Vitrification of bovine embryos in a mixture of ethylene glycol and dimethyl sulfoxide

The influence of equilibration time before vitrification on the viability of vitrified morula- to blastocyst-stage bovine embryos and in vivo viability of vitrified embryos following transfer to recipients were investigated. In experiment 1, the embryos were exposed to an equilibration solution (50% VSED) containing 12.5% v/v ethylene glycol and 12.5% v/v dimethyl sulfoxide in modified Dulbecco's phosphate buffered saline with 4 mg/ml BSA (m-PBS) for 1, 2 and 5 minutes at room temperature (22 to 24 degrees C). The embryos were then placed in 15mul vitrification solution (VSED) consisting of 25% v/v ethylene glycol and 25% v/v dimethyl sulfoxide in m-PBS and were loaded into 0.25 ml plastic straws at room temperature. After 30 seconds, the straws were placed in liquid nitrogen (LN(2)) vapor for 2 minutes, plunged and stored in LN(2). To thaw, the straws were warmed in water at 20 degrees C for 15 seconds and the contents of the straws were expelled into a plastic dish. The embryos were diluted in 0.5 M sucrose + m-PBS for 5 minutes and were cultured in TCM-199 supplemented with bovine oviductal epithelial tissue. Viability of the embryos was assessed by the forming or reforming of the blastocoele after 24 hours of culture. High in vitro survival rates (73 approximately 90%) of vitrified embryos were obtained after 1 and 2 minute equilibrations, but was reduced (P<0.05) after 5 minute equilibration. In Experiment 2, morula- to blastocyst-stage embryos were vitrified after 1 minute equilibration in 50% VSED and 30 seconds of exposure to VSED. The vitrified-warmed embryos were transferred to recipient heifers at 7 days after estrus (1 embryo per recipient). Five (38%) of 13 (40%) of 10 recipients that had received blastocysts were diagnosed as pregnant using ultrasonography 60 days following transfer.     

Stimulatory and inhibitory effects of dimethyl sulfoxide and ethylene glycol on ATPase activity and calcium transport of sarcoplasmic membranes.

1. The effect of dimethyl sulfoxide (Me2SO) and ethylene glycol on two different preparations of the sarcoplasmic reticulum, i.e. native membranes and membranes whose phospholipids were hydrolyzed by phospholipase A, were investigated using ATP and p-nitrophenylphosphate as substrates. 2. Me2SO and ethylene glycol inhibit both calcium-dependent ATP hydrolysis and ATP-supported calcium transport by native vesicles. 3. In contrast, calcium-dependent p-nitrophenylphosphatase activity as well as p-nitrophenyl-phosphate-supported calcium transport are activated by both agents at concentrations lower than 30% (v/v). 4. Me2SO strongly stimulates p-nitrophenylphosphate activity of vesicles treated with phospholipase A, but has relatively little effect on p-nitrophenylphosphatase activity of native vesicles. 5. Up to a concentration of approximately 40% Me2SO (v/v) the inhibiting effect on the calcium-dependent ATPase is fully reversible, but only partially reversible on calcium transport. 6. In the concentration range where Me2SO inhibits ATP hydrolysis and calcium transport, it does not affect ATP binding to the membranes nor calcium-dependent formation of phospho-protein. 7. The rate of dephosphorylation as well as the rate of Pi exchange between ATP and ADP are markedly reduced by the presence of 30% Me2SO (v/v). 8. While Me2SO inhibits passive calcium efflux, ethylene glycol produces a considerable activation. 9. ADP-dependent calcium efflux and ATP synthesis are activated by 15% Me2SO (v/v). Ethylene glycol reduces both activities. 10. The results suggest that the respective substrate-enzyme complexes are differently affected by the agents, resulting either in inhibition or stimulation     

Membrane permeability of the human granulocyte to water,dimethyl sulfoxide,glycerol, propylene glycol and ethylene glycol

Granulocytes are currently transfused as soon as possible after collection because they rapidly deteriorate after being removed from the body. This short shelf life complicates the logistics of granulocyte collection, banking, and safety testing. Cryopreservation has the potential to significantly increase shelf life; however, cryopreservation of granulocytes has proven to be difficult. In this study, we investigate the membrane permeability properties of human granulocytes, with the ultimate goal of using membrane transport modeling to facilitate development of improved cryopreservation methods. We first measured the equilibrium volume of human granulocytes in a range of hypo- and hypertonic solutions and fit the resulting data using a Boyle-van’t Hoff model. This yielded an isotonic cell volume of 378 μm³ and an osmotically inactive volume of 165 μm³. To determine the permeability of the granulocyte membrane to water and cryoprotectant (CPA), cells were injected into well-mixed CPA solution while collecting volume measurements using a Coulter Counter. These experiments were performed at temperatures ranging from 4 to 37 °C for exposure to dimethyl sulfoxide, glycerol, ethylene glycol, and propylene glycol. The best-fit water permeability was similar in the presence of all of the CPAs, with an average value at 21 °C of 0.18 μm atm⁻¹ min⁻¹. The activation energy for water transport ranged from 41 to 61 kJ/mol. The CPA permeability at 21 °C was 6.4, 1.0, 8.4, and 4.0 μm/min for dimethyl sulfoxide, glycerol, ethylene glycol, and propylene glycol, respectively, and the activation energy for CPA transport ranged between 59 and 68 kJ/mol.     

Factors affecting survival of mouse blastocysts vitrified by a mixture of ethylene glycol and dimethyl sulfoxide

The present study was conducted to determine suitable conditions for mouse blastocysts vitrified by a solution containing 25 % v/v (4.5M) ethylene glycol and 25% v/v (3.4M) dimethyl sulfoxide (VSi). In Experiment 1, blastocysts were exposed to 50% diluted VSi (50% VSi) for 10 minutes then to VSi for 0.5 minutes at room temperature (22 approximately 24 degrees C) or at 4 degrees C, followed by vitrification. The survival rates of these embryos exposed at each temperature were not significantly different. In Experiment 2, embryos were exposed directly to VSi for various time periods at room temperature and diluted in mPBS with 0.5 M sucrose without vitrification. The viability of embryos decreased after more than a 3 minute exposure. When the embryos were exposed to VSi for 0.5, 1, 1.5 and 2 minutes followed by vitrification, the survival rates were 78, 80, 76 and 50%, respectively. In Experiment 3, embryos were vitrified after exposure to 50% VSi for various time periods and then to VSi for 0.5 minutes at room temperature. One minute exposure to 50% VSi resulted in the highest survival rate. In Experiment 4 and 5, the cooling rate (from approximately 70 to approximately 2500 degrees C/minute), sucrose concentration (0, 0.5 and 1 M) of dilution solution, and dilution time (1 or 5 minutes) did not affect the viability of the vitrified embryos. Following exposure to 50% VSi for 1 minute and to VSi for 0.5 minutes at room temperature, embryos were cooled 1) at approximately 2500 degrees C/minute and diluted in 0.5 M sucrose in mPBS after warming or 2) at approximately 200 degrees C/minute and diluted in mPBS. In vivo development rates after the transfer to recipients were 38 and 42%, respectively. These values were similar to that of fresh control embryos.     

Biological effects of dimethyl sulfoxide on yeast

The effects of dimethyl sulfoxide (DMSO) on yeast cells were investigated. It was determined that while exposure of yeast to increasing concentrations of DMSO resulted in decreasing cell viability, it did not cause cell lysis or protein leakage from the cells. The inclusion of DMSO in growth medium resulted in the conversion of yeast cultures to respiratory deficient petites. This mutagenic effect requires cell growth for its expression.     

Ultrastructural features of agouti (Dasyprocta aguti) preantral follicles cryopreserved using dimethyl sulfoxide, ethylene glycol and propanediol

The objective was to develop an efficient protocol for cryopreservation of agouti (Dasyprocta aguti) ovarian tissue. Agouti ovarian fragments were placed, for 10 min, in a solution containing MEM and fetal bovine serum plus 1.5 M dimethyl sulfoxide (DMSO), ethylene glycol (EG) or propanediol (PROH); some of those fragments were subsequently cryopreserved in a programmable freezer. After exposure and/or thawing, all samples were fixed in Carnoy prior to histological analysis. To evaluate ultrastructure, follicles from the control and all cryopreserved treatments were fixed in Karnovsky and processed for transmission electron microscopy. After exposure and freezing, there was a significant decrease in the percentage of morphologically normal preantral follicles in all treatments when compared to the control (92.67 ± 2.79, mean ± SD). However, there were no significant difference when the exposure and freezing procedures were compared using the same cryoprotectant. Moreover, there was no significant difference among cryoprotectants at the time of exposure (DMSO: 64.7 ± 3.8; EG: 70.7 ± 11.2, PROH: 63.3 ± 8.5) or after freezing (DMSO: 60.6 ± 3.6, EG: 64.0 ± 11.9; PROH: 62.0 ± 6.9). However, only follicles frozen with PROH had normal ultrastructure. In conclusion, preantral follicles enclosed in agouti ovarian tissue were successfully cryopreserved using 1.5 M PROH, with satisfactory maintenance of follicle morphology and ultrastructure.     

The effects of dimethyl sulfoxide on the kinetics of tubulin assembly

The kinetics of tubulin assembly were examined in the absence and presence of dimethyl sulfoxide at 37 degrees C. Inclusion of 1.4 M (10%) dimethyl sulfoxide lowered the critical protein concentration about 8-10-fold, from 9.4 microM in the absence of the organic solvent to 1.1 microM in its presence. This decrease was due solely to an effect on k-, the off rate constant. The on rate constant k+, was essentially unaffected. Another effect of dimethyl sulfoxide was in the nucleation process. The pseudo-first-order rate constant of elongation, kapp (k+[m]), was greatly increased by inclusion of dimethyl sulfoxide. This was due to an increase in the microtubule number concentration, [m]. The microtubules formed in the presence of dimethyl sulfoxide were much shorter than those formed in its absence, accounting for the higher number concentration. The nucleation number, n, was calculated by plots of ln kapp vs. ln c0 or ln t10% vs. ln c0, and the value appeared to be about 4 to 5, although some variability was found. It was shown that a plot of kapp vs. c0 to determine n, is not appropriate because of the inability to distinguish between linear and curved plots in the range of tubulin concentration used in assembly studies.     

Structure and metastability of N-lignocerylgalactosylsphingosine (cerebroside) bilayers

Differential scanning calorimetry (DSC) and X-ray diffraction have been used to study hydrated N-lignocerylgalactosylsphingosine (NLGS) bilayers. DSC of fully hydrated NLGS shows an endothermic transition at 69-70 degrees C, immediately followed by an exothermic transition at 72-73 degrees C; further heating shows a high-temperature (Tc = 82 degrees C), high-enthalpy (delta H = 15.3 kcal/mol NLGS) transition. Heating to 75 degrees C, cooling to 20 degrees C and subsequent reheating shows no transitions at 69-73 degrees C; only the high-temperature (82 degrees C), high-enthalpy (15.3 kcal/mol) transition. Two exothermic transitions are observed on cooling; for the upper transition its temperature (about 65 degrees C) and enthalpy (about 6 kcal/mol NLGS) are essentially independent of cooling rate, whereas the lower transition exhibits marked changes in both temperature (30----60 degrees C) and enthalpy (2.2----9.5 kcal/mol NLGS) as the cooling rate decreases from 40 to 0.625 Cdeg/min. On reheating, the enthalpy of the 69-70 degrees C transition is dependent on the previous cooling rate. The DSC data provide clear evidence of conversions between metastable and stable forms. X-ray diffraction data recorded at 26, 75 and 93 degrees C show clearly that NLGS bilayer phases are present at all temperatures. The X-ray diffraction pattern at 75 degrees C shows a bilayer periodicity d = 65.4 A, and a number of sharp reflections in the wide-angle region indicative of a crystalline chain packing mode. This stable bilayer form converts to a liquid-crystal bilayer phase; at 93 degrees C, the bilayer periodicity d = 59.1 A, and a diffuse reflection at 1/4.6 A-1 is observed. The diffraction pattern at 22 degrees C represents a combination of the stable and metastable low-temperature bilayer forms. NLGS exhibits a complex pattern of thermotropic changes related to conversions between metastable (gel), stable (crystalline) and liquid-crystalline bilayer phases. The structure and thermotropic properties of NLGS are compared with those of hydrated N-palmitoylgalactosylsphingosine reported previously (Ruocco, M.J., Atkinson, D., Small, D.M., Skarjune, R.P., Oldfield, E. and Shipley, G.G. (1981) Biochemistry 20, 5957-5966).     

Polar and hydrophobic effects on ester aminolysis in dimethyl sulfoxide

Aminolysis of various carboxyl-containing esters by several tetra-, tri-, and diamines was kinetically studied in dimethyl sulfoxide. Rates were measured in the presence or absence of added sulfuric acid with the amine concentration being much greater than the ester concentration. In some reactions, pseudo-first-order rate constants manifested saturation kinetic behavior with respect to the total amine concentration, indicating the formation of complexes between the amines and the esters. The complex formation was most efficient when the carboxyl group of the ester substrate was located at the meta position to the ester group. In addition, the complex formation was facilitated by hydrophobic amines. In order to explain the positional stereoselectivity and the hydrophobic effects observed in the kinetic study, a structure of the complex is proposed. In this structure of the complex, two nitrogen atoms of the amine are linked by an intramolecular hydrogen bond and then further interact with the two carbonyl oxygen atoms of the substrate. In addition, the hydrophobic interaction between the hydrophobic portion of the amine and the benzene ring of the substrate stabilizes the complex. Dimethyl sulfoxide accommodates both the polar and the hydrophobic interactions that are needed in the formation of the complex, mimicking the microenvironment of enzyme active sites.     

二甲亚砜对酵母多糖致肠道屏障损伤的保护作用

目的：探讨二甲亚砜（DMSO）对酵母多糖诱导的肠道炎性因子释放及肠屏障功能损伤的影响。方法：SD大鼠随机分为4组：生理盐水组（SS组）,DMSO组（DS组）,酵母多糖+生理盐水组（ZS组）和酵母多糖+ DMSO组（ZD组）。每组又分为伤后4 h和24 h两个亚组。检测肠组织细胞因子TNF-α和IL-10含量和血中二胺氧化酶（DAO）活性,并对肠损伤程度进行组织学评分。结果：与ZS组相应时间点相比,ZD组肠组织TNF-α含量减少、IL-10含量增加,血中DAO活性降低,肠绒毛损伤减轻、肠损伤评分降低。结论：DMSO可抑制酵母多糖引起的肠组织炎性因子释放,减轻肠屏障损伤程度。     

Cryoprotection by dimethyl sulfoxide and dimethyl sulfone

Preservation of cells and tissues at low temperatures requires the presence of effective cryoprotectants with low toxicity to which cells are relatively permeable. Two similar compounds, dimethyl sulfoxide (DMSO) and dimethyl sulfone (DMSO2), exhibit both features for cryoprotectants, yet DMSO is a very effective cryoprotectant while DMSO2 is ineffective. This anomaly was investigated by relating observations on the phase behavior of DMSO and DMSO2 in aqueous solutions to the recovery of human lymphocytes frozen in the presence of these compounds. The lack of cryoprotection in the presence of DMSO2 appears to be due to the precipitation of DMSO2 from the solution at subzero temperatures. The observation of reduced cell recovery after freezing with increasing concentrations of DMSO2 implies that cell damage is related to the amount of solid DMSO2 present. Precipitation of DMSO2 occurs both intra- and extracellularly, but it is argued that intracellular precipitation of DMSO2 is the damaging phenomenon. Cryoprotective compounds are normally selected based on the criteria of low toxicity and permeability to the plasma membrane. An additional condition, solubility, must be included for interpretation of experimental data and for development of effective protocols for cryopreservation.     

Differential effects of dimethyl sulfoxide on human platelet aggregation and arachidonic acid metabolism

DMSO inhibited human platelet aggregation induced by ADP, AA, PAF, or collagen in a concentration-related manner, in vitro. DMSO was a more effective inhibitor for aggregation induced by ADP and collagen than PAF or AA. However, in vivo experiments on rabbits showed that DMSO did not protect rabbits against death from pulmonary platelet thrombosis induced by AA. On the other hand, DMSO (1-30% v/v) had no effect on thromboxane production by platelets incubated with [14C]AA. Moreover, DMSO stimulated PGE2 production by bovine seminal vesicle PG synthase. DMSO also stimulated the production of 12-HETE but inhibited the production of tri-HETE produced via lipoxygenase pathway. Since lipoxygenase products play an important role in inflammation, our data suggest that the anti-inflammatory effects of DMSO are probably not mediated via its action on AA metabolism.     

Growth inhibitory effects of dimethyl sulfoxide and dimethyl sulfone on vascular smooth muscle and endothelial cells in vitro

Summary The growth of bovine aortic smooth muscle and endothelial cells was studied after exposure to dimethyl sulfoxide (DMSO) or its major metabolite, dimethyl sulfone (DMSO₂). Both compounds caused a dose-dependent inhibition of cell growth as determined by [³H]thymidine incorporation and by counting the number of cells with time of exposure in culture. The IC₅₀ of DMSO (concentration which produces 50% inhibition of growth) was 1% for smooth muscle cells and 2.9% for endothelial cells. Similarly, the IC₅₀ of DMSO₂ was also 1% for smooth muscle cells, but was 1.8% for endothelial cells. After a 4-d exposure to either compound, the growth inhibition of smooth muscle cells was completely reversible at 1%, partially reversible at 2 to 3% and completely irreversible at 4%. By comparison, inhibition of endothelial cell growth was completely reversible up to 4% of either compound. It is concluded that the growth of smooth muscle cells was similarly inhibited by DMSO, and DMSO₂, but that smooth muscle cells were more susceptible than endothelial cells to the growth inhibitory effects of these compounds. In addition, DMSO₂ was a more potent inhibitor of cell growth than DMSO and its growth inhibition was less reversible than that produced by DMSO.     

The effects of dimethyl sulfoxide on the osmotic properties of a rat megakaryocytopoietic cell line

Dimethyl sulfoxide (DMSO) at 0.6 M alters the osmotic state of intracellular water in a line of rat megakaryocytopoietic cells. The response is a function of temperature. Maximal structuring of water occurs at 24.7 degrees C, while disorganization occurs at 30 and 37 degrees C. Little effect occurs at 3 and at 18 degrees C. Parallel measurements of membrane permeability to water indicate that DMSO inhibits the osmotic exit of water at all temperatures. Maximal inhibition occurs at 24.7 degrees C, the same temperature at which maximal organization of water occurs. These findings emphasize the possible role which water may play in explaining the diverse functions of DMSO as cryogenic substance, promoter of cell fusion, and stimulator of cell differentiation.