Thermal properties of ethylene glycol aqueous solutions

Preventing ice crystallization by transforming liquids into an amorphous state, vitrification can be considered as the most suitable technique allowing complex tissues, and organs cryopreservation. This process requires the use of rapid cooling rates in the presence of cryoprotective solutions highly concentrated in antifreeze compounds, such as polyalcohols. Many of them have already been intensively studied. Their glass forming tendency and the stability of their amorphous state would make vitrification a reality if their biological toxicity did not reduce their usable concentrations often below the concentrations necessary to vitrify organs under achievable thermal conditions. Fortunately, it has been shown that mixtures of cryoprotectants tend to reduce the global toxicity of cryoprotective solutions and various efficient combinations have been proposed containing ethanediol. This work reports on the thermal properties of aqueous solutions with 40, 43, 45, 48, and 50% (w/w) of this compound measured by differential scanning calorimetry. The glass forming tendency and the stability of the amorphous state are evaluated as a function of concentration. They are given by the critical cooling rates v(ccr)above which ice crystallization is avoided, and the critical warming rates v(cwr) necessary to prevent ice crystallization in the supercooled liquid state during rewarming. Those critical rates are calculated using the same semi-empirical model as previously. This work shows a strong decrease of averaged critical cooling and warming rates when ethanediol concentration increases, V(ccr) and V(cwr) = 1.08 x 10 (10) K/min for 40% (w/w) whereas V(ccr) = 11 and V(cwr) = 853 K/min for 50% (w/w). Those results are compared with the corresponding properties of other dialcohols obtained by the same method. Ethylene glycol efficiency is between those of 1,2-propanediol and 1,3-propanediol.     

Schistosoma mansoni: Cryopreservation of schistosomula by two-step addition of ethanediol and rapid cooling

A simple, inexpensive, and highly effective technique for the Cryopreservation of schistosomula of Schistosoma mansoni is outlined by experiments designed to clarify the role of each of the steps involved. The technique consists of incubating schistosomula in 10% ($\text{v}\text{v}$) ethanediol for 10 min at 37 C followed by 5 min at 0 C and for a further 10 min in 35% ($\text{v}\text{v}$) ethanediol at 0 C. The schistosomular suspension is then aliquotted in 20-μl drops onto 40 × 5.5-mm glass slivers prepared from standard microscope coverslips, each drop being spread out to cover an area of approximately 15 × 4 mm. These glass slivers are then dropped directly into liquid nitrogen giving a cooling rate of approximately 5000 C min^?1. Survival is further improved if the schistosomula are at least 90 min old before Cryopreservation and if the frozen organisms are thawed in culture medium prewarmed to +42 C. Levels of survival obtained with this technique are consistently high: 44 to 60% as assessed by motility. From 400 ± 11 cryopreserved schistosomula injected intramuscularly into eight mice, a mean of 54.5 ± 16.3 adult worms were recovered representing an infection level of 13.7%, and which in turn represents 47.4% of the unfrozen control level.     

Vitrification media: toxicity,permeability, and dielectric properties

The aim of this study was to select a cryoprotectant for use in attempts to preserve tissues and organs by vitrification. The first step was to select a cell line with which to compare the toxicity of a range of commonly used cryoprotectants. An immortal vascular endothelial cell (ECV304) was exposed to vitrifying concentrations of four cryoprotectants: dimethyl sulfoxide (Me(2)SO; 45% w/w); 2,3 butanediol (BD; 32%); 1,2-propanediol (PD; 45%); and ethanediol (ED; 45%). Three times of exposure (1, 3, and 9 min) and two temperatures (22 and 2-4 degrees C) were studied. After removal of the cryoprotectant, the ability of the cells to adhere and divide in culture over a 2-day period was measured and expressed as a Cell Survival Index (CSI). There was no measurable loss of cells after exposure to the four cryoprotectants but 3-min exposure to BD, PD, or Me(2)SO at room temperature completely destroyed the ability of the cells to adhere and divide in culture. In contrast, exposure to all four cryoprotectants at 2-4 degrees C for up to 9 min permitted the retention of significant cell function, the CSIs, as a proportion of control, being 76.3+/-7.0% for BD, 63.6+/-7.1% for PD, 37.0+/-4.1 for Me(2)SO, and 33.2+/-3.0 for ED. The permeability properties of the cells for these four cryoprotectants was also measured at each temperature. Permeability to water was high, L(p) approximately equal 10(-7) cm/s/atm at 2-4 degrees C with all the cryoprotectants, but there were substantial differences in solute permeability: BD and PD were the most permeable at 2-4 degrees C (P(s)=4.1 and 3.0 x 10(-6) cm/s, respectively). Equilibration of intracellular cryoprotectant concentration was rapid, due in part to high water permeability; the cells were approximately 80% of their physiological volume after 10 min. Treatment at 2-4 degrees C with BD was the least damaging, but PD was not significantly worse. Exposure to vitrifying concentrations of ED and Me(2)SO, even at 2-4 degrees C, was severely damaging. Segments of rabbit carotid artery were treated with vitrifying concentrations of each of the two most favorable cryoprotectants, BD and PD, for 9 min. It was shown that each cryoprotectant reduced smooth muscle maximum contractility to a similar extent and abolished the acetylcholine response. However, vital staining revealed that exposure to BD also caused substantial damage to the endothelial lining, whereas the endothelium was completely intact after PD exposure, raising the possibility that the effect of PD on NO release may be reversible. In later stages of this project it is planned to use dielectric heating to rewarm the tissues and thereby avoid devitrification. The effects of each cryoprotectant on this mode of heating was therefore studied. Gelatin spheres containing vitrifiable concentrations of each cryoprotectant were rewarmed from -60 degrees C in a radiofrequency applicator. Because the uniformity of heating is related to the dielectric properties of the material, these properties were also measured. PD was the most suitable. These physical measurements, combined with the measurements of toxicity and permeability, indicate that PD is the most favorable cryoprotectant of those tested for use in subsequent stages of this study.     

Schistosoma mansoni: Interactive effects of irradiation and cryopreservation on parasite maturation and immunization of mice

Mechanically transformed schistosomula of Schistosoma mansoni were irradiated with levels of ⁶⁰Co irradiation between 2.5 and 54 krad, cryopreserved by the two-step addition of ethanediol and rapid cooling technique, and were injected intramuscularly into groups of mice which were perfused 40 days later. The schistosomula were either irradiated and then cryopreserved (IC) or cryopreserved and then irradiated in the frozen state (CI). Development into adult worms was prevented with 4 krad for IC schistosomula, but for CI schistosomula a small number of worms (1.6%) was recovered using 8.8 krad. A dose of 4 krad was sufficient to prevent development of unfrozen controls (I), but for schistosomula irradiated while exposed to ethanediol (EI), a dose of 7 krad was required. Using the different protocols, the peak levels of protection against a challenge infection were achieved with 9 (IC) and 16 krad (CI), compared to 20 krad for unfrozen schistosomula (I) reported previously. The highest level of protection (65%) was achieved with CI schistosomula. Possible interactions between the radioprotective and damaging effects of cryopreservation are discussed.