Comparison of actual vs. synthesized ternary phase diagrams for solutes of cryobiological interest

Kleinhans, F.W.; Mazur, Péter

doi:10.1016/j.cryobiol.2007.01.007

Cited by 69 publications

(91 citation statements)

References 8 publications

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“…Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. The bottom three lines of Table 1 and the bottom half of Table 2 show the computed values for the right-hand five columns based on the synthesized ternary phase diagrams [3]. The chief conclusion is that now the values for the unfrozen fractions at the flash temperature for the oocytes in the EG solutions are in rather close agreement with the values obtained for oocytes in glycerol and in PBS alone.…”

supporting

confidence: 74%

“…In the ternary phase diagrams for the other CPAs, the downward curvature of the plots (isopleths) with increasing solute concentration becomes greater as the weight ratio of CPA to salt (R) decreases. That is so with the synthesized ternary EG plots in [3]; however, it is not the case, or is much less the case, with the Woods et al data in [8]. For these two reasons, we concluded that the synthesized phase diagrams are closer to reality than are the Woods et al data.…”

contrasting

confidence: 47%

“…However, in the case of EG, the agreement is not good. In addition, as pointed out in [3] there is a substantive internal discrepency in the Woods et al experimental data for EG [8]. In the ternary phase diagrams for the other CPAs, the downward curvature of the plots (isopleths) with increasing solute concentration becomes greater as the weight ratio of CPA to salt (R) decreases.…”

mentioning

confidence: 89%

“…Subsequently, Kleinhans and Mazur [3] have compared published experimental ternary phase diagrams for the cryoprotective agents (CPA) glycerol, sucrose, DMSO, and EG in NaCl with those that they synthesized by adding the melting points of the binary system CPA/water and the binary system NaCl/water. In the case of glycerol, sucrose, and DMSO, the agreement between the experimental and synthesized ternary phase diagrams is very good.…”

mentioning

confidence: 99%

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Relationship between intracellular ice formation in oocytes of the mouse and Xenopus and the physical state of the external medium—A revisit

Mazur

Kleinhans

2008

Cryobiology

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We have previously reported that intracellular ice formation (IIF) in mouse oocytes suspended in glycerol/PBS solutions or ethylene glycol (EG)/PBS solutions and rapidly cooled to −50°C or below occurs at temperatures where a critical fraction of the external water remains unfrozen (Cryobiology 51, 2005, 29-53; 54, 2007, 223-233). For mouse oocytes in PBS or glycerol/PBS that fraction is 0.06; for oocytes in EG that fraction was calculated to be 0.13, more than double. The fractions unfrozen are computed from ternary phase diagrams. In the previous publication, we used the EG data of Woods et al. (Cryobiology 38,1999, 403-407). Since then, we have determined that ternary phase diagrams for EG/NaCl/water synthesized by summing binary phase data for EG/water NaCl/water gives substantially different curves, which seem more realistic (Cryobiology 54, 2007, 212-222). Unfrozen fractions at the temperatures of IIF computed from these synthesized phase diagrams are about half of those calculated from the Woods et al. data, and are in close agreement with the computations for glycerol; i.e., IIF occurs when about 92-94% of the external water is frozen. A parallel paper was published by Guenther et al. (Cryobiology 52, 2006, 401-416) on IIF in oocytes of the frog Xenopus. It too examined whether the temperatures of IIF were related to the unfrozen fractions at those temperatures. It also used the Woods et al. ternary phase data to calculate the unfrozen fractions for EG solutions. As reported here, once again the values of these unfrozen fractions are substantially different from those calculated using synthesized phase diagrams. With the latter, the unfrozen fractions at IIF become very similar for EG and glycerol. KeywordsIntracellular ice formation; oocytes; mouse; Xenopus; unfrozen fraction; phase diagrams Our laboratory has recently reported on several variables that influence the temperature at which intracellular ice forms in mouse oocytes and in oocytes of the frog Xenopus. [5,1] that are cooled rapidly enough to ensure that they undergo intracellular ice formation (IIF); namely 20°C/min and 10°C/min, respectively. One major variable affecting the temperature of IIFin mouse oocytes was the concentration of ethylene glycol (EG) or glycerol present in the *Corresponding author. Fax: +1 865 974 8027 e-mail address: pmazur@utk.edu. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. The bottom three lines of Table 1 and the bottom half of Table 2 show the computed values for the right-hand five columns based on the synthesized ternary phase diagrams [3]. The chief conclus...

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supporting

confidence: 74%

contrasting

confidence: 47%

mentioning

confidence: 89%

mentioning

confidence: 99%

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Relationship between intracellular ice formation in oocytes of the mouse and Xenopus and the physical state of the external medium—A revisit

Mazur

Kleinhans

2008

Cryobiology

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“…3 Other research groups have applied our equation to v) a quaternary system of water-CPA-sugarsalt, 43 and vi) aqueous solutions of two micelle-forming non-ionic surfactants. 44 Although there have been other multi-solute solution theories able to make predictions directly from single solute information that apply accurately to specific examples, 49 our osmotic virial approach is the most broadly applied. 3,26,27,[42][43][44] It is important to point out that some nonlinear relationships have been presented for osmolality of cytoplasm in bacteria (i.e., Escherichia coli); 50,51 however, in those studies the nonlinearity arose from different phenomena than those being studied here.…”

Section: Introductionmentioning

confidence: 99%

Non-ideal Solution Thermodynamics of Cytoplasm

Ross-Rodriguez

Elliott

McGann

2012

Biopreservation and Biobanking

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Quantitative description of the non-ideal solution thermodynamics of the cytoplasm of a living mammalian cell is critically necessary in mathematical modeling of cryobiology and desiccation and other fields where the passive osmotic response of a cell plays a role. In the solution thermodynamics osmotic virial equation, the quadratic correction to the linear ideal, dilute solution theory is described by the second osmotic virial coefficient. Herein we report, for the first time, intracellular solution second osmotic virial coefficients for four cell types [TF-1 hematopoietic stem cells, human umbilical vein endothelial cells (HUVEC), porcine hepatocytes, and porcine chondrocytes] and further report second osmotic virial coefficients indistinguishable from zero (for the concentration range studied) for human hepatocytes and mouse oocytes.

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Prediction of ice content in biological model solutions when frozen under high pressure

Guignon

Aparicio

Otero

et al. 2009

Biotechnology Progress

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High pressure is, at least, as effective as cryoprotective agents (CPAs) and are used for decreasing both homogenous nucleation and freezing temperatures. This fact gives rise to a great variety of possible cryopreservation processes under high pressure. They have not been optimized yet, since they are relatively recent and are mainly based on the pressure-temperature phase diagram of pure water. Very few phase diagrams of biological material are available under pressure. This is owing to the lack of suitable equipment and to the difficulties encountered in carrying out the measurements. Different aqueous solutions of salt and CPAs as biological models are studied in the range of 0 degrees C down to -35 degrees C, 0.1 up to 250 MPa, and 0-20% w/w total solute concentration. The phase transition curves of glycerol and of sodium chloride with either glycerol or sucrose in aqueous solutions are determined in a high hydrostatic pressure vessel. The experimental phase diagrams of binary solutions were well described by a third-degree polynomial equation. It was also shown that Robinson and Stokes' equation at high pressure succeeds in predicting the phase diagrams of both binary and ternary solutions. The solute cryoconcentration and the ice content were calculated as a function of temperature and pressure conditions during the freezing of a binary solution. This information should provide a basis upon which high-pressure cryopreservation processes may be performed and the damages derived from ice formation evaluated.

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Comparison of actual vs. synthesized ternary phase diagrams for solutes of cryobiological interest

Cited by 69 publications

References 8 publications

Relationship between intracellular ice formation in oocytes of the mouse and Xenopus and the physical state of the external medium—A revisit

Relationship between intracellular ice formation in oocytes of the mouse and Xenopus and the physical state of the external medium—A revisit

Non-ideal Solution Thermodynamics of Cytoplasm

Prediction of ice content in biological model solutions when frozen under high pressure

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