Biochemical functionality and recovery of hepatocytes after deep freezing storage

Summary The present study was undertaken to define the conditions for optimal cryopreservation of hepatocytes. Two different freezing procedures were analyzed: a slow freezing rate (SFR) (−2° C/min down to −30°C and then quick freezing to −196° C) and a fast freezing rate (FFR) (direct freezing of tubes to −196° C: −39° C/min). Cells were frozen in fetal bovine serum containing 10% Dimethyl sulfoxide (DMSO). After rapid thawing at 37° C, followed by dilution and removal of the cryoprotectant, cells were plated and several parameters were followed as criteria for optimal cryopreservation of cells. The FFR cells showed no apparent ultrastructural damage after 24 h of culture. Plating efficiency and spreading were similar as controls. Gluconeogenesis from pyruvate and fructose, tyrosine amino transferase induction by glucagon and dexamethasone, urea production, and plasma protein synthesis of FFR cells were similar to those found in control cultures. The FFR procedure, in comparison to the SFR method, seemed to render the best preserved hepatocytes. The financial support for this work was from Fondo de Investigaciones Sanitarias de la Seguridad Social, Grants 41/82 and 48/82.     

Intracellular ice formation during the freezing of hepatocytes cultured in a double collagen gel.

During freezing, intracellular ice formation (IIF) has been correlated with loss in viability for a wide variety of biological systems. Hence, determination of IIF characteristics is essential in the development of an efficient methodology for cryopreservation. In this study, IIF characteristics of hepatocytes cultured in a collagen matrix were determined using cryomicroscopy. Four factors influenced the IIF behavior of the hepatocytes in the matrix: cooling rate, final cooling temperature, concentration of Me2SO, and time in culture prior to freezing. The maximum cumulative fraction of cells with IIF increased with increasing cooling rate. For cultured cells frozen in Dulbecco's modified Eagle's medium (DMEM), the cooling rate for which 50% of the cells formed ice (B50) was 70 degrees C/min for cells frozen after 1 day in culture and decreased to 15 degrees C/min for cells frozen after 7 days in culture. When cells were frozen in a 0.5 M Me2SO + DMEM solution, the value of B50 decreased from 70 to 50 degrees C/min for cells in culture for 1 day and from 15 to 10 degrees C/min for cells in culture for 7 days. The value of the average temperature for IIF (TIIF) for cultured cells was only slightly depressed by the addition of Me2SO when compared to the IIF behavior of other cell types. The results of this study indicate that the presence of the collagen matrix alters significantly the IIF characteristics of hepatocytes. Thus freezing studies using hepatocytes in suspension are not useful in predicting the freezing behavior of hepatocytes cultured in a collagen matrix. Furthermore, the weak effect of Me2SO on IIF characteristics implies that lower concentrations of Me2SO (0.5 M) may be just as effective in preserving viability. Finally, the value of B50 measured in this study indicates that cooling rates nearly an order of magnitude faster than those previously investigated could be used for cryopreservation of the hepatocytes in a collagen gel.     

The cryobiology of rat and human dendritic cells: preservation and destruction of membrane integrity by freezing

Dendritic cells (DCs) are now regarded as specialized leucocytes with distinctive morphological and functional characteristics as accessory or stimulator cells for many lymphocyte responses. While knowledge of the response of other leucocytes (e.g., lymphocytes, macrophages, and granulocytes) to freezing and thawing has been established for some years, an understanding of the cryobiological properties of DCs has not, hitherto, been determined specifically. Such information is important both for establishing procedures for the long-term storage of these cells for use in immunological procedures and for defining freezing conditions that might selectively kill DCs in attempts to modulate the immunogenicity of transplantable tissues during cryopreservation. Preparations of rat and human spleen cells enriched for DCs were frozen to -60 degrees C at one of six cooling rates (0.3, 1.5, 10, 20, 70, or 150 degrees C/min) using a procedure that was established for pancreatic islets with 2 M dimethyl sulfoxide (Me2SO) as the cryoprotectant. Following storage at -196 degrees C the survival of thawed cells was assessed by evaluating both the numbers of cells recovered after the complete process and the membrane integrity of the recovered cells using a supravital fluorescent probe assay. Survival profiles for DCs showed a dependence upon cooling rate similar to other lymphoid cells but DCs were more sensitive to freezing injury than either lymphocytes or macrophages: Optimum survival (75% recovery of numbers and 57% membrane integrity) of rat DCs was achieved by slow cooling (0.3 degrees C/min). Optimal recovery of human DCs was significantly higher (83% recovery of numbers and 72% membrane integrity) after cooling at either 0.3 or 1.5 degrees C/min. The viable yield of DCs from both species declined abruptly as cooling rate was increased, with less than 10% survival after cooling at 20 degrees C/min and negligible survival after cooling at 70 degrees C/min or greater. Analysis of variance of the survival data showed that the response of DCs to freezing and thawing was significantly different (P less than 0.005) from that of either lymphocytes or macrophages, thus providing additional evidence that DCs are distinct from other leucocytes, especially macrophages. This study defines conditions that either will provide effective cryopreservation of DCs for immunological purposes or are most likely to bring about their inactivation in cryobiological approaches to modulating tissue immunogenicity.     

Cryopreservation of seabream (Sparus aurata) spermatozoa

The aim of this research was to optimize protocols for freezing spermatozoa of seabream (Sparus aurata). All the phases of the cryopreservation procedure (sampling, choosing the cryoprotective extender, cooling, freezing, and thawing) were studied in relation to the species of spermatozoa under examination, so as to be able to restore on thawing the morphological and physiological characteristics of fresh semen. Seabream spermatozoa were collected by stripping and transported to the laboratory chilled (0-2 degrees C). Five cryoprotectants, dimethyl sulfoxide (Me(2)SO), ethylene glycol (EG), 1,2-propylene glycol (PG), glycerol, and methanol, were tested at concentrations between 5 and 15% by volume to evaluate their effect on the motility of semen exposed for up to 30 min at 26 degrees C. The less toxic cryoprotectants, 10% EG, 10% PG, and 5% Me(2)SO, respectively, were added to 1% NaCl to formulate the extenders for freezing. The semen was diluted 1:6 with the extender, inserted into 0.25-ml plastic straws by Pasteur pipette, and frozen using a cooling rate of either 10 or 15 degrees C/min to -150 degrees C followed by transfer and storage in liquid nitrogen (-196 degrees C). The straws were thawed at 15 degrees C/s. On thawing, the best motility was obtained with 5% Me(2)SO, although both 10% PG and EG showed good results; no differences were found between the two freezing gradients, although semen frozen with the 10 degrees C/min gradient showed a slightly higher and more prolonged motility.     

Cryopreservation of yellowfin seabream (Acanthopagrus latus) spermatozoa (Teleost, Perciformes, Sparidae)

The effects of both osmolality and cation in the initiation of sperm motility were examined in yellowfin seabream, Acanthopagrus latus. Various factors involved in the cryopreservation of yellowfin seabream spermatozoa on motility are discussed. Extender containing only glucose proved to be a suitable medium for freezing yellowfin seabream spermatozoa to -196 degrees C. Glycerol seems to have a direct osmotic effect on yellowfin seabream sperm cells, and it induced sperm motility before freezing and during thawing. However, this exhausted the energy needed for sperm motility for fertilization. Dimethyl sulfoxide (DMSO) proved superior to ethylene glycerol, propylene glycerol, glycerol and methanol as a cryoprotectant. Prolonged equilibration time had a detrimental effect on both prefreezing and post-thawing sperm motility. The estimated optimum freezing rate was in the range of -20 to -154 degrees C/min. More frozen-thawed than fresh spermatozoa are required to achieve comparable fertilization rates.     

Development of a simple sperm cryopreservation model using a chemically defined medium and goat cauda epididymal spermatozoa

This investigation was carried out to develop a simple sperm cryopreservation model using a chemically defined synthetic medium (modified Ringer's solution) and mature goat cauda epididymal sperm as the model system. Rates of cooling, freezing, and maximum freezing temperature were manipulated with the help of a computer-controlled programmable biofreezer. Highly motile goat cauda sperm dispersed in a modified Ringer's solution was subjected to the freezing protocol: cooling 0.25 degrees C min(-1) to 5 degrees C, 5 degrees C min (-1) to -20 degrees C, 20 degrees C min(-1) to -100 degrees C, prior to plunging into liquid nitrogen. In the absence of any cryoprotective agent, all of the spermatozoa lost their motility. Addition of glycerol (0.22 to 0.87 M) caused a dose-dependent increase of sperm motility recovery. The highest recovery of forward and total motility was (32 and 35%, respectively) at 0.87 M. Further increase of the glycerol concentration caused a marked decrease in motility. Changes in the cooling rate particularly before and during freezing had a notable effect on the sperm motility recovery. There was no or low recovery (0-18%) of sperm motility when the cells were transferred directly to liquid nitrogen from the initial two cooling stages. The data demonstrate the importance of all of the cooling stages in the cryopreservation of the cells. Like glycerol, dimethyl sulfoxide (Me(2)SO) and ethylene glycol also showed a dose-dependent increase in motility recovery as well as a biphasic curve of cryoprotection. At optimal concentrations, dimethyl sulfoxide (1.00 M) and ethylene glycol (1.29 M) were effective in recovering sperm motility to the extent of 20 and 13%, respectively. Thus these reagents have markedly lower cryoprotection potential than glycerol.     

A new approach to the cryopreservation of hepatocytes in a sandwich culture configuration

Current methods of cryopreservation of hepatocytes in single cell suspensions result in low overall yields of hepatocytes, demonstrating long-term preservation of hepatocellular functions. A novel culture method has recently been developed to culture liver cells in a sandwich configuration of collagen layers in order to stabilize the phenotypic expression of these cells in vitro (J. C. Y. Dunn, M. L. Yarmush, H. G. Koebe, and R. G. Tompkins, FASEB J. 3, 174, 1989). Using this culture system, rat hepatocytes were frozen with 15% (v/v) Me2SO to -70 degrees C, and stored at approximately -100 degrees C. Following rapid thawing, long-term function was assessed by measuring albumin secretion in culture for 7-14 days postfreezing. Comparison was made with cryopreservation of liver cells in single cell suspensions. Cryopreservation of liver cells in suspension resulted in only a 2% yield of cells which could be successfully cultured; albumin secretion rates in these cultured cells over 48 hr were 26-30% of secretion rates for nonfrozen hepatocytes. Freezing cultured liver cells in the sandwich configuration after 3, 7, and 11 days in culture maintained 0, 26, and 19% of the secretion rates of nonfrozen hepatocytes, respectively. Morphology of the cryopreserved cells appeared grossly similar to cells without freezing; however, this morphological result was patchy and represented approximately 30% of the cells in culture. These results represent the first demonstration of any quantitative long-term preservation of hepatocellular function by cryopreservation, suggesting that cultured hepatocytes can survive freezing and maintain function.     

Artificial insemination using cryopreserved sperm in the silkworm,Bombyx mori

We report in this paper that female moths artificially inseminated with cryopreserved sperm (-196 degrees C) could oviposit eggs when the sperm was preserved for 356days, and that the fertilization rate and the number of eggs laid were almost equivalent to those obtained in normally mated moths. The optimal cooling rate for sperm freezing was 5-65 degrees C/min for maintaining a high fertility of sperm. The simple and reliable method of cryopreservation was to put the semen first in a deep freezer at -80 degrees C and thereafter put them in liquid nitrogen. When female moths of 'white 2' egg-color mutant strain were inseminated with a mixture of frozen-thawed sperm from males of normal-colored egg strain and non-frozen sperm from males of the 'white 2', female moths deposited a majority of 'white 2' eggs and a very small number of eggs of normal color. The result shows that there was a competitive fertilization of sperm between the two strains of the silkworm, and that sperm fertility was reduced to a considerable extent by freezing at -196 degrees C. These results may contribute not only to basic studies on fertilization in Lepidoptera but also to the development of long-term preservation procedure of genetic resources by using cryopreserved sperm of Bombyx mori.     

Cryopreservation of isolated rat hepatocytes: a critical evaluation of freezing and thawing conditions

Various parameters, including the nature and proportion of the constituents of the cryoprotective medium, the cooling rate, and the composition of the thawing medium, were evaluated for the cryopreservation of adult rat hepatocytes. The highest percentage of cells able to survive in culture was obtained by freezing in L15 medium containing 16% dimethyl sulfoxide, at a rate of 3 degrees C/min, and by adding 0.8 M glucose to the thawing medium. More than 50% of hepatocytes capable of attachment just after cell isolation kept this property after freezing and survived in primary culture. Dead cells could be eliminated before seeding by centrifugation on a Percoll layer. In culture, frozen cells exhibited a morphology similar to that of unfrozen cells and after 24 hr their protein secretion rate was reduced by only about 40%.     

Viability and genetic stability of the bacterium Escherichia coli HB101 with the recombinant plasmid during preservation by various methods.

The effects of various methods of preservation (freeze-drying and storage at 4 degrees C; low-temperature freezing on desiccated silica gel and storage at -70 and -150 degrees C; cryopreservation and storage at -196 degrees C) on viability and genetic stability of the bacterium Escherichia coli HB101 carrying the recombinant plasmid with the human DNA fragment were studied. Genetic stability was estimated by maintenance of the selective markers of antibiotic resistance and the stability of the restriction sites in recombinant DNA. Freezing on silica gel and cryopreservation were shown to be the optimal preservation methods providing a high level of survival and genetic stability.     

Islet transplantation in experimental diabetes of the rat. XIII. Cryopreservation reduces MHC class II but not class I antigens of rat pancreatic islets.

Pretreatment of islet allografts prior to transplantation may reduce islet immunogenicity and prolong graft acceptance. We have studied the MHC antigen reducing effect of cryopreservation onto rat pancreatic islets performing indirect immunofluorescence tests and peroxidase-anti-peroxidase staining (PAP). Three different freezing programs were used. Program A: 0.5 degrees C/min to -35 degrees C and 1 degree C/min from -35 to -100 degrees C. Program B: 2 degrees C/min to -35 degrees C and 6 degrees C/min from -35 to -100 degrees C. Program C: 0.25 degrees C/min to -40 degrees C. Cryopreservation clearly reduced the number of class II antigen positive cells per islet in all cases. Program A was most effective with 45.5% of class II antigen negative islets compared to 6.4% of class II antigen negative fresh islets as shown by indirect immunofluorescence. The class II antigen reducing effect of cryopreservation proved to be permanent and not only temporary. Reduced class II antigen expression of cryopreserved islets could not be reestablished by incubation of the islets with rat IFN. A combination of cryopreservation followed by a 10 day culture period proved to be most effective with 85.6% of class II antigen negative islets. In contrast, we could not show any effect of cryopreservation on class I antigen expression. Viability of the cryopreserved rat islets was shown in-vitro by glucose stimulated insulin secretion.     

Survival of frozen mouse embryos after rapid thawing from -196 degrees C.

The effect of the rate of rewarming on the survival of 8-cell mouse embryos and blastocysts was examined. The samples were slowly cooled (0.3--0.6 degrees C/min) in 1.5 M-DMSO to temperatures between -10 and -80 degrees C before direct transfer to liquid nitrogen (-196 degrees C). Embryos survived rapid thawing (275--500 degrees C/min) only when slow cooling was terminated at relatively high subzero temperatures (-10 to -50 degrees C). The highest levels of survival in vitro of rapidly thawed 8-cell embryos were obtained after transfer to -196 degrees C from -35 and -40 degrees C (72 to 88%) and of rapidly thawed blastocysts after transfer from -25 to -50 degrees C (69 to 74%). By contrast, for embryos to survive slow thawing (8 to 20 degrees C/min) slow cooling to lower subzero temperatures (-60 degrees C and below) was required before transfer to -196 degrees C. The results indicate that embryos transferred to -196 degrees C from high subzero temperatures contain sufficient intracellular ice to damage them during slow warming but to permit survival after rapid warming. Survival of embryos after rapid dilution of DMSO at room temperature was similar to that after slow (stepwise) dilution at 0 degrees C. There was no difference between the viability of rapidly and slowly thawed embryos after transfer to pseudopregnant foster mothers. It is concluded that the behaviour of mammalian embryos subjected to the stresses of freezing and thawing is similar to that of other mammalian cells. A simpler and quicker method for the preservation of mouse embryos is described.     

Membrane integrity and development of immature murine cumulus-oocyte complexes following slow cooling to -60 degrees C: the effect of immediate rewarming, plunging into LN2 and two-controlled-rate-stage cooling

Cryopreservation of murine germinal vesicle (GV) stage cumulus-oocyte complexes (COCs) has been shown to result in poor development and cumulus cell damage. In an attempt to determine the stage of the cryopreservation protocol at which damage occurs, three cooling profiles were compared: slow-cooling (0.3 degrees C/min) to -60 degrees C (protocol A); slow-cooling to -60 degrees C and plunging to -196 degrees C (protocol B); or slow-cooling to -60 degrees C followed by further cooling at 10 degrees C/min to -150 degrees C, then plunging to -196 degrees C (protocol C). GV-stage COCs were collected from hormone-primed mice by repeated puncturing of ovarian follicles. COCs were exposed to 1.5 M Me(2)SO prior to cooling to -60 or -196 degrees C. Membrane integrity was assessed immediately after thawing using carboxy fluorescein and propidium iodide. A greater proportion of cumulus cells were damaged following protocol B than protocol A. Damage was less extensive following protocol C than following protocol B. For assessment of development, COCs were matured and fertilised in vitro. Morphological normality was significantly reduced following cooling to -60 or -196 degrees C compared with non-cryopreserved controls. Fertilisation of oocytes assessed as normal post-treatment was not significantly different between any of the groups. Development to blastocyst was least from oocytes exposed to protocol B, being significantly worse than for oocytes exposed to protocol A, but not significantly different to protocol C. A protocol comprising two stages of controlled-rate cooling decreased damage to the membranes of cumulus cells but did not significantly improve embryo development.     

Long-term cryopreservation of sperm from Mandarin fish Siniperca chuatsi

In order to develop cryopreservation techniques for long-term preserving the sperm of Mandarin fish Siniperca chuatsi, we examined the effects of various extender and cryopreservation on post-thaw motility. We found the optimal freezing procedures for the Mandarin fish sperm is diluting the semen in D-15 extender, chilling it to 4 degrees C, adding ME2SO to a final concentration of 10% (v/v), then transferring the semen in cryotubes, holding the cryotubes for 10 min at 6 cm (about -180 degrees C) above the surface of liquid nitrogen, for 5 min on the surface of liquid nitrogen, and finally plunged into liquid nitrogen. After thawed at 37 degrees C for 60s, the sperm had the highest post-thaw motility (96.00+/-1.73%). The optimal fertilization procedures for the frozen sperm is mixing the eggs with sperm, then adding 1 ml of swimming medium (SM=45 mM NaCl+5 mM KCl+20mM Tris-HCl, pH 8.0) immediately. At the sperm/egg ratio of 100,000:1, the fertilization rate and the hatching rate of the frozen sperm cryopreserved for 1 week or 1 year in liquid nitrogen (66.01+/-5.14% and 54.76+/-4.40% & 62.97+/-14.28% and 52.58+/-11.17%) were similar to that of fresh sperm (69.42+/-8.11% and 59.82+/-5.27%) (p>0.05). This is the first report that the Mandarin fish (S. chuatsi) sperm can successfully fertilized eggs after long-term cryopreservation.     

Drug metabolism and viability studies in cryopreserved rat hepatocytes

Rat hepatocytes were cryopreserved optimally by freezing them at 1 degrees C/min to -80 degrees C in cryoprotectant medium containing either 20% (v/v) dimethylsulfoxide (Me2SO) and 25% (v/v) fetal calf serum in Leibowitz L15 medium (Me2SO cryoprotectant) or 25% (v/v) vitrification solution (containing Me2SO, acetamide, propylene glycol and polyethylene glycol) in Leibowitz L15 medium (VS25). The VS25 solution was superior for maintaining viability during short-term storage (24-48 hr) but was slightly toxic during longer storage periods (7 days). Although thawed cells were 40-50% viable on ice after cryopreservation, their viability fell rapidly during incubation in suspension at 37 degrees C. This decline in viability occurred more rapidly after freezing in Me2SO cryoprotectant than in VS25 and was associated with extensive intracellular damage and cell swelling. The loss in viability at 37 degrees C does not appear to be due to ice-crystal damage as it occurred in cells stored at -10 degrees C (above the freezing point of the cryoprotectants) and it may be due to temperature/osmotic shock. Both cryoprotectant media were equally efficient at preserving enzyme activities in the hepatocytes over 7 days at -80 degrees C. Cytochrome P450 and reduced glutathione content and the activities of the microsomal enzymes responsible for aminopyrine N-demethylation and epoxide hydrolysis were well maintained over 7 days storage. In contrast, the cytosolic enzymes glutathione-S-transferase and glutathione reductase were markedly labile during cryopreservation. Cytosolic enzymes may be more susceptible to ice-crystal damage, whereas the microsomal membrane may protect the enzymes which are embedded in it.     

Cryopreservation of adult human hepatocytes obtained from resected liver biopsies

Isolated human hepatocytes have been shown to represent a valuable in vitro model to investigate the metabolism and cytotoxicity of xenobiotics. In addition, human hepatocyte transplantation and artificial liver support systems using isolated human hepatocytes are currently investigated as treatment for acute and chronic hepatic failure. In this regard, human hepatocyte banking by cryopreservation would be of great interest. In the present study, freshly isolated hepatocytes from resected liver biopsies of 28 separate donors (viability: 88 +/- 2%; plating efficiency: 79 +/- 5%) were cryopreserved using two different protocols, stepwise freezing (SF) or progressive freezing (PF), in combination (PF(+), SF(+)) or not (PF(-), SF(-)) with a 30 min preincubation in culture medium at 37 degrees C. Total recovery was higher after PF (38 +/- 3%) than after SF (12 +/- 2%). Preincubation prior to SF had no effect on plating efficiency of thawed hepatocytes (SF(-): 38 +/- 6% versus SF(+): 46 +/- 7%) while preincubation prior to PF increased plating efficiency of thawed hepatocytes (PF(-): 42 +/- 6% versus PF(+): 64 +/- 4%, p < 0.05). In attached cultured human cryopreserved/thawed hepatocytes (CH) from the PF(+) group, albumin production and glutathione content were not significantly different from those of the freshly isolated hepatocyte (FIH) cultures. Cells in CH monolayers appeared smaller than cells in FIH monolayers. In addition, the pattern of cytochrome P450- and UDP-glucuronosyl transferase-dependent isoenzyme activities and GST activity were different, suggesting a variability in the resistance to cryopreservation of the various liver hepatocyte populations. Taken all together, the results of the present study suggest that recovery of human hepatocytes after isolation prior to progressive freezing should allow human hepatocyte banking for use in pharmacotoxicology and cell therapy research purposes.     

Effect of cryopreservation on human articular chondrocyte viability, proliferation, and collagen expression

Autotransplantation of human chondrocytes is an alternative therapeutic treatment for focal lesions of cartilage. During the process of isolation and culture of chondrocytes some problems that render the implantation of the cells unsuitable can occur. For security, some cells must be stored using cryopreservation. The objective of this study was to analyze the effect of cryopreservation on cellular viability, proliferation, and collagen expression of human chondrocytes. Human osteoarthritic cartilage (n = 23) was obtained and transferred to a sterile flask containing Dulbecco's modified Eagle's medium (DMEM) and antibiotics. Chondrocytes were isolated, cultured for 3-4 weeks, and frozen in DMEM containing 10% human serum and 10% dimethyl sulfoxide by use of three different protocols. A cellular fraction was frozen directly to -80 degrees C (Protocol I). Another fraction was directly frozen to -80 degrees C and 24 h later introduced into liquid nitrogen (Protocol II). The last aliquot was frozen with controlled freezing using a freezing rate of -1 degrees C/min to a temperature of -40 degrees C, 2 degrees C/min to -60 degrees C, and 5 degrees C/min to -150 degrees C (Protocol III). Cells were cryopreserved for 2 weeks. Cells from each cryopreservation method were then cultured for 7 days and cellular proliferation was evaluated by the counting of the total cells in each flask. Cryopreservation had a negative effect on chondrocyte survival and proliferation. The survival after cryopreservation with the three protocols was 70-75%. There was no significative difference between the methods used to cryopreserve (P = 0.4117). However, there was a significant difference among the donors (P = 0.0111). Cellular proliferation of chondrocytes was reduced by cryopreservation (P = 0.024). The rate of proliferation of different groups was control samples 6.56, Protocol I 4.66, Protocol II 4.69, and Protocol III 5.58. Statistical analysis showed that the programmed protocol was the best method to preserve cellular functions. Chondrocytes were able to express collagen type II 1 week after cryopreservation. Cryopreservation modifies the survival and proliferation of chondrocytes. Of all protocols used to cryopreserve, the programmed protocol seems to be the best technique. Cryopreservation does not alter the collagen type II expression.     

Thawed human hepatocytes in primary culture.

In drug metabolism studies, isolated and cultured human hepatocytes provide a useful model for overcoming the difficulty of extrapolating from animal data. In vitro studies with human hepatocytes are scarce because of the lack of livers and suitable methods of storage. After developing a new method for cryopreservation of human hepatocytes, we evaluated the effects of deep freezing storage on their viability, morphology, and functional and toxicological capabilities in classical culture conditions. Freshly isolated human hepatocytes were cryopreserved in medium containing 10% Me2SO and 20% fetal calf serum, using a Nicool ST20 programmable freezer (-1.9 degrees C/min for 18 min and -30 degrees C/min for 4 min). Cells were stored in liquid nitrogen. Viability of thawed human hepatocytes was 50-65% as assessed by erythrosin exclusion test prior to purification on a Percoll density gradient. Morphological criteria showed that thawed human hepatocytes require an adaptation period to the medium after seeding. Functional assessments showed that human hepatocytes which survive freezing and thawing preserve their protein synthesis capabilities and are able to secrete a specific protein, anionic peptidic fraction, which is involved in the hepatic uptake of bile-destined cholesterol. We then studied Midazolam biotransformation to test metabolic functions, and erythromycin toxicity by Neutral Red test (cell viability) and 3-(4,5-dimethylthiazol-2-yl)-diphenyl tetrazolium bromide test (cell metabolism). All of these experiments indicated that thawed human hepatocytes should be used 38 h after seeding for optimum recovery of their functions: membrane integrity, protein synthesis, and stabilization of drug metabolism enzymes.     

Controlled-rate freezing of human ES cells

A significant obstacle to using human embryonic stem cells (hESCs) arises from extremely poor survival associated with freezing, typically in the range of 1%. This report describes a slow controlled-rate freezing technique commonly used for mammalian embryo cryopreservation. Using a combination of surviving colony number and colony diameter; survival was determined relative to untreated hESCs. Using a dimethyl sulfoxide (DMSO) cryoprotectant and either a homemade controlled-rate freezing device or a commercial freezing device, survival rates of 20%-80% were obtained. To achieve the highest levels of survival, the critical factors were an ice crystal seed (at -7 degrees to -10 degrees C), a freeze rate between 0.3 degrees and 1.8 degrees C/min, and a rapid thaw rate using room temperature water. Slow controlled-rate cooling allows a rapid, simple, and reproducible means of cryopreserving hESCs.     

Refrigerated storage and cryopreservation of black drum (Pogonias cromis) spermatozoa

Procedures were developed for the collection, refrigerated storage and cryopreservation of black drum spermatozoa. Sperm samples were collected by removing and slicing the testis, and suspending the spermatozoa in Hanks' balanced salt solution (HBSS) at 200 mOsm/kg. Threshold activation (10%) of black drum spermatozoa occurred at 370 mOsm/kg, and complete activation occurred at 580 mOsm/kg in HBSS. Sperm cells activated in artificial seawater had higher motility than those activated in HBSS at osmolalities from 350 to 500 mOsm/kg. Spermatozoa stored at 4 degrees C in HBSS or artificial seawater at osmolalities from 202 to 290 mOsm/kg retained motility longer than did those stored at other osmolalities Dilution rate had no effect on sperm storage time at 4 degrees C. Four chemicals were evaluated as cryoprotectants: dimethyl sulfoxide (DMSO), n,n-dimethyl acetamide (DMA), methanol, and glycerol. Glycerol and DMA at concentrations of 10% significantly reduced motility within 52 min. Spermatozoa were cryopreserved at 3 freezing rates (-27, -30, or -45 degrees C/min) in a nitrogen vapor shipping dewar or a computer-controlled freezer. Spermatozoa frozen using 10% DMSO had the highest post-thaw motility at a freezing rate of -27 or -30 degrees C/min. Spermatozoa frozen using 5% glycerol, 5% DMSO, or 10% DMSO had the highest post-thaw motility at a freezing rate of -45 degrees C/min.