Cryopreservation of pig and human liver slices

The ability to cryopreserve human liver slices would greatly enhance the opportunities to test potentially hepatotoxic drugs and environmental contaminants as well as the metabolism of these compounds. This study focused on trying to cryopreserve pig and human liver slices. Since the acquisition of human liver tissue is unpredictable and scarce, an animal model was sought to predict problems associated with cryopreservation of human tissue. The pig liver was chosen because of its anatomical and physiological resemblance to human liver. The human liver tissues that did become available were obtained through the Arizona Organ Bank and the National Disease Research Interchange and from surgical liver resections. An in vitro culture system that employed precision-cut liver slices was used in this study. Different types and concentrations of cryoprotectants, cooling rates, and culture media were all tried in an attempt to cryopreserve pig and human liver slices. The viabilities of fresh and cryopreserved liver slices were evaluated using slice K+ retention and protein synthesis. Pig liver slices following cryopreservation retained between 80 and 85% of intracellular K+ content and protein synthesis as compared to controls using 1.4 M Me2SO, a 12 degrees C/min cooling rate, and a rapid rewarming rate of direct submersion of the slice into 37 degrees C fetal calf serum. Human liver slices following cryopreservation retained between 54 and 89% of intracellular K+ content and protein synthesis as compared to controls using the same protocol as for pigs, except that lower cooling rates were giving better results. The large variation seen in cryopreserved human liver slices was due to the length of warm and cold ischemia to which the tissue was exposed before arriving at the laboratory. This study indicated that pig and human liver slices can be cryopreserved and used for future toxicological and metabolic studies.     

High developmental rates of vitrified bovine oocytes following parthenogenetic activation, in vitro fertilization, and somatic cell nuclear transfer

Successful cryopreservation of mammalian oocytes would provide a steady source of materials for nuclear transfer and in vitro embryo production. Our goal was to develop an effective vitrification protocol to cryopreserve bovine oocytes for research and practice of parthenogenetic activation, in vitro fertilization, and nuclear transfer. Bovine oocytes matured in vitro were placed in 4% ethylene glycol (EG) in TCM 199 plus 20% fetal bovine serum (FBS) at 39 degrees C for 12-15 min, and then transferred to a vitrification solution (35% EG, 5% polyvinyl-pyrrolidone, 0.4 M trehalose in TCM 199 and 20% FBS). Oocytes were vitrified in microdrops on a precooled (-150 degrees C) metal surface (solid-surface vitrification). The vitrified microdrops were stored in liquid nitrogen and were either immediately thawed or were thawed after storage for 2-3 wk. Surviving oocytes were subjected to 1) parthenogenetic activation, 2) in vitro fertilization, or 3) nuclear transfer with cultured adult fibroblast cells. Treated oocytes were cultured in KSOM containing BSA or FBS for 9 to 10 days. Embryo development rates were recorded daily and morphologically high-quality blastocysts were cryopreserved for nuclear transfer-derived embryos at Day 7 or Day 8 of culture. Immediate survival of vitrified/thawed oocytes varied between 77% and 86%. Cleavage and blastocyst development rates of vitrified oocytes following in vitro fertilization or activation were lower than those of the controls. For nuclear transfer, however, vitrified oocytes supported embryonic development as equally well as fresh oocytes.     

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.     

Cryopreserved rat liver slices: a critical evaluation of cell viability, histological integrity, and drug-metabolizing enzymes

The effects of a cryopreservation procedure on the biochemical, morphological and functional integrity of rat liver slices just after thawing and after 24 h culture were evaluated. Freshly prepared slices were incubated in modified University of Wisconsin solution containing 50% fetal calf serum and 10% dimethyl sulfoxide for 20 min on ice prior to a rapid cooling in liquid nitrogen. After 10-40 days, slices were thawed rapidly at 42 degrees C. Total protein content and (3-[4,5-dimethylthiazol-2-yl]-2, 5-diphenyltetrazolium bromide) (MTT) reduction were well preserved at thawing, whereas ATP content was markedly decreased relative to freshly prepared slices (-83%). The major microscopic findings in sections of just-thawed liver slices consisted of hepatocellular dissociation and minimal apoptosis. The qualitative profile of antipyrine (AP) metabolism was well preserved in cryopreserved slices, but the amounts of phase I and phase II AP metabolites produced over a 3-h incubation period were markedly reduced relative to fresh slices (-58 to -71%). When cryopreserved slices were cultured for 24 h after thawing, the viability was markedly reduced, as reflected by the almost complete absence of MTT reduction and the loss of ATP content. Histological examinations showed extensive cellular necrosis. The amount of AP metabolites produced by cryopreserved slices was similar after a 3- or a 24-h culture period, indicating that AP metabolism capacities were lost at 24 h culture. In conclusion, our results suggest that cryopreserved rat liver slices may be a useful model for short-term in vitro determination of drug metabolism pathways. Further work is required to extend their use for toxicological studies.     

Cryoprotectant-free cryopreservation of human spermatozoa by vitrification and freezing in vapor: effect on motility, DNA integrity, and fertilization ability

Human spermatozoa can be successfully cryopreserved avoiding the use of cryoprotectants through vitrification at very high cooling rates (up to 7.2 x 10(5) degrees C/min). This is achieved by directly plunging a copper cryoloop loaded with a sperm suspension into liquid nitrogen. After storage, vitrified spermatozoa are instantly thawed by melting in an agitated, warm medium. The goal of the present study was to compare the quality of spermatozoa cryopreserved using this rapid vitrification method with that of spermatozoa cooled relatively slowly by preexposure of the loaded cryoloop to liquid nitrogen vapor (-160 degrees C) with speed in the range 150-250 degrees C/min) before immersion into liquid nitrogen. Both cooling modes led to comparable results in terms of the motility, fertilization ability, and DNA integrity of the warmed spermatozoa. In both cases, instant thawing by melting in a warm medium was essential for successful cryopreservation. Our findings suggest that optimal regimes for the cryoprotectant-free cryopreservation of spermatozoa need not be restricted to very fast cooling before storage in liquid nitrogen, a wide range of cooling rates being acceptable. Herein, we discuss the implications of this finding in the light of the physics of extra- and intracellular vitrification.     

Double vitrification of rat embryos at different developmental stages using an identical protocol

The aim of the present investigation was to test the effectiveness of a method of vitrifying rat embryos at different stages of development (from early morula to expanding blastocyst) in a double vitrification procedure. Wistar rat embryos were vitrified and warmed in super-fine open-pulled straws (SOPS). Before being plunged into liquid nitrogen, the embryos were exposed to 40% ethylene glycol+0.75 M sucrose in TCM-199+20% fetal calf serum (FCS) for 20s at 38 degrees C. Subsequent warming and direct rehydration of the embryos was conducted in culture medium (TCM-199+20% FCS) at 38 degrees C. Early morula stage (7-10 blastomeres) embryos (n=358) were vitrified, warmed and cultured in vitro (EM group). Batches of these embryos were then cryopreserved again (revitrified) at the early blastocyst (EB group, n=87), blastocyst (B group, n=93) or expanding blastocyst stage (ExpB group, n=73). After the first (EM group) and repeated (EB, B, and ExpB groups) vitrification procedures, developmental rates of 81, 83, 34 and 76%, respectively were achieved (for EM-EB-ExpB P>0.1; for EM, EB, ExpB-B P<0.005). Our data demonstrate the possibility of using the described identical protocol for the SOPS vitrification of rat early morulae, early blastocysts and expanding blastocysts. The low survival rate of blastocysts subjected to double vitrification requires further investigation.     

Vitrification of mouse oocytes results in aneuploid zygotes and malformed fetuses

Vitrification of mouse oocytes adversely affected the subsequent developmental potential of embryos and fetuses derived from the fertilization of such oocytes after thawing. Only 5% of oocytes vitrified formed viable fetuses on the 15th day of gestation as compared to 47% in the controls. The incidence of chromosomally aneuploid zygotes, derived from cryopreserved oocytes, was approximately threefold higher than the controls irrespective of whether the oocytes were cryopreserved by vitrification or DMSO slow-freezing. Malformed fetuses were obtained from oocytes that had been vitrified as well as those that had been exposed to vitrification solutions only, whereas no malformed fetuses were obtained in oocytes slow-frozen by DMSO or fresh controls--thus demonstrating that the exposure of oocytes to the vitrification chemicals was responsible for the fetal malformations. The data in this study suggest that the vitrification technique should be cautiously applied to human oocyte cryopreservation. Furthermore, the data also demonstrate that the exposure of female gametes to carcinogenic and/or teratogenic chemicals may result in malformed embryos when such oocytes are subsequently fertilized.     

Cryopreservation of porcine embryos by vitrification: A study of in vitro development

Until recently, attempts to preserve porcine embryos have been unsuccessful. Vitrification has been developed as a method of cryopreserving mammalian embryos by avoiding ice crystal formation, assuring a cryopreserved glass state during storage in liquid nitrogen. Vitrification may be a useful method of overcoming the deleterious effects of chilling injury when pig embryos are cryopreserved using conventional slow freezing procedures. In this study, we applied vitrification procedures for rodent and/or bovine embryos to cryopreserve porcine embryos. Following warming, survival was defined as normal development of embryos in culture, namely the formation or reexpansion of the blastocoelic cavity. Experiment 1 tested the relative toxicity of 3 vitrification procedures on Day-5, 6 and 7 porcine embryos. Embryos equilibrated in vitrification solution (VS3a) continued to develop in vitro at rates comparable to that of untreated control embryos. Experiment 2 was designed to evaluate embryonic development following cryopreservation by vitrification in VS3a. Day-5 porcine embryos did not survive cryopreservation while Day-6 and Day-7 embryos survived and continued development in vitro. In Experiment 3, we evaluated a period of culture prior to vitrification and its effect on cryosurvivability of porcine embryos. A 3-h culture period prior to vitrification had no effect on cryosurvivability over that of freshly recovered, immediately vitrified embryos. These studies indicate, for the first time, that porcine embryos can be successfully cryopreserved by vitrification based on morphology and subsequent development in vitro. However, survival following cryopreservation appears to depend upon embryonic age or stage of development.     

Meiotic maturation of vitrified immature chousingha (Tetracerus quadricornis) oocytes recovered postmortem

The ability to recover and cryopreserve oocytes from postmortem ovaries of endangered or wildlife species holds tremendous potential for conservation using assisted reproductive technologies. The objective of this study was to assess the in vitro meiotic maturation of chousingha (four-horned antelope) oocytes following vitrification using open pulled straw (OPS) method. The average number of oocytes recovered per ovary was 65.6. The proportion of oocytes that matured was significantly lower in vitrified oocytes (29.4%) when compared with fresh oocytes (69.3%). The study provides evidence that it is possible to cryopreserve immature oocytes by vitrification collected from the ovaries of chousingha at postmortem and also demonstrates that these cryopreserved oocytes retain their potential to undergo in vitro meiotic maturation.     

Development of vitrified porcine primordial follicles in xenografts

The objective was to cryopreserve porcine primordial follicles by vitrification and to assess the development of these follicles in xenografts. Ovarian tissues containing primordial follicles were collected from neonatal (15-d-old) piglets. They were vitrified in modified tissue culture medium (TCM)-199 containing 15% (v/v) ethylene glycol, 15% (v/v) dimethylsulfoxide, 20% (v/v) fetal calf serum, and 0, 0.25, or 0.5 M sucrose. After 1 wk of storage in liquid nitrogen (LN₂), the tissues were warmed, and the morphology of follicles and oocytes was examined histologically. After vitrification in sucrose-free medium, there were 50 ± 2 (mean ± SEM; n = 10) follicles per tissue, in contrast with 108 ± 10 (n = 10) in fresh tissues. Losses were attributed to puncturing oocytes during the vitrification-warming process, as oocytes were apparently normal after treatment of the sucrose-free vitrification solution without plunging into LN₂. When tissues were vitrified in sucrose-supplemented medium, loss of oocytes decreased (P < 0.05). However, the number of abnormal oocytes having nuclear shrinkage was increased (P < 0.05) by the addition of 0.5 M sucrose; this occurred in a small number of oocytes treated with sucrose-supplemented vitrification solutions without vitrification. After 2 mo of xenografting of vitrified-warmed tissues in SCID (severe combined immune deficiency) mice, primordial follicles developed to the secondary stage (accompanied by oocyte growth), whereas there was development to the antral stage in xenografts of fresh tissues. In conclusion, primordial follicles from neonatal pigs maintained their developmental ability after vitrification and warming, although their developmental rate was slower than that of the fresh control in xenografts.     

Effect of sugars-addition on the survival of vitrified bovine blastocysts produced in vitro

We investigated the effect of addition of sugars to a vitrification solution on the survival rate of bovine blastocysts produced in vitro. In vitro-matured (IVM) and in vitro-fertilized (IVF) bovine Day-6 to Day-8 bovine blastocysts were classified into 3 developmental stages: early blastocysts, blastocysts and expanded blastocysts. The blastocysts were cryopreserved in 1 of 3 vitrification solutions: 1) 25% glycerol25% ethylene glycol (GE); 2) 20% glycerol20% ethylene glycol3/4 M sucrose (GES); and 3) 20% glycerol20% ethylene glycol3/8 M sucrose3/8 M dextrose (GESD). The basic solution was Dulbecco's PBS supplemented with 20% of fetal calf serum. Embryos were exposed to each vitrification solution in 3 steps, and after loading into 0.25-ml straws, were plunged into liquid nitrogen. After warming in water bath at 20 degrees C, cryoprotectants were diluted in 1/2 M and 1/4 M sucrose each for 5 min. Equilibration and dilution procedure except warming were conducted at room temperature (23 to 27 degrees C). After dilution, the embryos were cultured in Ham's F10 medium0.1 mM beta-mercaptoethanol20% fetal calf serum. Survival rates of embryos at 48 h of incubation of each of the 3 developmental stages (early blastocysts, blastocysts and expanded blastocysts) exposed to the 3 types of the vitrification solutions (GE, GES and GESD) were 23.5, 33.3, 65.8% (early blastocysts, blastocysts and expanded blastocysts respectively) in GE, 55.6, 71.9, 90.5% in GES and 84.6, 83.3, 95.8% in GESD respectively. These results indicate that a mixture of 25% glycerol25% ethylene glycol is not suitable for vitrification of early bovine blastocysts; however, addition of sugars to the solution significantly (P<0.01) improved the survival rate of the vitrified blastocysts, independently of their stage of development.     

Vitrification of porcine embryos at various developmental stages using different ultra-rapid cooling procedures

In this study, three different vitrification systems (open pulled straw: OPS; superfine open pulled straw: SOPS; and Vit-Master technology using SOPS: Vit-Master-SOPS) were compared in order to investigate the influence of cooling rate on in vitro development of vitrified/warmed porcine morulae, early blastocysts, or expanded blastocysts. Embryos were obtained surgically on Day 6 of the estrous cycle (D0 = onset of estrus) from weaned crossbred sows, classified and pooled according their developmental stage. A subset of embryos from each developmental stage was cultured to evaluate the in vitro development of fresh embryos; the remaining embryos were randomly allocated to each vitrification system. After vitrification and warming, embryos were cultured in vitro for 96 h in TCM199 with 10% fetal calf serum at 39 degrees C, in 5% CO(2) in humidified air. During the culture period, embryos were morphologically evaluated for their developmental progression. The developmental stage of embryos at collection affected the survival and hatching rates of vitrified/warmed embryos (P < 0.001). The vitrification system or the interaction of vitrification system and developmental stage had no effect on these parameters (P > 0.05). Vitrified expanded blastocysts showed the best development in vitro (P < 0.001), with survival and hatching rates similar to those of fresh expanded blastocysts. The hatching rate of fresh morula or early blastocyst stage embryos was higher than their vitrified counterparts. In conclusion, under our experimental conditions, cooling rates greater than 20,000 degrees C/min, as occurs when SOPS or Vit-Master-SOPS systems are used, do not enhance the efficiency of in vitro development of vitrified porcine embryos.     

Vitrification of two-cell rat embryos derived from immature hypothyroid rdw rats by in vitro fertilization in ethylene glycol-based solutions

Two-cell embryos derived from immature rdw rats by in vitro fertilization (IVF) were vitrified in ethylene glycol-based solutions. Embryos exposed to EFS20 before being vitrified in EFS40 exhibited improved viability in vitro. All embryos exposed to EFS20 for 1-3 min before vitrification in EFS40 were morphologically normal. However, 2-3 min of exposure to EFS20 increased the number of embryos that developed beyond the four-cell stage. More embryos exposed to EFS20 for 2-3 min developed to morulae (63-64%) and blastocysts (34-38%) than those exposed for 1 min (35 and 10%, respectively). After transfer, 33% of embryos exposed to EFS20 for 3 min and vitrified in EFS40 developed to term compared to 29% of fresh embryos. Fifteen (47%) of live young were homozygous rdw and all of the others were heterozygous rats. The present study demonstrated that vitrification in EFS solution can be routinely used to cryopreserve rat two-cell IVF-embryos with no loss of viability.     

Effects of equilibration time, precooling and developmental stage on the survival of mouse embryos cryopreserved by vitrification

Factorial experiments were carried out to examine the effects of equilibration time, precooling and developmental stage on the postthaw in vitro survival of vitrified mouse embryos. Eight-cell embryos, compacted morulae, or blastocysts were cryopreserved using vitrification Solution 1 (VS1; 10% glycerol + 20% propylene glycol), and vitrification Solution 2 (VS2; 25% glycerol + 25% propylene glycol) in phosphate buffered saline + 10% calf serum. Each embryo stage group was first equilibrated in VS1 for 5, 10 or 20 min and then exposed to either a precooled ( approximately 4 degrees C) or nonprecooled ( approximately 20 degrees C) VS2 in a 0.25-ml straw before they were plunged directly into liquid nitrogen. Results of this study showed an interaction between precooling, equilibration time and developmental stage which affect significantly post-thaw embryo survival (P< 0.05). High survival rates were obtained after 10 min equilibration in VS1 irrespective of the embryo developmental stage. Precooling of the VS2 significantly improved the survival mainly of blastocysts. However, eight-cell and morula-stage embryos also showed high survival rates when they were exposed to precooled VS2 after 5 min equilibration in VS1. It was further observed that morulae usually exhibit high survival rates, and vitrification conditions are more critical for early and advanced stage embryo development.     

Water crystallization within rat precision-cut liver slices in relation to their viability

This study examined whether tissue vitrification, promoted by partitioning within the tissue, could be the mechanism explaining the high viability of rat liver slices, rapidly frozen after preincubation with 18% Me2SO or VS4 (a 7.5 M mixture of Me2SO, 1,2-propanediol, and formamide with weight ratio 21.5:15:2.4). To achieve this, we first determined the extent to which crystallization or vitrification occurred in cryoprotectant solutions (Me2SO and VS4) and within liver slices impregnated with these solutions. Second, we determined how these events were related to survival of slices after thawing. Water crystallization was evaluated by differential scanning calorimetry and viability was determined by histomorphological examination of the slices after culturing at 37 degrees C for 4 h. VS4-preincubated liver slices indeed behaved differently from bulk VS4 solution, because, when vitrified, they had a lower tendency to devitrify. Vitrified VS4-preincubated slices that were warmed sufficiently rapid to prevent devitrification had a high viability. When VS4 was diluted (to 75%) or if warming was not fast enough to prevent ice formation, slices had a low viability. With 45% Me2SO, low viability of cryopreserved slices was caused by cryoprotectant toxicity. Surprisingly, liver slices preincubated with 18% Me2SO or 50% VS4 had a high viability despite the formation of ice within the slice. In conclusion, tissue vitrification provides a mechanism that explains the high viability of VS4-preincubated slices after ultrarapid freezing and thawing (>800 degrees C/min). Slices that are preincubated with moderately concentrated cryoprotectant solutions (18% Me2SO, 50% VS4) and cooled rapidly (100 degrees C/min) survive cryopreservation despite the formation of ice crystals within the slice.     

Cryopreservation of cartilage cell and tissue for biobanking

Preservation of cell and tissue samples from endangered species is a part of biodiversity conservation strategy. Therefore, setting up proper cell and tissue cryopreservation methods is very important as these tissue samples and cells could be used to reintroduce the lost genes into the breeding pool by nuclear transfer. In this study, we investigated the effect of vitrification and slow freezing on cartilage cell and tissue viability for biobanking. Firstly, primary adult cartilage cells (ACCs) and fetal cartilage cells (FCC) were cryopreserved by vitrification and slow freezing. Cells were vitrified after a two-step equilibration in a solution composed of ethylene glycol (EG), Ficoll and sucrose. For slow freezing three different cooling rates (0.5, 1 and 2 °C/min) were tested in straws. Secondly, the tissues taken from articular cartilage were cryopreserved by vitrification and slow freezing (1 °C/min). The results revealed no significant difference between the viability ratios, proliferative activity and GAG synthesis of cartilage cells which were cryopreserved by using vitrification or slow freezing methods. Despite the significant decrease in the viability ratio of freeze–thawed cartilage tissues, cryopreservation did not prevent the establishment of primary cell cultures from cartilage tissues. The results revealed that the vitrification method could be recommended to cryopreserve cartilage tissue and cells from bovine to be used as alternative cell donor sources in nuclear transfer studies for biobanking as a part of biodiversity conservation strategy. Moreover, cartilage cell suspensions were successfully cryopreserved in straws by using a controlled-rate freezing machine in the present study.     

Vitrification of goat preantral follicles enclosed in ovarian tissue by using conventional and solid-surface vitrification methods

Caprine preantral follicles within ovarian fragments were exposed to or vitrified in the presence of sucrose, dimethyl sulfoxide (DMSO), ethylene glycol (EG), or various combinations thereof. The fragments were cryopreserved by using either a conventional (CV) or a solid-surface vitrification (SSV) protocol, and the cryoprotectants were removed by equilibrating vitrified ovarian fragments in “warming solution” consisting of minimum essential medium and heat-inactivated fetal calf serum (MEM⁺) followed by washes in MEM⁺ with or without sucrose. Histological analysis of follicle integrity showed that the percentages of normal follicles in ovarian fragments vitrified in sucrose mixed with EG and/or DMSO (CV method) or mixed with EG or DMSO (SSV method) followed by washes in MEM⁺ plus sucrose were similar to those of controls (ovarian fragments fixed without previous vitrification). Unlike for MEM⁺ (supplemented or unsupplemented by sucrose) and DMSO followed by washes in the absence of sucrose, the percentages of normal follicles found after exposure to cryoprotectant did not significantly differ from that found after vitrification, indicating that follicular degeneration was attributable to a toxic effect of cryoprotectants and not to the vitrification procedure. The viability of preantral follicles after the CV and SSV procedures was investigated by using calcein-AM and the ethidium-homodimer as “live” and “dead” markers, respectively. In both tested vitrification procedures, the highest percentages of viable follicles were observed when a mixture of sucrose and EG (70.3% for CV and 72.4% for SSV) was used. Preantral follicles were also vitrified (either by CV or SSV) in sucrose and EG and then cultured for 24 h, after which their viability was compared with that of cultured fresh and uncultured vitrified follicles. The viability of these follicles was maintained after SSV, but not after CV. Thus, the viability of caprine preantral follicles can be best preserved after SSV in a mixture of sucrose and EG, followed by washes in medium containing sucrose.CAPES/Brazil supported this work. Regiane Rodrigues dos Santos is a recipient of a grant from CAPES/Brazil.     

Vitrification of calf oocytes: effects of maturation stage and prematuration treatment on the nuclear and cytoskeletal components of oocytes and their subsequent development

This study was designed to establish the effects of the meiotic stage of bovine oocytes and of a prematuration treatment with roscovitine (ROS) on their resistance to cryopreservation. Oocytes from prepubertal calves at the stages of germinal vesicle breakdown (GVBD) or at metaphase II (MII) were vitrified by the open pulled straw (OPS) method. In another experiment, oocytes were kept under meiotic arrest with 50 microM ROS for 24 hr and vitrified at the GVBD stage. After warming, some oocyte samples were fixed, stained using specific fluorescent probes and examined under a confocal microscope. The remaining oocytes were fertilized, and cleavage and blastocyst rates recorded. Significantly lower cleavage rates were obtained for the vitrified GVBD and MII oocytes (9.9% and 12.6%, respectively) compared to control oocytes (73.9%). Significantly worse results in terms of cleavage rates were obtained when GVBD calf oocytes were exposed to cryoprotectants (CPAs: ethylene glycol plus dimethyl sulfoxide, DMSO) (13.1%) or vitrified (1.6%) after a prematuration treatment with ROS, when compared to untreated control oocytes (68.7%) or ROS-control oocytes (56.6%). None of the vitrification procedures yielded blastocysts, irrespective of the initial meiotic stage or previous prematuration treatment. Compared to the control oocytes, significantly fewer oocytes exhibited normal spindle configuration after being exposed to CPAs or after vitrification of either GVBD or MII calf oocytes. These results indicate that the vitrification protocol has a deleterious effect on the meiotic spindle organization of calf oocytes cryopreserved at both the GVBD and MII stage, which impairs the capacity for further development of the embryos derived from these vitrified oocytes. Prematuration treatment with ROS has no beneficial effect on the outcome of vitrification by the OPS method.     

Sheep embryo cryopreservation by vitrification and conventional freezing

The survival of ovine embryos (morulae and blastocysts) either frozen by a conventional method or vitrified was investigated in culture. In Experiment I, embryos were vitrified using a solution containing 25% propylene glycol and 25% glycerol. A group of embryos (simulated control) was processed without freezing to evaluate the toxicity of the vitrification solution. In Experiment II, embryos were exposed to a solution of PBS containing 10% glycerol and 0.25 M sucrose placed horizontally in a programmable freezer. Automatic seeding was applied at -7 degrees C in 2 positions on straws and cooled at -0.3 degrees C/min to -25 degrees C and then stored in liquid nitrogen. In vitro development rates of vitrified embryos were 12% (morulae) and 19% (blastocysts). Simulated embryos showed a higher rate of survival than embryos cryopreserved by vitrification (67 and 63%, morulae and blastocysts respectively). In conventional cooling, the blastocysts showed the highest viability percentage (67%) of all the experimental groups but these values decreased significantly in morulae (31%). Differences in temperature between straws placed in distinct positions in the freezing chamber and thermic deviation were observed when automatic seeding was applied. Embryo viability differed from 51 to 75% according the relative position of the embryos within the chamber. Survival was higher when automatic seeding was applied on the meniscus of the embryo column versus the central point of this column (65 vs 21%). The damage of both cryopreservation methods on zona pellucida integrity (27 and 35% in vitrified and conventionally frozen embryos, respectively) had no effect on the in vitro survival.     

Effect of polyvinyl alcohol (PVA) concentration during vitrification of in vitro matured bovine oocytes

Polyvinyl alcohol (PVA) was used as a substitute for serum in a vitrification solution for in vitro matured bovine oocytes. In vitro matured bovine oocytes were cryopreserved in various vitrification solutions (VS) supplemented with different concentrations (0.05, 0.1, 0.5, and 1%) of PVA, 20% fetal calf serum (FCS) or without macromolecule supplementation in a gel-loading tip (GL-tip). After warming, vitrified oocytes were examined for effects on survivability, fertilizability, and embryonic development in vitro. At 18 h in vitro fertilization after vitrifying and warming, the number of surviving mature oocytes vitrified in VS without macromolecule supplementation was significantly (P < 0.05) lower than those with macromolecule supplementation. For fertilizability after vitrification, there was no significant difference in the penetration rate of oocytes among fresh oocytes (98.7%); oocytes vitrified in VS supplemented with 0.1 (76.8%), 0.5 (70.2%), or 1% (80.3%) PVA; 20% (84.1%) FCS; or without supplementation (61.7%). Also, the normal fertilization rate was not significantly different in oocytes vitrified with 0.1 (56.5%), 0.5 (43.5%), or 1% (49.7%) PVA and 20% (60.6%) FCS, compared with fresh oocytes (84.0%). Subsequently, vitrified oocytes were examined for embryonic development effects in vitro. The highest proportion of cleaved oocytes after vitrification was obtained in VS supplemented with 0.1% (18.8%) PVA. Additionally, the proportion of development to morula stage (7.7%) in the oocytes vitrified in a VS supplemented with 0.1% PVA was significantly (P < 0.05) superior to that of the 0, 0.5, and 1% PVA-vitrified groups. However, the beneficial effect of PVA addition was not found in blastocyst development. Embryonic development of vitrified oocytes was significantly lower than that of fresh oocytes. In conclusion, the present results indicate that 0.1% PVA supplementation in VS results in a significantly higher rate of morula stage embryos than 0, 0.5, and 1% PVA supplementation, and could replace FCS in VS for vitrification of in vitro matured bovine oocytes.