Cryopreservation of rat precision-cut liver and kidney slices by rapid freezing and vitrification

Precision-cut tissue slices of both hepatic and extra-hepatic origin are extensively used as an in vitro model to predict in vivo drug metabolism and toxicity. Cryopreservation would greatly facilitate their use. In the present study, we aimed to improve (1) rapid freezing and warming (200 degrees C/min) using 18% Me(2)SO as cryoprotectant and (2) vitrification with high molarity mixtures of cryoprotectants, VM3 and VS4, as methods to cryopreserve precision-cut rat liver and kidney slices. Viability after cryopreservation and subsequent 3-4h of incubation at 37 degrees C was determined by measuring ATP content and by microscopical evaluation of histological integrity. Confirming earlier studies, viability of rat liver slices was maintained at high levels by rapid freezing and thawing with 18% Me(2)SO. However, vitrification of liver slices with VS4 resulted in cryopreservation damage despite the fact that cryoprotectant toxicity was low, no ice was formed during cooling and devitrification was prevented. Viability of liver slices was not improved by using VM3 for vitrification. Kidney slices were found not to survive cryopreservation by rapid freezing. In contrast, viability of renal medullary slices was almost completely maintained after vitrification with VS4, however vitrification of renal cortex slices with VS4 was not successful, partly due to cryoprotectant toxicity. Both kidney cortex and medullary slices were vitrified successfully with VM3 (maintaining viability at 50-80% of fresh slice levels), using an optimised pre-incubation protocol and cooling and warming rates that prevented both visible ice-formation and cracking of the formed glass. In conclusion, vitrification is a promising approach to cryopreserve precision-cut (kidney) slices.     

Glass transition behavior of the vitrification solutions containing propanediol, dimethyl sulfoxide and polyvinyl alcohol

Knowledge of the glass transition behavior of vitrification solutions is important for research and planning of the cryopreservation of biological materials by vitrification. This brief communication shows the analysis for the glass transition and glass stability of the multi-component vitrification solutions containing propanediol (PE), dimethyl sulfoxide (Me₂SO) and polyvinyl alcohol (PVA) by using differential scanning calorimetry (DSC) during the cooling and subsequent warming between 25 and −150 °C. The glass formation of the solutions was enhanced by introduction of PVA. Partial glass formed during cooling and the fractions of free water in the partial glass matrix increased with the increasing of PVA concentration, which caused slight decline of glass transition temperature, T_g. Exothermic peaks of devitrification were delayed and broadened, which may result from the inhibition of ice nucleation or recrystallization of PVA.     

Propane-1,2-diol as a potential component of a vitrification solution for corneas

Any method of cryopreservation of the cornea must maintain integrity of the corneal endothelium, a monolayer of cells on the inner surface of the cornea that controls corneal hydration and keeps the cornea thin and transparent. During freezing, the formation of ice damages the endothelium, and vitrification has been suggested as a means of achieving ice-free cryopreservation of the cornea. To achieve vitrification at practicable cooling rates, tissues must be equilibrated with high concentrations of cryoprotectants. In this study, the effects of propane-1,2-diol on the structure and function of rabbit corneal endothelium were studied. Corneas were exposed to concentrations of propane-1,2-diol ranging from 10 to 30% v/v in a Hepes-buffered Ringer's solution containing glutathione, adenosine, 5 mmol/liter sodium bicarbonate, and 6% w/v bovine serum albumin. Endothelial function was assessed by monitoring corneal thickness during perfusion of the endothelial surface at 34 degrees C for 6 hr. Exposure to 10-15% v/v propane-1,2-diol was well tolerated for 20 min at 4 degrees C when the cryoprotectant was removed in steps or by sucrose dilution. However, exposure to 25% v/v propane-1,2-diol for 20 min at 0 or -5 degrees C was consistently tolerated only when 2.5% w/v chondroitin sulfate was included in the vehicle solution. Exposure to 30% v/v propane-1,2-diol was harmful at -5 and -10 degrees C. The endothelial damage following exposure to 30% v/v propane-1,2-diol was probably the result of a toxic effect rather than osmotic stress. Although 25% v/v propane-1,2-diol does not vitrify at cooling rates that are practicable for corneas, it could at this concentration form a major component of a vitrification solution comprising a mixture of cryoprotectants.     

Survival of corneal endothelium following exposure to a vitrification solution

Corneal endothelium, a monolayer of cells lining the inner surface of the cornea, is particularly susceptible to freezing injury. Ice formation damages the structural and functional integrity of the endothelium, and this results in a loss of corneal transparency. Instead of freezing, an alternative method of cryopreservation is vitrification, which avoids damage associated with ice formation. Vitrification at practicable cooling rates, however, requires exposure of tissues to very high concentrations of cryoprotectants, and this can cause damage through chemical toxicity and osmotic stress. The effects of a vitrification solution (VS1) containing 2.62 mol/liter (20.5%, w/v) dimethyl sulfoxide, 2.62 mol/liter (15.5%, w/v) acetamide, 1.32 mol/liter (10%, w/v) propane-1,2-diol, and 6% (w/v) polyethylene glycol were studied on corneal endothelium. Endothelial function was assessed by monitoring corneal thickness during 6 hr of perfusion at 35 degrees C with a Ringer solution supplemented with glutathione and adenosine. Various dilutions of the vitrification solution were introduced and removed in a stepwise manner to mitigate osmotic stress. Survival of endothelium after exposure to VS1 or a solution containing 90% of the cryoprotectant concentrations in VS1 (90% VS1) was dependent on the duration of exposure, the temperature of exposure, and the dilution protocol. The basic dilution protocol was performed at 25 degrees C: corneas were transferred from 90% VS1 or VS1 into 50% VS1 for 15 min, followed by 25% VS1 for 15 min and finally into isosmotic Ringer solution. Using this protocol, corneal endothelium survived exposure to 90% VS1 for 15 min at -5 degrees C, but 5 min in VS1 at -5 degrees C was harmful and resulted in some very large and misshapen endothelial cells. This damage was not ameliorated by using a sucrose dilution technique; but endothelial function was improved when the temperature of exposure to VS1 was reduced from -5 to -10 degrees C. Exposure to VS1 for 5 min at -5 degrees C was well tolerated, however, when the temperature of the first dilution step into 50% VS1 was reduced from 25 to 0 degree C. The large, misshapen cells were not observed under these conditions nor after exposure to VS1 at -10 degrees C. These results suggested that damage was the result of cryoprotectant toxicity rather than osmotic stress. Thus, corneal endothelium survived exposure to two solutions of cryoprotectants, namely, 90% VS1 and VS1, that were sufficiently concentrated to vitrify. Whether corneas can be cooled fast enough in these solutions to achieve vitrification and warmed fast enough to avoid devitrification remains to be determined.     

活体肺癌组织玻璃化保存的研究

保存活体的肺癌组织将为肺癌发病基因筛查和靶向药物筛选等体外实验研究提供更完整的样本信息. 本文对活体肺癌组织的玻璃化保存方法进行研究，首先采用针浸法玻璃化保存单块肺癌组织，对所需低温保护剂的浓度和平衡时间进行了优化；其次采用冻存管对多块肺癌组织样本进行玻璃化保存，对低温保护剂溶液体积以及平衡时间进行了优化；最后对慢速冷冻、不加低温保护剂快速冷冻、玻璃化冷冻3种冷冻方法的冻存效果进行比较并通过低温显微分析其冰晶损伤机理.结果表明，20% EG+20% DMSO+0.5 mol/L海藻糖作为低温保护剂，在平衡溶液和玻璃化溶液分别加载3 min和1 min时，针浸法和0.25 ml冻存管内玻璃化冻存，复苏后组织活力最高，分别约为79.96%与80.44%. 免疫组化显示玻璃化保存肺癌组织经过复苏后，相比慢速冷冻和无保护剂快速冷冻，组织结构损伤较小，组织内细胞TUNEL阳性表达较少. 低温显微结果表明，玻璃化保存组织内部及周围只出现少量细小冰晶，而慢速冷冻、快速冷冻组织皆出现明显冰晶.     

Vitrification of posterior corneal lamellae

Cryopreservation of corneas has not yet been established as a routine method. Unsatisfactory experimental results with conventional techniques prompted us to explore the possibilities of vitrification. The aim of the present study was to optimize the heat exchange between the corneal tissue and cooling medium by reducing the corneal tissue volume and using a suitable sample container. A further objective was to promote vitrification by developing a new device for rapid cooling to -140 degrees C, just below the vitrification temperature of the cryopreservation medium. Experiments were done using posterior lamellar discs from pig corneas with a diameter of 7.5 mm and a thickness of 250-350 microm. The volume of tissue to be vitrified was 88% lower with posterior corneal lamellae than with the previously used corneoscleral discs. A very thin-walled (0.05 mm), teflon-coated bag served as the sample container. Immersed in only 0.1 ml of the vitrification solution VS41a, the lamellae were cooled to a final storage temperature of -196 degrees C. After warming and organ-culturing for 24h, the endothelium was stained with trypan blue and alizarin red, to determine cell viability. Vitrification of corneal lamellae without apparent ice formation or cracking of the specimen was achieved. Despite the successful vitrification, only a maximum of 10% of the endothelial cells was vital after warming. Thus, the toxicity of the cryoprotective agents and the devitrification that occurred during the heating process require further optimization of the method.     

The effect of internal and external cryoprotectants on zebrafish (Danio rerio) embryos

The study investigated the effects of internal (DMSO, 1,2-propanediol, glycerol, ethylene glycol, methanol, N,N-dimethylacetamide) and external cryoprotectants (glucose, sucrose) on the viability and on morphometric parameters of zebrafish embryos. From the tested internal cryoprotectants, DMSO had the lowest toxicity, followed by 1,2-propanediol and glycerol. The external cryoprotectants were less toxic then the internal ones. Early ontogenetic stages were more sensible to cryoprotectant exposure than advanced stages. Two-step incubation procedures in increasing concentrations of internal and external cryoprotectants were superior to multiple-step exposure procedures. All tested vitrification solutions exceeded the tolerance limit of embryos. The tolerance of zebrafish embryos to cryoprotectants was highly variable in a concentration range causing approximately 50% embryo mortality. The width of the perivitelline space showed significant morphometrical changes due to cryoprotectant exposure. In the germinative tissue non-significant changes occurred. The yolk did not change morphometrically after exposure to internal cryoprotectants and showed no sign of dehydration after exposure to external cryoprotectants. Based on these results the study comes to the following conclusions: as yolk dehydration was impossible and as vitrification solutions were over the tolerance limit it seems unlikely that successful vitrification of zebrafish embryos can be achieved. Under these considerations slow freezing methods would be a better option as lower cryoprotectant concentrations can be used and embryos can be dehydrated during freezing.     

Factors affecting the survival of mouse embryos cryopreserved by vitrification

Preimplantation stage mouse embryos have been used to examine the response of a simple multicellular system to cryopreservation by the complete vitrification of the suspension. Successful vitrification requires the use of a solution of cryoprotectants that is sufficiently concentrated to supercool and solidify into a glass at practicable cooling rates. Factors that influence the survival of embryos include the concentration and composition of the vitrification solution, the procedure used to equilibrate embryos in this solution, the cooling and warming conditions, and the procedure used to dilute embryos from the vitrification solution. High rates of survival are obtained when embryos are dehydrated prior to vitrification in solutions composed of saline plus multimolar concentrations of either mixtures of permeating cryoprotectants (e.g. dimethyl sulphoxide-acetamide-propylene glycol) or single permeating cryoprotectants (propylene glycol or glycerol). Full permeation of cryoprotectants into the cells is not necessary and may lead to chemical toxicity and osmotic injury. Partial permeation and osmotic shrinkage concentrates the endogenous cytoplasmic macromolecules and greatly increases the likelihood of intracellular vitrification. Vitrification is a practical approach for embryo cryopreservation and offers new opportunities to examine fundamental aspects of cryoprotection and cryoinjury in the absence of freezing.     

Vitrification of large tissues with dielectric warming: biological problems and some approaches to their solution

If large pieces of tissue and organs are to be successfully stored at low temperatures, some means must be found to minimize the disruption of extracellular structures by the ice that develops during conventional cryopreservation methods. The use of sufficiently high concentrations of cryoprotectant (CPA) to vitrify rather than freeze the tissue is a possible solution to this problem, and the retention of function of embryos and elastic arteries after vitrification suggests that some cells and tissues at least can withstand exposure to the high concentrations of CPA necessary for this process to occur. There are, however, additional problems in applying vitrifying techniques to bulky tissues and organs. These are related to the additional time required for tissue equilibration of CPA to occur and the consequences for toxic injury, the difficulty in achieving sufficiently rapid and uniform cooling rates to produce the required glassy state, and the even more rapid and uniform warming rates that are necessary to avoid devitrification. Non-uniformity of temperature will increase the risk of mechanical stresses and fractures developing in the glass during rapid warming. This paper reviews possible strategies and the progress that has been made in overcoming these problems. This will include the permeation of CPA mixtures into whole tissues and possibilities for reducing their toxicity by the inclusion of adjuncts such as ice inhibitors and sugars. The warming of tissues by dielectric heating is currently the only practical means by which sufficiently rapid rates can be achieved in bulky tissues given that the tolerable limits of CPA concentration will most likely be insufficient to prevent the development of ice nuclei during cooling. The biological effects of microwaves are reviewed and their effectiveness in producing the required uniformity in warming of tissue models of various shapes are discussed.     

Pig oocyte vitrification by cryotop method: effects on viability, spindle and chromosome configuration and in vitro fertilization

Three experiments were designed to evaluate the effects of vitrification using Cryotop method on MII porcine oocyte viability, chromosomes configuration, meiotic spindle morphology and in vitro fertilization; to do this, in vitro matured oocytes were subjected to the cryoprotectant treatment excluding the plunging into liquid nitrogen, the whole vitrification/warming/rehydration procedure or no treatment (control). In experiment 1 viable oocytes were not reduced by either cryoprotectants or vitrification when they were evaluated immediately after warming and cryoprotectant dilution. However, after a 2 h incubation, the survival rate significantly decreased (P<0.05). In experiment 2 cryoprotectant exposure significantly (P<0.05) influenced spindle morphology even if chromosome organization did not vary, while vitrification significantly (P<0.05) increased oocytes with damaged spindles and chromosomes displaced from the metaphase plate. No significant improvements in these parameters were observed after 2 h of incubation but, on the contrary, the rate of oocytes with normal chromosome configuration was reduced. In experiment 3 significant differences among the three groups in the fertilization rate but not in the percentages of monospermy fertilization were recorded; in addition, exposure to cryoprotectants and vitrification significantly (P<0.05) increased degenerated oocyte rate. Overall, these findings confirm that porcine oocytes at MII stage are very sensitive to vitrification, which reduces the rate of viable oocytes and alters microtubule organization, thus impairing fertilization; in addition, incubation of oocytes for 2 h after devitrification seems to be detrimental rather than ameliorative. Further improvements of the current protocol will be necessary in order to optimize the Cryotop method for vitrifying pig matured oocytes.     

Cryopreservation of cornea: a low cooling rate improves functional survival of endothelium after freezing and thawing

AIM: To investigate the influence of low cooling rates on endothelial function and morphology of corneas frozen with propane-1,2-diol (PROH). METHODS: Rabbit corneas, mounted on support rings, were exposed to 1.4mol/l (10% v/v) PROH, seeded to initiate freezing, and cooled at 0.2 or 1 degrees C/min to -80 degrees C. Corneas were frozen immersed in liquid or suspended in air. After being held overnight in liquid nitrogen, corneas were warmed at 1 or 20 degrees C/min. After stepwise removal of the cryoprotectant, the ability of the endothelium actively to control corneal hydration was monitored during normothermic perfusion. Morphology was assessed after staining with trypan blue and alizarin red S, and by specular microscopy during perfusion. RESULTS: Functional survival was achieved only after slow cooling (0.2 degrees C/min) with the cornea immersed in the cryoprotectant medium, and rapid warming (20 degrees C/min). These conditions also gave the best morphology after freezing and thawing. CONCLUSION: Cooling rates lower than those typically applied to cornea improved functional survival of the endothelium. This result is in accord with previous observations showing the benefit of low cooling rates for cell monolayers [CryoLetters 17 (1996) 213-218].     

Ovarian tissue cryopreservation by stepped vitrification and monitored by X-ray computed tomography

Ovarian tissue cryopreservation is, in most cases, the only fertility preservation option available for female patients soon to undergo gonadotoxic treatment. To date, cryopreservation of ovarian tissue has been carried out by both traditional slow freezing method and vitrification, but even with the best techniques, there is still a considerable loss of follicle viability. In this report, we investigated a stepped cryopreservation procedure which combines features of slow cooling and vitrification (hereafter called stepped vitrification). Bovine ovarian tissue was used as a tissue model. Stepwise increments of the Me₂SO concentration coupled with stepwise drops-in temperature in a device specifically designed for this purpose and X-ray computed tomography were combined to investigate loading times at each step, by monitoring the attenuation of the radiation proportional to Me₂SO permeation. Viability analysis was performed in warmed tissues by immunohistochemistry. Although further viability tests should be conducted after transplantation, preliminary results are very promising. Four protocols were explored. Two of them showed a poor permeation of the vitrification solution (P1 and P2). The other two (P3 and P4), with higher permeation, were studied in deeper detail. Out of these two protocols, P4, with a longer permeation time at −40 °C, showed the same histological integrity after warming as fresh controls.     

Measurement of essential physical properties of vitrification solutions

Vitrification is an "ice-free" cryopreservation method that has rapidly developed in recent years and might become the method of choice for oocyte cryopreservation. Five sources of damage should be considered when attempting to achieve successful oocyte cryopreservation by vitrification: (1) Solution effects (2) Crystallization (3) Glass fractures (4) Devitrification and recrystallization (5) Chilling injury. The probability of successful vitrification depends on three major factors: viscosity of the sample; cooling and warming rates; and sample volume. One of the problems associated with the vitrification solution is that it may contain high concentrations of cryoprotectants (CP), which can damage the cells through chemical toxicity and osmotic shock. In the present study, we examined the principal parameters associated with successful vitrification, and attempted to compose guidelines to the most important aspects of the vitrification process. The first step was the selection of a suitable and least toxic vitrification solution. We then evaluated the effects of cooling rate and volume on the probability of vitrification. Reduction of the sample volume, combined with accelerated cooling, enabled reduction of the CP concentration. However, in practice, a delicate balance must be maintained among all the factors that affect the probability of vitrification in order to prevent crystallization, devitrification, recrystallization, glass fractures and chilling injury.     

Japanese flounder (Paralichthys olivaceus) embryos are difficult to cryopreserve by vitrification

The first successful cryopreservation of fish embryos was reported in the Japanese flounder by vitrification [Chen and Tian, Theriogenology, 63, 1207-1219, 2005]. Since very high concentrations of cryoprotectants are needed for vitrification and fish embryos have a large volume, Japanese flounder embryos must have low sensitivity to cryoprotectant toxicity and high permeability to water and cryoprotectants. So, we investigated the sensitivity and the permeability of Japanese flounder embryos. In addition, we assessed the survival of flounder embryos after vitrification with solutions containing methanol and propylene glycol, following Chen and Tian's report. The embryos were relatively insensitive to the toxicity of individual cryoprotectants at lower concentrations, especially methanol and propylene glycol as their report. Although their permeability to water and cryoprotectants could not be measured from volume changes in cryoprotectant solutions, the embryos appeared to be permeable to methanol but less permeable to DMSO, ethylene glycol, and propylene glycol. Although vitrification solutions containing methanol and propylene glycol, which were used in Chen and Tian's report, were toxic to embryos, a small proportion of embryos did survived. However, when vitrified with the vitrification solutions, no embryos survived after warming. The embryos became opaque during cooling with liquid nitrogen, indicating the formation of intracellular ice during cooling. When embryos had been kept in vitrification solutions for 60 min after being treated with the vitrification solution, some remained transparent during cooling, but became opaque during warming. This suggests that dehydration and/or permeation by cryoprotectants were insufficient for vitrification of the embryos even after they had been over-treated with the vitrification solutions. Thus, Chen and Tian's cryopreservation method lacks general application to Japanese flounder embryos.     

Implications of storage and handling conditions on glass transition and potential devitrification of oocytes and embryos

Devitrification, the process of crystallization of a formerly crystal-free, amorphous glass state, can lead to damage during the warming of cells. The objective of this study was to determine the glass transition temperature of a cryopreservation solution typically used in the vitrification, storage, and warming of mammalian oocytes and embryos using differential scanning calorimetry. A numerical model of the heat transfer process to analyze warming and devitrification thresholds for a common vitrification carrier (open-pulled straw) was conducted. The implications on specimen handling and storage inside the dewar in contact with nitrogen vapor phase at different temperatures were determined. The time required for initiation of devitrification of a vitrified sample was determined by mathematical modeling and compared with measured temperatures in the vapor phase of liquid nitrogen cryogenic dewars. Results indicated the glass transition ranged from −126 °C to −121 °C, and devitrification was initiated at −109 °C. Interestingly, samples entered rubbery state at −121 °C and therefore could potentially initiate devitrification above this value, with the consequent damaging effects to cell survival. Devitrification times were calculated considering an initial temperature of material immersed in liquid nitrogen (−196 °C), and two temperatures of liquid nitrogen vapors within the dewar (−50 °C and −70 °C) to which the sample could be exposed for a period of time, either during storage or upon its removal. The mathematical model indicated samples could reach glass transition temperatures and undergo devitrification in 30 seconds. Results of the present study indicate storage of vitrified oocytes and embryos in the liquid nitrogen vapor phase (as opposed to completely immersed in liquid nitrogen) poses the potential risk of devitrification. Because of the reduced time-handling period before samples reach critical rubbery and devitrification values, caution should be exercised when handling samples in vapor phase.     

Production of channel catfish with sperm cryopreserved by rapid non-equilibrium cooling

This report describes the feasibility of using vitrification for fish sperm. Vitrification can be used to preserve samples in the field and offers an alternative to conventional cryopreservation, although it has not been systematically studied for sperm of aquatic species. The overall goal of the project was to develop streamlined protocols that could be integrated into a standardized approach for vitrification of aquatic species germplasm. The objectives of the present study in channel catfish (Ictalurus punctatus) were to: (1) evaluate the acute toxicity of 5%, 10%, 20% and 30% methanol, N,N-dimethyl acetamide, dimethyl sulfoxide, 1,2-propanediol, and methyl glycol; (2) evaluate a range of devices commonly used for cryopreservation and vitrification of mammalian sperm; (3) compare vitrification with and without cryoprotectants; (4) evaluate the post-thaw membrane integrity of sperm vitrified in different cryoprotectant solutions, and (5) evaluate the ability of vitrified sperm to fertilize eggs. Cryoprotectant concentrations of higher than 20% were found to be toxic to sperm. Methanol and methyl glycol were the least toxic at a concentration of 20% with an exposure time of less than 5 min. We evaluated a method reported for human sperm, using small volumes in loops (15 μl) or cut standard straws (20 μl) with and without cryoprotectants plunged into liquid nitrogen. Cryoprotectant-free vitrification using loops did not yield fertilization (assessed by neurulation), and the fertilization rates observed in two trials using the cut standard straws were low (∼2%). In general, fertilization values for vitrification experiments were low and the use of low concentrations of cryoprotectants yielded lower fertilization (<10%) than the use of vitrification solutions containing high cryoprotectant concentrations (as high as 25%). The highest neurulation obtained was from a mixture of three cryoprotectants (20% methanol + 10% methyl glycol + 10% propanediol) with a single-step addition. This was reflected in the flow cytometry data from which the highest membrane integrity using loops was for 20% methanol + 10% methyl glycol + 10% propanediol (∼50%). We report the first successful sperm vitrification in fish and production of offspring from vitrified sperm in channel catfish. Although the fertilization values were low, at present this technique could nevertheless be used to reconstitute lines (especially in small aquarium fishes), but it would require improvement and scaling up before being useful as a production method for large-bodied fishes such as catfish.     

Vitrification of domestic cat (Felis catus) ovarian tissue: Effects of three different sugars

We aimed to evaluate the effect of three extracellular cryoprotectants on the morphology of vitrified feline preantral follicles. Feline ovarian fragments (0.5 × 2 × 2 mm) collected from five domestic adult cats subjected to ovariohysterectomy for routine castration were vitrified with ethylene glycol (EG) 40% combined or not with sucrose (0.1 or 0.5 M), trehalose (0.1 or 0.5 M), or raffinose (0.1 M). After vitrification using the solid-surface method and warming of the tissues, cryoprotectants were washed out of the ovarian tissues, which were fixed for histological analysis. The percentages of normal follicles were similar to the control (fresh) (62.9 ± 4.1%) only for tissues exposed and cryopreserved with EG + trehalose at concentrations of 0.1 (35.8 ± 8.3%) and 0.5 M (33.4 ± 5.4%). All the other sugars decreased the percentages of morphologically normal follicles as compared to the control group and the trehalose groups. Based on the results of the present study, we recommend the use of trehalose as the extracellular cryoprotectant for the vitrification of feline ovarian tissue.     

Vitrification of dog spermatozoa: Effects of two cryoprotectants (sucrose or trehalose) and two warming procedures

Sperm vitrification is a low cost and simple technique that does not require special equipment and may represent an attractive alternative to the costly and time consuming conventional dog spermatozoa cryopreservation techniques. The objective of this study was to evaluate different cryoprotectants and warming temperatures on the vitrification of dog spermatozoa. Pooled semen samples from 10 beagle dogs were vitrified with four extenders, based on Tris, citric acid and glucose, 20% egg yolk (TCG-20% EY) and different combinations of sucrose and/or trehalose: 250 mM sucrose; 250 mM trehalose; 125 mM sucrose + 125 mM trehalose; 250 mM sucrose + 250 mM trehalose. Samples were vitrified by dropping 50 μL of sperm suspension directly into liquid nitrogen. After vitrification, warming was done either fast (at 65 °C for 2–5 s) or slow (at 37 °C for one minute). Motility was assayed using a computer-aided sperm analysis (CASA) system; membrane integrity and acrosomal status were analyzed by fluorescence microscopy. For comparison, samples were also conventionally frozen in liquid nitrogen vapor using a TCG-20% egg yolk extender plus 5% glycerol. Frozen straws were thawed in a water bath at 37 °C for 30 s. Poorer motility results (P < 0.05) but similar viability were obtained when vitrification was performed, compared to conventional freezing (P > 0.05). When vitrification was used, cryoprotectants containing either 250 mM sucrose or 250 mM trehalose and warmed at 37 °C returned the best sperm quality variables.     

Vitrification of mouse oocytes using short cryoprotectant exposure: effects of varying exposure times on survival.

The effects on oocyte viability of varying the duration of exposure to cryoprotectants before rapid cooling to -196 degrees C were examined, using the vitrification protocol of Nakagata. A very short exposure (15 sec) was found to be optimal, resulting in an overall rate of development from vitrified oocytes to hatching blastocysts of 31.8%. Very high rates of survival (77-89%) of oocytes exposed to the cryoprotectant media, but without the vitrification, together with extreme variability in results between straws in the vitrified groups, suggest that losses in viability during vitrification may result from ice damage during devitrification of the medium.