes were vitrified in 15% EG + 15% Me₂SO + 0.5 M sucrose in two steps. In Experiment 2, GV oocytes were vitrified either as above or using theoretical modeling based on permeability and osmotic tolerance characteristics in 30% EG + 11.4% trehalose in three steps or 40% EG + 11.4% trehalose in four steps. In Experiment 3, GV oocytes were vitrified in media supplemented or not with 1 of 2 ice blockers (21st Century Medicine, Fontana, CA) 1% X-1000, 1% Z-1000 or both in three steps. In Experiment 1, the survival, cleavage and blastocyst rate of cumulus-enclosed oocytes was significantly higher than those of partially-denuded oocytes when vitrified at the GV stage (93.8% vs. 81.3%, 65.8% vs. 47.3%, 11.3% vs. 4.0%, respectively, P < 0.05). However, no significant effect of cumulus cover was detected between the two groups when vitrified at MII (93.0% vs. 91.8%, 35.2% vs. 36.8%, 5.0% vs. 4.4%, respectively). Furthermore, cumulus-enclosed oocytes vitrified at the GV stage exhibited significantly higher developmental competence than those vitrified at the MII stage (P < 0.05). In Experiment 2, there were no significant differences in the survival, cleavage and blastocyst rate among three protocols (86.0% vs. 92.8% vs. 91.2%, 44.8% vs. 54.4% vs. 45.6%, 5.0% vs. 5.4% vs. 4.0%, respectively). However, cleavage and blastocyst rate were significantly lower (P < 0.05) than non-vitrified control oocytes. In Experiment 3, the presence of ice blockers did not alter the cleavage rate or blastocyst development (P > 0.05). In conclusion, cumulus-enclosed GV bovine oocytes survived vitrification and subsequently developed at higher rates than MII oocytes using Cryotop method and conventional IVF procedure. Theoretical analysis of permeability characteristics and tolerance limits could not explain the low developmental competence of vitrified oocytes.     

Cryopreservation of periodontal ligament cells with magnetic field for tooth banking

The purpose of this study was to establish a long-term tooth cryopreservation method that can be used for tooth autotransplantation. Human periodontal ligament (PDL) cells were frozen in 10% dimethyl sulfoxide (Me₂SO) using a programmed freezer with a magnetic field. Cells were cryopreserved for 7 days at −150 °C. Immediately after thawing, the number of surviving cells was counted and the cells were cultured; cultured cells were examined after 48 h. Results indicated that a 0.01 mT of a magnetic field, a 15-min hold-time, and a plunging temperature of −30 °C led to the greatest survival rate of PDL cells. Based on these findings, whole teeth were cryopreserved under the same conditions for 1 year. The organ culture revealed that the PDL cells of cryopreserved tooth with a magnetic field could proliferate as much as a fresh tooth, although the cells did not appear in the cryopreserved tooth without a magnetic field. Histological examination and the transmission electron microscopic image of cryopreserved tooth with a magnetic field did not show any destruction of cryopreserved cells. In contrast, severe cell damage was seen in cells frozen without a magnetic field. These results indicated that a magnetic field programmed freezer is available for tooth cryopreservation.     

Human Semen Refrigeration at + 4 °C: Bio-kinetic Characteristics

The aim of our study was to evaluate the bio-kinetic characteristics of human semen refrigerated for different periods and to compare the effects of refrigeration at +4 °C against cryopreservation of human sperm at −196 °C. Semen was obtained from 30 male partners of infertile couples (infertile subjects) with the following semen profile: sperm count ≥10 × 10⁶/ml; progressive motility ≥20%; atypical forms <70% and white blood cells <1.0 × 10⁶/ml. Fifteen normospermic subjects were also selected as controls (control subjects). The following tests were carried out on basal, refrigerated and cryopreserved sperm: a) sperm kinetic properties (by Superimposed Image Analysis System); b) the Hypoosmotic Viability Test (HVT) (combined Hypoosmotic Swelling and Viability Test). The results of the study showed that the percentage recovery of kinetic properties and of HVT were optimum for up to 48 h. After refrigeration for 72 h, a drastic decrease in straight motility recovery was observed. No significant differences were observed between cryopreservation and refrigeration at +4 °C for 48 h for motility or HVT recoveries in samples from control subjects. However, in infertile subjects, a significant decrease in straight progressive motility and HVT recoveries was observed in cryopreserved samples compared to those refrigerated for 48 h. Neither refrigeration nor cryopreservation led to the growth of pathogenic bacteria in any of the cases studied. Based on the above results, refrigeration could represent a useful alternative to the cryopreservation method.     

Sperm Cryopreservation in Male Infertility Due to Genetic Disorders

Certain chromosomal and genetic anomalies, such as Klinefelter syndrome (47,XXY) and Y chromosome microdeletions, have been reported as potential causes of a progressive impairment of spermatogenesis. In these cases cryoconservation of ejaculated or testicular sperm represent a valuable tool for the preservation of fertility. However, dealing with genetic disorders, the transmission of genetic anomalies has to be taken into consideration. It is therefore important to be aware about the clinical importance and the related genetic risks of these anomalies. In this article we describe the clinical significance of these diseases.     

Fixation methods can produce misleading artifacts in sperm cell ultrastructure of diploid and tetraploid Pacific oysters, Crassostrea gigas

Spermatozoa from diploid and tetraploid Pacific oysters (Crassostrea gigas) were examined after anisotonic fixation. Morphological anomalies, such as membrane rupture, detached tails, and the formation of tail vesicles (typically associated with damage attributable to procedures such as cryopreservation) were observed; the Mantel-Haenszel Chi-square test indicated a strong association between the anomalies and fixative osmolality (P<0.001). The present study also indicated that media in a range of 800 to 1,086 mOsm/kg could be assumed to be functionally isotonic to Pacific oysters, and osmolalities below or above this caused severe cell damage. For example, the maximum volume of flagella obtained after hypotonic fixation was approximately twice the volume of the flagella in isotonic fixation. Sperm cell flagellar volumes after hypertonic fixation (1,110 mOsm/kg) were 32% smaller than those in isotonic fixation, and sperm heads were 25% smaller. Although the damage associated with anisotonic fixation was evident in all parts of the sperm cells, the most vulnerable locations were the plasma membrane and flagellum motor apparatus. The formation of tail vesicles after hypotonic fixation was also examined. Because of water uptake, oyster sperm became swollen in hypotonic fixative, and bending or coiling of the axoneme within the tail vesicles led to the appearance of multiple axonemal structures in cross sections when observed by transmission electron microscopy. This phenomenon might be generally misinterpreted as the presence of double tails. This and other fixation artifacts can lead to the misinterpretation of damage caused by cryopreservation in ultrastructure studies of sperm of aquatic species, especially those in marine species.This work was supported in part by funding from the USDA-SBIR program, 4Cs Breeding Technologies, and the Louisiana Sea Grant College Program.     

Development of a single mode electromagnetic resonant cavity for rewarming of cryopreserved biomaterials

An electromagnetic (EM) heating system is developed to achieve the rapid and uniform warming of cryopreserved biomaterials. Using the heating system, a rectangular resonant cavity is excited in TE101 mode at frequencies near 434 MHz. In experiments, a spherical phantom of biomaterial with a diameter of 36 mm is placed at the center of the cavity. The phantom is first cooled down to about -80 degrees C within the cavity and then thawed by EM absorption. Results show that EM warming can produce much higher warming rate than conventional water-bath warming method. The spatial temperature distribution in the phantom during EM warming is also more uniform than that during the water-bath warming.     

The effect of EGF and the comitogen, norepinephrine, on the proliferative responses of fresh and cryopreserved rat and mouse hepatocytes

The effect of cryopreservation on the proliferative response of fresh and cryopreserved (CP) rat and mouse hepatocytes was studied. Of the parameters measured, incorporation of 3H-thymidine and bromodeoxyuridine (BdrU) incorporation were the most sensitive and LDH content was the least sensitive. The optimal seeding density for epidermal growth factor (EGF)-stimulated proliferative response in fresh rat and mouse hepatocytes was 1.8 x 10(4) cells/cm2 and 2.1 x 10(4) cells/cm2, respectively. 3H-thymidine incorporation by fresh rat and mouse hepatocytes was maximal in cultures treated with 10 and 5 ng/ml EGF, respectively. The cell attachment of fresh rat hepatocytes after 48 h was higher (68%) than CP (42%), therefore, the CP hepatocyte seeding density was increased to 7.1 x 10(4) cells/cm2 so that the cell number after 48 h was the same as fresh hepatocytes. Using the adjusted seeding density, the 3H-thymidine and BdrU incorporation into fresh and CP rat hepatocytes was equivalent. The attachment efficiencies of fresh and CP mouse hepatocytes were the same, therefore, no adjustment was needed. The proliferative response (3H-thymidine incorporation and DNA content) to EGF was the same in fresh and CP mouse hepatocytes. The comitogen, norepinephrine (NE), increased the proliferative response to EGF to the same extent in both fresh and CP rat hepatocytes. In summary, cryopreserved rat and mouse hepatocytes retain their ability to proliferate in culture. Adjustment and monitoring of the seeding density is of high importance, especially with rat hepatocytes, which lose some attachment capacity after cryopreservation. The secondary mitogenic effect of NE is also retained by cryopreserved rat hepatocytes, suggesting that these cells retain alpha1-receptor function.     

Water transport and IIF parameters for a connective tissue equivalent

Understanding the biophysical processes that govern freezing injury of a tissue equivalent (TE) is an important step in characterizing and improving the cryopreservation of these systems. TEs were formed by entrapping human dermal fibroblasts (HDFs) in collagen or in fibrin gels. Freezing studies were conducted using a Linkam cryostage fitted to an optical microscope allowing observation of the TEs cooled under controlled rates between 5 and 130 degrees C/min. Typically, freezing of cellular systems results in two biophysical processes that are both dependent on the cooling rate: dehydration and/or intracellular ice formation (IIF). Both these processes can potentially be destructive to cells. In this study, the biophysics of freezing cells in collagen and fibrin TEs have been quantified and compared to freezing cells in suspension. Experimental data were fitted in numerical models to extract parameters that governed water permeability, E(Lp) and L(pg), and intracellular ice nucleation, omega(o) and kappa(o). Results indicate that major differences exist between freezing HDFs in suspension and in a tissue equivalent. During freezing, 55% of the HDFs in suspension formed IIF as compared to 100% of HDFs forming IIF in collagen and fibrin TE at a cooling rate of 130 degrees C/min. Also, both the water permeability and the IIF parameters were determined to be higher for HDFs in TEs as compared to cell suspensions. Between the TEs, HDFs in fibrin TE exhibited higher values for the biophysical parameters as compared to HDFs in collagen TE. The observed biophysics seems to indicate that cell-cell and cell-matrix interactions play a major role in ice propagation in TEs.     

Cryovial with partial membrane sealing can prevent liquid nitrogen penetration in submerged storage

Cryopreservation is one of the fundamental techniques in life science. To preserve the viability of cells and tissues, many researchers use plastic cryogenic vials and immerse them into liquid nitrogen for long-term storage. However, the non-sterile liquid nitrogen usually infiltrates into the vials and may cause a high rate of microbial contamination, and even some explosive incidents upon retrieval. To prevent these drawbacks while retaining the benefit of constant ultra-low temperature in submerged liquid nitrogen, we used a heat-sealable membrane to cover the upper portion of vials. After heat-sealing, the vials were completely free of liquid nitrogen penetration in the submerging test. Moreover, the sealing process did not affect the cell viability. This modified protocol provides an easy and efficient tool to ensure the integrity of biospecimens in long-term storage without interfering with existing cryobox storage systems.     

A new approach for freezing of aqueous solutions under active control of the nucleation temperature

An experimental setup for controlled freezing of aqueous solutions is introduced. The special feature is a mechanism to actively control the nucleation temperature via electrofreezing: an ice nucleus generated at a platinum electrode by the application of an electric high voltage pulse initiates the crystallization of the sample. Using electrofreezing, the nucleation temperature in pure water can be precisely adjusted to a desired value over the whole temperature range between a maximum temperature Tn(max) close to the melting point and the temperature of spontaneous nucleation. However, the presence of additives can inhibit the nucleus formation. The influence of hydroxyethylstarch (HES), glucose, glycerol, additives commonly used in cryobiology, and NaCl on Tn(max) were investigated. While the decrease showed to be moderate for the non-ionic additives, the hindrance of nucleation by ionic NaCl makes the direct application of electrofreezing in solutions with physiological salt concentrations impossible. Therefore, in the multi-sample freezing device presented in this paper, the ice nucleus is produced in a separate volume of pure water inside an electrode cap. This way, the nucleus formation becomes independent of the sample composition. Using electrofreezing rather than conventional seeding methods allows automated freezing of many samples under equal conditions. Experiments performed with model solutions show the reliability and repeatability of this method to start crystallization in the test samples at different specified temperatures. The setup was designed to freeze samples of small volume for basic investigations in the field of cryopreservation and freeze-drying, but the mode of operation might be interesting for many other applications where a controlled nucleation of aqueous solutions is of importance.