Transplantation and in vitro perifusion of rat islets of Langerhans after slow cooling and warming in the presence of either glycerol or dimethyl sulfoxide

The cryoprotectants dimethyl sulfoxide (Me2SO) and glycerol have been used for the cryopreservation of fetal rat pancreases but only Me2SO has been reported for the cryopreservation of adult rat islets. Since glycerol may be preferred to Me2SO for clinical use, this study was undertaken to compare the effectiveness of these cryoprotectants during the slow cooling of isolated adult rat islets. Islets of Langerhans prepared from the pancreases of WAG rats by collagenase digestion were stored at -196 degrees C after slow cooling (0.3 degrees C/min) to -70 degrees C in the presence of multimolar concentrations of either Me2SO or glycerol. Samples were rewarmed slowly (approximately 10 degrees C/min) and dilution of the cryoprotectant was achieved using medium containing sucrose. Function was assessed by determination of the time course of the glucose-induced insulin release during in vitro perifusion at 37 degrees C and also by isograft transplantation. Transplants were carried out by intraportal injection of a minimum of 1700 frozen and thawed islets into streptozotocin-induced diabetic recipients and tissue function was assessed by monitoring blood glucose levels and body weight changes. Without exception the islets frozen and thawed in the presence of glycerol failed to reduce high serum glucose levels of recipient rats and in vitro dynamic release curves showed to demonstrate a glucose-sensitive insulin release pattern. Reversal of the diabetic conditions was achieved in two of five animals receiving islets which had been frozen and thawed with 2 M Me2SO; and in one of three animals receiving islets cryopreserved with 3 M Me2SO. Nevertheless, perifusion studies showed that the pattern of insulin secretion from groups of cryopreserved islets which did show an ability to secrete insulin was atypical compared with that of untreated controls, suggesting that the tissue was altered or damaged in some way.     

Cryopreservation of isolated hepatocytes: intracellular ice formation under various chemical and physical conditions.

Kinetics of intracellular ice formation (IIF) for isolated rat hepatocytes was studied using a cryomicroscopy system. The effect of the cooling rate on IIF was investigated between 20 and 400 degrees C/min in isotonic solution. At 50 degrees C/min and below, none of the hepatocytes underwent IIF; whereas at 150 degrees C/min and above, IIF was observed throughout the entire hepatocyte population. The temperature at which 50% of hepatocytes showed IIF (50TIIF) was almost constant with an average value of -7.7 degrees C. Different behavior was seen in isothermal subzero holding temperatures in the presence of extracellular ice. 50TIIF from isothermal temperature experiments was approximately -5 degrees C as opposed to -7.7 degrees C for constant cooling rate experiments. These experiments clearly demonstrated both the time and temperature dependence of IIF. On the other hand, in cooling experiments in the absence of extracellular ice, IIF was not observed until approximately -20 degrees C (at which temperature the whole suspension was frozen spontaneously) suggesting the involvement of the external ice in the initiation of IIF. The effect of dimethyl sulfoxide (Me2SO) on IIF was also quantified. 50TIIF decreased from -7.7 degrees C in the absence of Me2SO to -16.8 degrees C in 2.0 M Me2SO for a cooling rate of 400 degrees C/min. However, the cooling rate (between 75 and 400 degrees C/min) did not significantly affect 50TIIF (-8.7 degrees C) in 0.5 M Me2SO. These results suggest that multistep protocols will be required for the cryopreservation of hepatocytes.     

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.     

Cryopreservation of umbilical cord blood: 2. Tolerance of CD34(+) cells to multimolar dimethyl sulphoxide and the effect of cooling rate on recovery after freezing and thawing

Cryopreservation protocols for umbilical cord blood have been based on methods established for bone marrow (BM) and peripheral blood stem cells (PBSC). The a priori assumption that these methods are optimal for progenitor cells from UCB has not been investigated systematically. Optimal cryopreservation protocols utilising penetrating cryoprotectants require that a number of major factors are controlled: osmotic damage during the addition and removal of the cryoprotectant; chemical toxicity of the cryoprotectant to the target cell and the interrelationship between cryoprotectant concentration and cooling rate. We have established addition and elution protocols that prevent osmotic damage and have used these to investigate the effect of multimolar concentrations of Me(2)SO on membrane integrity and functional recovery. We have investigated the effect of freezing and thawing over a range of cooling rates and cryoprotectant concentrations. CD34(+) cells tolerate up to 60 min exposure to 25% w/w (3.2M) Me(2)SO at +2 degrees C with no significant loss in clonogenic capacity. Exposure at +20 degrees C for a similar period of time induced significant damage. CD34(+) cells showed an optimal cooling range between 1 degrees C and 2.5 degrees C/min. At or above 1 degrees C/min, increasing the Me(2)SO concentration above 10% w/w provided little extra protection. At the lowest cooling rate tested (0.1 degrees C/min), increasing the Me(2)SO concentration had a statistically significant beneficial effect on functional recovery of progenitor cells. Our findings support the conclusion that optimal recovery of CD34(+) cells requires serial addition of Me(2)SO, slow cooling at rates between 1 degrees C and 2.5 degrees C/min and serial elution of the cryoprotectant after thawing. A concentration of 10% w/w Me(2)SO is optimal. At this concentration, equilibration temperature is unlikely to be of practical importance with regard to chemical toxicity.     

Factors to consider in the assessment of viability of cryopreserved islets of Langerhans

With the development of techniques for the isolation and transplantation of pancreatic islets of Langerhans, research has been directed toward low-temperature storage of islets as a means of preservation. For successful islet cryopreservation several factors must be considered. In these studies we have investigated the effects of the cryoprotectant dimethyl sulfoxide (Me2SO) on islet function in the absence of freezing. We have found that Me2SO pretreatment can inhibit subsequent glucose-induced insulin release, but this effect can be minimized by hypothermic exposure to the cryoprotectant using a stepwise addition and dilution protocol for treatment. By studying islet function after freezing and thawing, we have found also that a slow cooling rate (0.3 degrees C/min) results in optimal survival and that islet function can be significantly improved by increasing the duration of post-thaw culture. The results of these studies address only a few of the many questions that need to be answered before clinical application of cryopreserved islet transplantation occurs.     

A comparative study of mouse embryo freeze-preservation including the examination of a thermoelectric freezing device

In Study 1 over 2000 4- to 8-cell mouse embryos were randomly pooled and assigned to 1 of 12 treatment groups. A 2 X 2 X 3 factorial design was used to analyze two types of cryoprotectant/post-thaw (PT) dilutions (dimethyl sulfoxide [Me2SO]/stepwise dilution versus glycerol/sucrose dilution), two storage containers (glass ampoules versus plastic straws), and three cooling treatments. Two commercial, controlled-rate freezing machines were examined, employing either nitrogen gas (Planer) or thermoelectric (Glacier) cooling. Embryos were cooled slowly (0.5 degrees C/min) to -35 or -80 degrees C and then cooled rapidly by transfer into liquid nitrogen (LN2). Thawed embryos were cultured for 24 hr after which developmental stage, post-thaw survival (PTS), embryo degeneration rate (EDR), quality grade (QG), and fluorescein diacetate viability grade (VG) were assessed. Overall, PTS and EDR were similar (P greater than 0.05) among the three freezing unit/plunge temperature treatments. Cumulative results of container and cryoprotectant/PT dilution treatments consistently demonstrated greater PTS, QG, and VG ratings and lower EDR values when embryos were frozen in ampoules using glycerol/sucrose dilution. Embryos treated with Me2SO/stepwise dilution were particularly sensitive to freezing damage when stored in plastic straws and plunged into LN2 at -35 degrees C. Study 2 was directed at determining whether Study 1 methods for diluting Me2SO-protected embryos markedly affected PTS rates. Post-thaw culture percentages were no different (P greater than 0.05) for four- to eight-cell Me2SO-treated embryos frozen in ampoules (using the forced-LN2 device), thawed, and diluted either conventionally in reduced concentrations of Me2SO or in the sucrose treatment normally accorded glycerolated embryos.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of dimethyl sulfoxide on cultured rat hepatocytes in sandwich configuration.

A recently developed sandwich culture system, in which hepatocytes are sandwiched between two layers of collagen, has been shown to be capable of maintaining long-term expression of hepatocellular function (J. C. Y. Dunn et al., Biotechnol. Prog. 7, 237-245, 1991). The development of an adequate technique for the cryopreservation of hepatocytes in such a stable culture configuration would ensure a ready supply of hepatocytes for use in bioreactors or bioartificial liver support devices. This report describes the effects of exposing hepatocytes in sandwich culture to different concentrations of the cryoprotectant dimethyl sulfoxide (Me2SO) at 22 degrees C on Day 7 of culture. Cell function, morphology, and cytoskeletal organization were followed for 14 days after exposure. Hepatocellular morphology and albumin secretion remained normal when cultures were exposed for up to 120 min to predicted final Me2SO concentrations up to 1.33 M. Exposure for less than 60 min to equilibrium concentrations of up to 3.33 M Me2SO did not adversely affect cell morphology or albumin secretion rate, but at the highest concentration (3.33 M), increase of the exposure time to 60 or 120 min resulted in dramatic, irreversible cell damage and loss of function. Actin filament organization was shown to be undisturbed when the cells were exposed to 1.33 M Me2SO for 60 min, but was irreversibly disrupted by exposure to 3.33 M for 120 min. Based on these results, a simple and safe procedure is suggested for the addition of Me2SO to hepatocytes in a sandwich culture configuration and its subsequent removal, which will be valuable for studies on hepatocyte cryopreservation.     

Preservation of taenia coli by freezing and storage at -196 degrees C

Some damaging effects that occur during cryopreservation by freezing to -196 degrees C have been evaluated in rabbit taenia coli by analyzing the proportional recovery of acetylcholine- and histamine-induced maximal contractions. Dimethyl sulfoxide (Me2SO) 10 v/v% was used as the cryoprotectant; it reversibly abolishes spontaneous contractility even after incubation at 37 degrees C during 2 hr. Programmed freezing at 0.6 degrees C/min with compensation for the latent heat of fusion and warming at 35 degrees C/min proved to be slightly superior to programmed cooling without compensation and slower warming. The degree of functional recovery was comparable after either abrupt or stepwise removal of Me2SO. Freeze-thawing resulted in a significant reduction of contractile force in each buffer solution tested, and acetylcholine-induced contractility was always better preserved than histamine-induced contractility. The best preservation (approximately 65%) was obtained in a potassium-rich buffer solution. The absence of calcium and magnesium from the incubating medium had no influence, whereas the presence of EDTA significantly affected functional recovery. It is difficult to compare our results with those reported by others because of multiple methodological differences. However, it seems that previous results can be improved by changing the freezing rate and the composition of the incubating and cryoprotecting medium.     

Cryopreservation of chum salmon blastomeres by the straw method

In order to preserve genetic resources of chum salmon, Oncorhynchus keta, optimum conditions for cryopreservation of isolated blastomeres were investigated. Survival rates under various conditions were compared: the nature and the concentration of cryoprotectants before and after freezing, the seeding temperature, and the developmental stages of donor embryos. Isolated blastomeres immersed for 30 min in Eagle's MEM containing both a cryoprotectant and 10% fetal bovine serum (FBS) at 10 degrees C were transferred into a straw and frozen at 1 degrees C/min to -30 degrees C by a programmable freezer before being plunged into liquid nitrogen. Ice seeding was carried out at -5 to -15 degrees C. Frozen blastomeres were thawed in water at 15 degrees C. Blastomeres cryopreserved with MEM containing 10% dimethyl sulfoxide (Me(2)SO) and 10% FBS (10% Me(2)SO/MEM10) showed higher survival rates than those cryopreserved with MEM containing 10% FBS and 10% glycerol, ethyleneglycol, 1, 2-propanediol, or sucrose. Blastomeres treated with 10% Me(2)SO/MEM10 showed higher survival rates than those treated with MEM containing only 10% Me(2)SO. Blastomeres seeded above -10 degrees C showed higher survival rates than non-seeded ones. Frozen blastomeres at advanced stages demonstrated high survival rates. Blastomeres cryopreserved under optimum conditions showed survival rates of 59.3+/-2.8%. These results indicate that 10% Me(2)SO/MEM10 is a suitable cryoprotectant medium to cryopreserve chum salmon blastomeres, that seeding should be carried out above -10 degrees C on pre-freezing, and that blastomeres at the blastula stage should be used as material.     

Effect of rapid addition and dilution of dimethyl sulfoxide and 37 degrees C equilibration on viability of rabbit morulae thawed rapidly

The aim of the present study was to examine the effects of various conditions of addition and dilution of dimethyl sulfoxide (Me2SO) and 37 degrees C equilibration, and also the effects of freezing in the solution which was prepared in advance and stored in plastic straws at -20 degrees C on the viability of rabbit morulae thawed rapidly. The embryos were cooled from room temperature to -30 degrees C at 1 degree C/min in the presence of 1.5 M Me2SO using a programmable liquid nitrogen vapor freezing machine with an automatic seeding device, then cooled rapidly, and stored in liquid nitrogen. The frozen straws were thawed rapidly (greater than 1000 degrees C/min). When Me2SO was added in a single step, equilibrated with embryos at 37 degrees C for 15 min and diluted out in a single step, a very high survival was obtained: transferable/recovered, 90%: developed/recovered, 96%. When embryos were pipetted into 1.5 M Me2SO that was prepared in advance, stocked in straws at -20 degrees C, and cooled, the proportions of transferable and developed embryos were equivalent to those of embryos frozen in the solution that was prepared immediately before use.     

Selective oxidation and reduction of methionine residues in peptides and proteins by oxygen exchange between sulfoxide and sulfide

Treatment of amino acids, peptides, and proteins with aqueous solution of dimethyl sulfoxide (Me2SO) and hydrochloric acid (HCl) resulted in the oxidation of methionine to methionine sulfoxide. In addition to methionine, SH groups are also oxidized, but this reaction proceeds after a lag period of 2 h. Other amino acids are not modified by aqueous Me2SO/HCl. The reaction is strongly pH-dependent. Optimal conditions are 1.0 M HCl, 0.1 M Me2SO, at 22 degrees C. The reaction exhibits pseudo-first order kinetics with Kobs = 0.23 +/- 0.015 M-1 min-1 at 22 degrees C. Incubation of methionine sulfoxide with dimethyl sulfide and HCl resulted in the conversion of methionine sulfoxide to methionine. This reaction is fast (t1/2 = 4 min at room temperature) and quantitative at relatively anhydrous condition (i.e. at H2O:concentrated HCl:dimethyl sulfide ratio of 2:20:1). Quantitative conversions of methionine sulfoxide back to methionine are obtained in peptides and proteins as well, with no observable other side reactions in amino acids and proteins. The wide applications of this selective oxidation and reduction of methionine residues are demonstrated and discussed.     

Effect of rapid addition and dilution of dimethyl sulfoxide on the viability of frozen-thawed rabbit morulae

The aim of the present study was to examine effects of altering thawing conditions and procedure of addition and dilution of Me2SO on the viability of frozen-thawed rabbit morulae. Five hundred and sixty two rabbit morulae were cooled from room temperature to -80 degrees C at 1 degree C/min in the presence of 1.5 M dimethyl sulfoxide (Me2SO) using a programmable liquid nitrogen vapor freezing machine with an automatic seeding device, cooled rapidly, and stored in liquid nitrogen. When Me2SO was added in a single step, the frozen embryos were thawed in ambient air at 40 degrees C/min and Me2SO was diluted in a single step, 99 of 107 (93%) embryos cultured for 48 hr and 12 of 32 (38%) embryos transferred to 6 recipients developed to expanding blastocysts and viable fetuses, respectively. When Me2SO was added in a single step and the frozen embryos were thawed at the same rate and transferred directly without removal of Me2SO to culture media or oviducts of 8 recipients, 67 of 75 (89%) embryos cultured and 12 of 40 (30%) embryos transferred developed to expanding blastocysts and viable fetuses, respectively. There were no significant differences between these survival rates and survival rates obtained by conventional method, i.e., frozen embryos were thawed at 4 degrees C/min by interrupted slow method and Me2SO was added and diluted in a stepwise manner.     

Multifaceted freezing injury in human polymorphonuclear cells at high subfreezing temperatures

Extracellular freezing injury at high subzero temperatures in human polymorphonuclear cells (PMNs) was studied with a cryomicroscope, electron microscope, and functional assays (phagocytosis, microbicidal activity, and chemotaxis). There are at least four major factors in freezing injury: osmotic stress, chilling, cold shock, and dilution shock. Extracellularly frozen PMNs lose functions when cooled to -2 degrees C without a cryoprotectant. Cells lose volume on freezing to the same degree as in hypertonic exposure. PMNs have a minimum volume to which they can shrink without injury. Greater dehydration produces irreversible injury to cellular functions, and cells eventually collapse under high osmotic stress. Chilling sensitivity is seen in slowly chilled, supercooled PMNs below -5 degrees C; at -7 degrees C, functions are lost in 1 h. This injury can be prevented by the addition of Me2SO but not glycerol. Me2SO does not, however, prevent cold shock (injury due to rapid cooling), which is seen during cooling at 10 degrees C/min to -14 degrees C, but not during slow cooling at 0.5 degrees C/min. One of the problems of using glycerol as a cryoprotectant stems from the high sensitivity of PMNs to dilution shock during the dilution or removal of glycerol.     

Fundamental cryobiology of rat immature and mature oocytes: hydraulic conductivity in the presence of Me(2)SO, Me(2)SO permeability, and their activation energies

The hydraulic conductivity in the presence of dimethyl sulfoxide Me(2)SO (L(p)(Me(2)SO)), Me(2)SO (P(Me(2)SO)) permeability and reflection coefficient (sigma) of immature (germinal vesicle; GV) and mature (metaphase II; MII) rat oocytes were determined at various temperatures. A temperature controlled micropipette perfusion technique was used to conduct experiments at five different temperatures (30, 20, 10, 4, and -3 degrees C). Kedem and Katchalsky membrane transport theory was used to describe the cell volume kinetics. The cell volumetric changes of oocytes were calculated from the measurement of two oocyte diameters, assuming a spherical shape. The activation energies (E(a)) of L(p)(Me(2)SO) and P(Me(2)SO) were calculated using the Arrhenius equation. Activation energies of L(p)(Me(2)SO) for GV and MII oocytes were 34.30 Kcal/mol and 16.29 Kcal/mol, respectively; while the corresponding E(a)s of P(Me(2)SO) were 19.87 Kcal/mol and 21.85 Kcal/mol, respectively. These permeability parameters were then used to calculate cell water loss in rat oocytes during cooling at subzero temperatures. Based on these values, the predicted optimal cooling rate required to maintain extra- and intracellular water in near equilibrium for rat GV stage oocytes was found to be between 0.05 degrees C/min and 0. 025; while for rat MII oocytes, the corresponding cooling rate was 1 degrees C/min. These data suggest that standard cooling rates used for mouse oocytes (e.g., 0.5-1 degrees C/min) can also be employed to cryopreserve rat MII oocytes. However, the corresponding cooling rate required to avoid damage must be significantly slower for the GV stage rat oocyte. J. Exp. Zool. 286:523-533, 2000.     

Effect of different cryoprotectants and vitrificant solutions on the hatching rate of turbot embryos (Scophthalmus maximus)

Vitrification could provide a promising tool for the cryopreservation of fish embryos. However, in order to achieve a vitrifiable medium, a high concentration of permeable cryoprotectants must be employed, and the incorporation of high molecular weight compounds should also be considered. The toxicity of these permeable and non-permeable agents has to be assessed, particularly when high concentrations are required. In the present study, permeable and non-permeable cryoprotectant toxicity was determined in turbot embryos at two development stages (F stage-tail bud and G stage-tail bud free). Embryos treated with pronase (2mg/ml, 10 min at 22 degrees C) were incubated in dimethyl sulfoxide (Me2SO), methanol (Meth.) or ethylene glycol (EG) in concentrations ranging from 0.5 to 6M for periods of 10 or 30 min, and in 5, 10, and 15% polyvinylpyrrolidone (PVP), 10, 15, and 20% sucrose or 0.1, 1, and 2% X-1000 for 2 min. The embryos were then washed well and incubated in seawater until hatching. The toxicity of permeable cryoprotectants increased with concentration and exposure time. There were no significant differences between permeable cryoprotectants. However, embryos tolerated higher concentrations of Me2SO than other cryoprotectants. Exposure to permeable cryoprotectants did not affect the hatching rate except at G stage with X-1000 treatment and 20% sucrose. Taking into account the cryoprotectant toxicity and the vitrification ability of cryoprotectant mixtures, three vitrification solutions (V1, V2, and V3), and one protocol for stepwise incorporation were designed. The tested solutions contained 5M Me2SO+2M Meth+1M EG plus 5% PVP, 10% sucrose or 2% X-1000. The hatching rate of embryos that had been exposed to the the vitrification solutions was analyzed and no significant differences were noticed compared with the controls. Our results demonstrate that turbot embryos can be subject to this cryoprotectant protocol without deleterious effect on the hatching rate.     

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.     

Factors influencing renal cryopreservation. II. Toxic effects of three cryoprotectants in combination with three vehicle solutions in nonfrozen rabbit cortical slices

The [K+]/[Na+] ratio of rabbit renal cortical slices was used to examine, at 25 degrees C, the effects on viability of three cryoprotectant agents (CPA) (dimethyl sulfoxide (Me2SO), ethylene glycol, and glycerol) in combination with three vehicle solutions (Krebs-Henseleit (K-H), solution A, and RPS-2). Viability assessment by [K+]/[Na+] for all test solutions was made after incubating the slices in modified Cross-Taggart solution (C-T). With K-H and solution A, all concentrations of ethylene glycol and glycerol resulted in lowered ratios, whereas with Me2SO, concentrations greater than 1.4 M are required to reduce [K+]/[Na+]. With RPS-2 no decrease in the ratios was found until concentrations greater than 2.8 M were reached for all three CPAs. Binding of Me2SO to albumin, studied using [14C]Me2SO, was inhibited by RPS-2 when compared to K-H. Introduction and removal of Me2SO at 10 degrees C allowed an improvement in viability, at higher Me2SO concentrations, as compared to 25 degrees C.     

The influence of cooling rate and warming rate on the response of renal cortical slices frozen to -40 degrees C in the presence of 2.1 M cryoprotectant (ethylene glycol, glycerol, or dimethyl sulfoxide)

Renal cortical slices were treated with 2.1 M cryoprotectant in RPS-2 vehicle solution, cooled at one of four rates to -40 degrees C, then immediately warmed at one of four rates to 25 degrees C for determination of the [K+]/[Na+] after a standard incubation period. Results are presented in the form of survival "topographical maps" or surfaces with the x axis representing [K+]/[Na+]; the y axis, cooling rate; and the z axis, warming rate. The rate of temperature change fell in the range of 0.5 to 10 degrees C/min. The results suggest that when RPS-2 vehicle solution is used for 2.1 M cryoprotectants, Me2SO offers the prospect for greatest post-thaw recovery. With this vehicle-cryoprotective agent combination, the greatest post-thaw recovery is attained with cooling-warming combinations of -3, +4, and -0.5, +10 degrees C/min.     

Cryopreservation of Holospora undulata, a bacterial parasite of the ciliate Paramecium caudatum

We investigated cryopreservation of horizontal transmission stages of Holospora undulata, a micronucleus-specific bacterial parasite of Paramecium caudatum. Unlike in previous studies on related Holospora species, protocols using glycerol as cryoprotectant failed entirely. In contrast, freezing with dimethyl sulfoxide (Me2SO) conserved infectiousness of nearly all replicate inocula, although infection success was considerably lower than that of fresh inocula. Infection probability was enhanced by increasing the Me2SO concentration from 5 to 10%, and by freezing at -196 degrees C rather than -80 degrees C. Prolonged storage of up to 3 months had no significant effect on the viability of the inocula.