Visualization of intracellular ice crystals formed in very rapidly frozen cells at −27 °C

Tumor cells of an ascites sarcoma of rat were primarily frozen very rapidly with the original host ascitic fluid at ?27 °C by the spraying method. Frozen specimens were fractured and replicated at about ?100 °C under vacuum by a special spray-sandwich method for freeze-etching, and the morphological appearance of ice crystals formed in and around the frozen cells were observed by electron microscopy.The cells cooled very rapidly at ?27 °C actually froze intracellularly, and intracellular ice crystals ranged from 0.03 to 0.5 μm in grain size due to the initial freezing rate of the specimens. In the cells having granulous intracellular ice crystals less than 0.05 μm in grain size, cytoplasmic organelles seemed to maintain their original structures.We suggested in our previous report that these tumor cells, frozen very rapidly at temperatures above ?30 °C, survived intracellular freezing as long as they remained translucent, and optically no ice crystals appeared within them, as seen in intact unfrozen cells. It may therefore be concluded that the tumor cells frozen very rapidly at temperatures near ?30 °C actually freeze intracellularly and probably maintain their viability as long as the size of individual intracellular ice-crystals is kept smaller than 0.05 μm, although the exact critical size of innocuous intracellular ice crystals is uncertain.     

Effects of freezing on membranes and proteins in LNCaP prostate tumor cells

Fourier transform infrared spectroscopy (FTIR) and cryomicroscopy were used to define the process of cellular injury during freezing in LNCaP prostate tumor cells, at the molecular level. Cell pellets were monitored during cooling at 2 °C/min while the ice nucleation temperature was varied between − 3 and − 10 °C. We show that the cells tend to dehydrate precipitously after nucleation unless intracellular ice formation occurs. The predicted incidence of intracellular ice formation rapidly increases at ice nucleation temperatures below − 4 °C and cell survival exhibits an optimum at a nucleation temperature of − 6 °C. The ice nucleation temperature was found to have a great effect on the membrane phase behavior of the cells. The onset of the liquid crystalline to gel phase transition coincided with the ice nucleation temperature. In addition, nucleation at − 3 °C resulted in a much more co-operative phase transition and a concomitantly lower residual conformational disorder of the membranes in the frozen state compared to samples that nucleated at − 10 °C. These observations were explained by the effect of the nucleation temperature on the extent of cellular dehydration and intracellular ice formation. Amide-III band analysis revealed that proteins are relatively stable during freezing and that heat-induced protein denaturation coincides with an abrupt decrease in α-helical structures and a concomitant increase in β-sheet structures starting at an onset temperature of approximately 48 °C.     

Cryopreservation of Unfertilized Mouse Oocytes: The Effect of Replacing Sodium with Choline in the Freezing Medium

Although embryo cryopreservation has become commonplace in many species, effective methods are not available for routine freezing of unfertilized eggs. Cryopreservation-induced damage may be caused by the high concentration of sodium ions in conventional freezing media. This study investigates the effect of a newly developed low-sodium choline-based medium (CJ2) on the ability of unfertilized, metaphase II mouse eggs to survive cryopreservation and develop to the blastocyst stagein vitro.Specifically, the effects of cooling to subzero temperatures, thawing rate, LN₂plunge temperature, and equilibration with a low-sodium medium prior to freezing are examined. In contrast to cooling to 23, 0, or −7.0°C in a sodium-based freezing medium (ETFM), cooling in CJ2 had no significant negative effect on oocyte survival or development. Oocytes frozen in CJ2 survived plunging into LN₂from −10, −20, or −33°C at significantly higher rates than oocytes frozen in ETFM. With the protocol used (1.5 M PrOH, 0.1 M sucrose, −0.3 C/min, plunging at −33°C) rapid thawing by direct submersion in 30°C water was more detrimental to oocyte survival than holding in air for 30 or 120 s prior to transfer to water. Equilibration of unfertilized oocytes with a low-sodium medium prior to cryopreservation in CJ2 significantly increased survival and blastocyst development. These results demonstrate that the high concentration of sodium in conventional freezing media is detrimental to oocyte cryopreservation and show that choline is a promising replacement. Reducing the sodium content of the freezing medium to a very low level or eliminating sodium altogether may allow oocytes and other cells to be frozen more effectively.     

Survival of Pacific oyster, Crassostrea gigas, oocytes in relation to intracellular ice formation

The effect of IIF in Pacific oyster oocytes was studied using cryo and transmission electron microscopy (TEM). The viability of oocytes at each step of a published cryopreservation protocol was assessed in an initial experiment. Two major viability losses were identified; one when oocytes were cooled to −35 °C and the other when oocytes were plunged in liquid nitrogen. Although the cryomicroscope showed no evidence of IIF in oocytes cooled with this protocol, TEM revealed that these oocytes contained ice crystals and were at two developmental stages when frozen, prophase and metaphase I. To reduce IIF, the effect of seven cooling programmes involving cooling to −35 or −60 °C at 0.1 or 0.3 °C min⁻¹ and holding for 0 or 30 min at −35 or −60 °C was evaluated on post-thaw fertilization rate of oocytes. Regardless of the cooling rate or holding time, the fertilization rate of oocytes cooled to −60 °C was significantly lower than that of oocytes cooled to −35 °C. The overall results indicated that observations of IIF obtained from cryomicroscopy are limited to detection of larger amounts of ice within the cells. Although the amount of cellular ice may have been reduced by one of the programmes, fertilization was reduced significantly; suggesting that there is no correlation between the presence of intracellular ice and post-thaw fertilization rate. Therefore, oyster oocytes may be more susceptible to the effect of high solute concentrations and cell shrinkage than intracellular ice under the studied conditions.     

Cooling rate optimization for zebrafish sperm cryopreservation using a cryomicroscope coupled with SYBR14/PI dual staining

The Zebrafish has gained increased popularity as an aquatic model species in various research fields, and its widespread use has led to numerous mutant strains and transgenic lines. This creates the need to store these important genetic materials as frozen gametes. Sperm cryopreservation in zebrafish has been shown to yield very low post-thaw survival and many protocols suffer from great variability and poor reproducibility. The present study was intended to develop a freezing protocol that can be reliably used to cryopreserve zebrafish sperm with high post-thaw survival. In particular, our study focused on cooling protocol optimization with the aid of cryomicroscopy. Specifically, sperm suspended in 8% DMSO or 4% MeOH were first incubated with live/dead fluorescent dyes (SYBR14/PI) and then cooled at various rates from 4 °C to different intermediate stopping temperatures such as −10, −20, −30 and −80 °C before rewarming to 35 °C at the rate of 100 °C/min. %PI-positive (dead) cells were monitored throughout the cooling process and this screening yielded an optimal rate of 25 °C/min for this initial phase of freezing. We then tested the optimal cooling rate for the second phase of freezing from various intermediate stopping temperatures to −80 °C before plunging into liquid nitrogen. Our finding yielded an optimal intermediate stopping temperature of −30 °C and an optimal rate of 5 °C/min for this second phase of freezing. When we further applied this two-step cooling protocol to the conventional controlled-rate freezer, the average post-thaw motility measured by CASA was 46.8 ± 6.40% across 11 males, indicating high post-thaw survival and consistent results among different individuals. Our study indicates that cryomiscroscopy is a powerful tool to devise the optimal cooling conditions for species with sperm that are very sensitive to cryodamage.     

Intracellular ice formation and growth in MCF-7 cancer cells

Direct cell injury in cryosurgery is highly related to intracellular ice formation (IIF) during tissue freezing and thawing. Mechanistic understanding of IIF in tumor cells is critical to the development of tumor cryo-ablation protocol. In aid of a high speed CMOS camera system, the events of IIF in MCF-7 cells have been studied using cryomicroscopy. Images of ‘darkening’ type IIF and recrystallization are compared between cells frozen with and without ice seeding. It is found that ice seeding has significant impact on the occurrence and growth of intracellular ice. Without ice seeding, IIF is observed to occur over a very small range of temperature (∼1 °C). The crystal dendrites are indistinguishable, which is independent of the cooling rate. Ice crystal grows much faster and covers the whole intracellular space in comparison to that with ice seeding, which ice stops growing near the cellular nucleus. Recrystallization is observed at the temperature from −13 °C to −9 °C during thawing. On the contrary, IIF occurs from −7 °C to −20 °C with ice seeding at a high subzero temperature (i.e., −2.5 °C). The morphology of intracellular ice frozen is greatly affected by the cooling rate, and no ‘darkening’ type ice formed inside cells during thawing. In addition, the intracellular ice formation is directional, which starts from the plasma membrane and grows toward the cellular nucleus with or without ice seeding. These results can be used to explain some findings of tumor cryosurgery in vivo, especially the causes of insufficient killing of tumor cells in the peripheral area near vessels.     

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.     

Blastocysts cloned from the Putian Black pig ear tissues frozen without cryoprotectant at -80 and -196 degrees Celsius for 3 yrs

The Putian Black pig, as one of elite cultivars of endemic species in China, has been on the verge of extinction and urgently needs protection. Somatic cell nuclear transfer (SCNT) and noncryoprotected frozen tissue technology have successfully resurrected several mammalian species. Therefore, this study explored the primary feasibility of conserving this breed using a combination of both technologies. Skin tissues obtained from the ears of adult Putian Black boars were frozen without cryoprotectant at −20, −80, or −196 °C and stored for 3 yrs. Primary cell culture, passage and subculture were performed on frozen samples after being rapidly thawed at 39 °C and on fresh pig ear tissues (control). Cloned embryos were reconstructed using fibroblasts (from frozen and fresh tissues) with enucleated oocytes. Live cell lines were obtained from tissues frozen at −80 and at −196 °C and appeared to have normal proliferative activity after passage; furthermore, they directed cloned embryos to develop to the blastocyst stage after nuclear transfer. We concluded that the population of Putian Black pig might be increased in the future by transferring cloned blastocysts into synchronized recipient pigs.     

Transmembrane ion distribution during recovery from freezing in the woolly bear caterpillar Pyrrharctia isabella (Lepidoptera: Arctiidae)

During extracellular freezing, solutes in the haemolymph are concentrated, resulting in osmotic dehydration of the cells, which must be reversed upon thawing. Here, we used freeze tolerant Pyrrharctia isabella (Lepidoptera: Arctiidae) larvae to examine the processes of ion redistribution after thawing. To investigate the effect of the intensity of cold exposure on ion redistribution after thawing, we exposed caterpillars to −14 °C, −20 °C or −30 °C for 35 h. To investigate the effect of duration of cold exposure on ion redistribution after thawing, we exposed the caterpillars to −14 °C for up to 6 weeks while sampling several time points. The concentrations of Na⁺, K⁺, Mg²⁺ and Ca²⁺ were measured after thawing in the haemolymph, fat body, muscle, midgut tissue and hindgut tissue. Being frozen for long durations (>3 weeks) or at low temperatures (−30 °C) both result in 100% mortality, although different ions and tissues appear to be affected by each treatment. Both water distribution and ion content changes were detected after thawing, with the largest effects seen in the fat body and midgut tissue. Magnesium homeostasis appears to be vital for post-freeze survival in these larvae. The movement of ions during thawing lagged behind the movement of water, and ion homeostasis was not restored within the same time frame as water homeostasis. Failure to regain ion homeostasis after thawing is therefore implicated in mortality of freeze tolerant insects.     

Freeze tolerance and accumulation of cryoprotectants in the enchytraeid Enchytraeus albidus (Oligochaeta) from Greenland and Europe

The freeze tolerance and accumulation of cryoprotectants was investigated in three geographically different populations of the enchytraeid Enchytraeus albidus (Oligochaeta). E. albidus is widely distributed from the high Arctic to temperate Western Europe. Our results show that E. albidus is freeze tolerant, with freeze tolerance varying extensively between Greenlandic and European populations. Two populations from sub Arctic (Nuuk) and high Arctic Greenland (Zackenberg) survived freezing at −15 °C, whereas only 30% of a German population survived this temperature. When frozen, E. albidus responded by catabolising glycogen to glucose, which likely acted as a cryoprotectant. The average glucose concentrations were similar in the three populations when worms were frozen at −2 °C, approximately 50 μg glucose mg⁻¹ tissue dry weight (DW). At −14 °C the glucose concentrations increased to between 110 and 170 μg mg⁻¹ DW in worms from Greenland. The average glycogen content of worms from Zackenberg and Nuuk were about 300 μg mg⁻¹ DW, but only 230 μg mg⁻¹ DW in worms from Germany showing that not all glycogen was catabolised during the experiment. Nuclear magnetic resonance spectrometry (NMR) was used to screen for other putative cryoprotectants. Proline, glutamine and alanine were up regulated in frozen worms at −2 °C but only in relatively small concentrations suggesting that they were of little significance for freeze survival. The present study confirms earlier reports that freeze tolerant enchytraeids, like other freeze tolerant oligochaete earthworms, accumulate high concentrations of glucose as a primary cryoprotectant.     

Viability of fastidious Phytophthora following different cryopreservation treatments

Living stock cultures with constant phenotypes and genotypes are required for a wide range of research and industrial applications; however, long-term, stable preservation of fastidious Phytophthora strains has been challenging. In this study, we systematically evaluated different cryopreservation treatments to identify and clarify freezing, thawing, and other conditions appropriate for long-term maintenance. Optimal preservation conditions were largely strain-specific, with robust strains remaining fully viable and the fastidious yielding lower recovery under all test conditions. Nevertheless, several procedures were shown to be generally applicable for effective cryopreservation of most Phytophthora organisms. Fastidious strains retained higher viability following the −1 °C min⁻¹ freezing protocol (Mr Frosty's) than either of two widely used programmed freezing procedures. Revival was higher when frozen mycelium plugs were thawed at 37 °C for 2 min or 25 °C for 5 min, while lower viability was apparent for fastidious strains thawed at 55 °C for 1.5 min. Among 15 cryoprotective solutions assessed, 5 % dimethyl sulfoxide produced the highest viability for all fastidious strains. The effect of prefreeze and postfreeze treatments on revival was mild, if any, and strain-dependent. This study has generated reliable, practical, long-term preservation solutions applicable to a majority of Phytophthora species. It also has revealed a need for in-depth physiological and morphological investigations to further enhance the preservation methods for fastidious strains.     

Cryopreservation of buffy-coat-derived platelet concentrates in dimethyl sulfoxide and platelet additive solution

Platelets prepared in plasma can be frozen in 6% dimethyl sulfoxide (Me₂SO) and stored for extended periods at −80 °C. The aim of this study was to reduce the plasma present in the cryopreserved product, by substituting plasma with platelet additive solution (PAS; SSP+), whilst maintaining in vitro platelet quality. Buffy coat-derived pooled leukoreduced platelet concentrates were frozen in a mixture of SSP+, plasma and 6% Me₂SO. The platelets were concentrated, to avoid post-thaw washing, and frozen at −80 °C. The cryopreserved platelet units (n = 9) were rapidly thawed at 37 °C, reconstituted in 50% SSP+/plasma and stored at 22 °C. Platelet recovery and quality were examined 1 and 24 h post-thaw and compared to the pre-freeze samples. Upon thawing, platelet recovery ranged from 60% to 80%. However, there were differences between frozen and liquid-stored platelets, including a reduction in aggregation in response to ADP and collagen; increased CD62P expression; decreased viability; increased apoptosis and some loss of mitochondrial membrane integrity. Some recovery of these parameters was detected at 24 h post-thaw, indicating an extended shelf-life may be possible. The data suggests that freezing platelets in 6% Me₂SO and additive solution produces acceptable in vitro platelet quality.     

Studies on Rapidly Frozen Suspensions of Yeast Cells by Differential Thermal Analysis and Conductometry

Few, if any, yeast cells survived rapid cooling to -196°C and subsequent slow warming. After rapid freezing, the suspensions absorbed latent heat of fusion between -15° and 0°C during warming, and the relation between the amount of heat absorbed and the concentration of cells was the same as that in equivalent KCl solutions, indicating that frozen suspensions behave thermally like frozen solutions. The amount of heat absorbed was such that more than 80 per cent of the intracellular solution had to be frozen. The conductometric behavior of frozen suspensions showed that cell solutes were still inside the cells and surrounded by an intact cell membrane at the time heat was being absorbed. Two models are consistent with these findings. The first assumes that intracellular freezing has taken place; the second that all freezable water has left the cells and frozen externally. The latter model is ruled out because rapidly cooled cells do not shrink by an amount equal to the volume of water that would have to be withdrawn to prevent internal freezing.     

A cell-free approach to the study of membrane trafficking in frozen rat brains potentially applicable to frozen autopsy material

Summary A cell-free transfer system was used to measure capacity of brain membranes to support membrane renewal. To study transfer in brain, radiolabeled donor microsome fractions were prepared using brain slices from rats or frozen human brain autopsy specimens. Acceptor fractions, prepared from fresh or frozen rat brain or frozen human brain autopsy specimens, were immobilized on nitrocellulose. The complete reconstituted transfer system contained ATP plus ATP-regenerating system (or NADH) as a source of energy and brain cytosol. Slices of frozen brain incorporated acetate into membrane lipids with approximately the same efficiency as fresh brains. This efficiency declined with storage at 4 °C but only slowly. Donor fractions labeled with acetate from frozen slices exhibited specific transfer (37 °C minus 4 °C) of labeled membrane lipids with efficiencies comparable to fresh. The acceptor fraction could be prepared either from fresh or frozen material. Transfer was on the average two-fold stimulated by ATP at 37 °C compared to no ATP. Transfer also was stimulated by NADH. Analysis of linear transfer rates between 0 and 30 min revealed no significant effect of delay time or of time of prolonged storage on transfer efficiency beyond an initial decline of ca. 25% observed within the first two weeks after freezing. A decline of transfer was obtained with brains as the animals aged.     

Loading process of sugars into cabbage petiole and asparagus shoot apex cells by incubation with hypertonic sugar solutions

Summary The freezing tolerance of cabbage petioles and asparagus shoot apexes was increased by preincubation with 0.8 M sugar solutions. In cabbage petioles with an initial freezing tolerance of –3 °C (temperature for 50% cell survival), as determined by both electrolyte leakage and fluorescein diacetate vital staining, the freezing tolerance was increased to –13 °C by incubation with sorbitol solutions for 3 h. In meristematic cells of asparagus shoot apexes with an initial freezing tolerance of –7.5 °C, as determined by fluorescein diacetate vital staining, the freezing tolerance was increased to –30 °C by incubation with 0.8 M sugar solutions for 3 h, although other cells in the shoot apexes were killed by higher freezing temperatures. During incubation of both cabbage petioles and asparagus shoot apexes with sugar solutions, sugars were intracellularly taken up by osmotically induced fluid-phase endocytotic vesicles, as indicated by comovement of Lucifer Yellows carbohydrazide (LYCH) observed with a confocal laser scanning microscope. The amounts of intracellularly taken up sugars increased concomitantly with the formation of endocytotic vesicles depending on the time of incubation in parallel with a gradual increase of freezing tolerance. However, the endocytotic vesicles and their contents were retained not only after prolonged incubation after maximum freezing tolerance had been achieved but also after recovery of these tissue cells to isotonic conditions or after freeze-thawing. These results suggest that although sugars are intracellularly taken up by endocytotic vesicles, they might be sequestered within vesicles, casting doubt on their protective role to the plasma membranes as a main site of freezing injury. The pretreatment with 1 mMp-chloromercuribenzenesulfonic acid (PCMBS), an inhibitor of sugar transport, reduced the amounts of intracellular sugar uptake without affecting the formation of endocytotic vesicles, suggesting that sugars were, at least partly, taken up by sugar transporters. In the pretreatment with PCMBS, the freezing tolerance of incubated tissues with sugar solutions was significantly reduced, although addition of PCMBS per se did not affect survival. These results suggest that sugars taken up by sugar transporters, rather than sugars taken up by endocytotic vesicles, are mainly responsible for the increased freezing tolerance of cabbage petioles and asparagus shoot apexes. Furthermore, we aimed to study the occurrence of fluid-phase endocytosis with LYCH in an isotonic condition. Our results indicated that uptake of LYCH by fluid-phase endocytotic vesicles was not detected microscopically in isotonic condition, although LYCH was spectrofluorimetrically taken up in isotonic condition. Spectrofluorimetric uptake of LYCH was inhibited by addition of probenecid, an anion transport inhibitor. These results suggest that in cabbage petioles and asparagus shoot apexes, LYCH is taken up by anion transport but not by fluid-phase endocytosis in isotonic condition, and uptake of LYCH by fluid-phase endocytosis is restricted to occur only in hypertonic condition.Abbreviations CLSM confocal laser scanning microscope - FDA fluorescein diacetate - LYCH Lucifer Yellow carbohydrazide - PCMSB p-chloromercuribenzenesulfonic acid - T_EL50 temperature at which 50% electrolyte leakage occurred     

Cryopreservation of Greenshell™ mussel (Perna canaliculus) trochophore larvae

The Greenshell™ mussel (Perna canaliculus) is the main shellfish species farmed in New Zealand. The aim of this study was to evaluate the effects of cryoprotectant concentration, loading and unloading strategy as well as freezing and thawing method in order to develop a protocol for cryopreservation of trochophore larvae (16–20 h old). Toxicity tests showed that levels of 10–15% ethylene glycol (EG) were not toxic to larvae and could be loaded and unloaded in a single step. Through cryopreservation experiments, we designed a cryopreservation protocol that enabled 40–60% of trochophores to develop to D-larvae when normalized to controls. The protocol involved: holding at 0 °C for 5 min, then cooling at 1 °C min⁻¹ to −10 °C, holding for a further 5 min, then cooling at 0.5 °C min⁻¹ to −35 °C followed by a 5 min hold and then plunging into liquid nitrogen. A final larval rearing experiment of 18 days was conducted to assess the ability of these frozen larvae to develop further. Results showed that only 2.8% of the frozen trochophores were able to develop to competent pediveligers.     

Comparison between the temperatures of intracellular ice formation in fresh mouse oocytes and embryos and those previously subjected to a vitrification procedure

When cells that have been subjected to supposedly innocuous freezing or vitrification procedures are used as the source material for subsequent experiments, it is important that they possess or exhibit the same relevant properties as fresh cells. In this study, we compared the temperatures of intracellular ice formation (IIF) in previously vitrified mouse oocytes/embryos with those in fresh intact ones. In the case of MII oocytes, 2-cell embryos, 4-6-cell embryos, and morulae, there are no significant differences (p > 0.05); namely, -33.3 °C (fresh) vs. -35.4 °C (vitrified) with MII oocytes, -40.6 °C (fresh) vs. -38.7 °C (vitrified) with 2-cell embryos, -38.0 °C (fresh) vs. -39.4 °C (vitrified) with 4-6-cell embryos, -24.5 °C (fresh) vs. -24.2 °C (vitrified) with morulae. But, in 8-cell embryos, there is a significant difference (p < 0.05) between fresh (−37.9 °C) and vitrified (−32.9 °C). If we include this significant difference, the overall IIF temperature of fresh cells is 0.74 °C lower than that of previously vitrified cells. If we exclude it, the IIF temperature for fresh cells is 0.32 °C higher than that for previously vitrified cells. Our conclusion then is that there is no difference between the IIF temperatures of fresh and previously vitrified cells.     

Cryopreservation of sea urchin embryos (Paracentrotus lividus) applied to marine ecotoxicological studies

Current strategies for marine pollution monitoring are based on the integration of chemical and biological techniques. The sea urchin embryo-larval bioassays are among the biological methods most widely used worldwide. Cryopreservation of early embryos of sea urchins could provide a useful tool to overcome one of the main limitations of such bioassays, the availability of high quality biological material all year round. The present study aimed to determine the suitability of several permeant (dimethyl sulfoxide, Me₂SO; propylene glycol, PG; and ethylene glycol, EG) and non-permeant (trehalose, TRE; polyvinylpyrrolidone, PVP) cryoprotectant agents (CPAs) and their combination, for the cryopreservation of eggs and embryos of the sea urchin Paracentrotus lividus. On the basis of the CPAs toxicity, PG and EG, in combination with PVP, seem to be most suitable for the cryopreservation of P. lividus eggs and embryos. Several freezing procedures were also assayed. The most successful freezing regime consisted on cooling from 4 to −12 °C at 1 °C/min, holding for 2 min for seeding, cooling to −20 °C at 0.5 °C/min, and then cooling to −35 °C at 1 °C/min. Maximum normal larvae percentages of 41.5% and 68.5%, and maximum larval growth values of 42.9% and 60.5%, were obtained for frozen fertilized eggs and frozen blastulae, respectively.     

Development of a novel methodology for cryopreservation of melanoma cells applied to CSF470 therapeutic vaccine

CSF470 vaccine is a mixture of four lethally irradiated melanoma cell lines, administered with BCG and GM-CSF, which is currently being tested in a Phase II/III Clinical trial in stage II/III melanoma patients. To prepare vaccine doses, irradiated melanoma cell lines are frozen using dimethyl sulfoxide (Me₂SO) and stored in liquid nitrogen (liqN₂). Prior to inoculation, doses must be thawed, washed to remove Me₂SO and suspended for clinical administration. Avoiding the use of Me₂SO and storage in liqN₂ would allow future freeze-drying of CSF470 vaccine to facilitate pharmaceutical production and distribution. We worked on the development of an alternative cryopreservation methodology while keeping the vaccine’s biological and immunogenic properties. We tested different freezing media containing trehalose suitable to remain as excipients in a freeze-dried product, to cryopreserve melanoma cells either before or after gamma irradiation. Melanoma cells incorporated trehalose after 5 h incubation at 37 °C by fluid-phase endocytosis, reaching an intracellular concentration that varied between 70–140 mM depending on the cell line. Optimal freezing conditions were 0.2 M trehalose and 30 mg/ml human serum albumin, at −84 °C. Vaccine doses could be frozen in trehalose at −84 °C for at least four months keeping their cellular integrity, antigen expression and apoptosis/necrosis profile after gamma-irradiation as compared to Me₂SO control. Non-irradiated melanoma cell lines also showed comparable proliferative capacity after both cryopreservation procedures. Trehalose-freezing medium allowed us to cryopreserve melanoma cells, either alive or after gamma irradiation, at −84 °C avoiding the use of Me₂SO and liqN₂ storage. These cryopreservation conditions could be suitable for future freeze-drying of CSF470 vaccine.     

A fine-structural study of the freeze-preservation of plant tissue cultures

Summary Suspension culture cells of sycamore (Acer pseudoplatanus L.) and carrot (Daucus carota L.) were frozen to ultralow temperatures under rapid ( 100 °C s^–1) and slow, controlled (1 or 2 °C min^–1) rates, in the presence and absence of cryoprotective compounds. After storage at –196 °C, cells were recovered by thawing either slowly, in air at room temperature (ca. 20 °C min^–1) or rapidly, in a water bath at 40 °C (ca. 100 °C min^–1). The ultrastructure of the thawed cells was examined by thin-sectioning and compared with unfrozen controls and cells examined in the frozen state. Cells frozen rapidly, in the presence of cryoprotectants, or frozen slowly in their absence, suffered serious ultrastructural damage and a total loss of viability. Carrot cells frozen at a rate of 2 °C min^–1 in the presence of cryoprotectants and thawed at either rate, yielded up to 70% of viable cells. The recovered aggregates of carrot cells comprised some centrally located, seriously damaged cells and, at the periphery, groups of cells with a high electron opacity neighbouring well preserved cells, showing little ultrastructural modification compared with unfrozen controls. The highest rate of survival of sycamore cells (ca. 30%) was observed when they were frozen at a rate of 1 °C min^–1 and thawed rapidly. In all recoverd cells of sycamore some ultrastructural modifications were evident. These included: dilation of mitochondria, plastids, golgi and ER cisternae and the nuclear envelope, decrease in polysomes, increase in nuclear and cytoplasmic microfilaments and changes in nuclear and nucleolar granularity. The probable causes and timing of the ultrastructural changes and their effects on the potential for regrowth of the recovered cells are discussed.