Thermo-mechanics aspects of isochoric cryopreservation: A new modeling approach and comparison with experimental data

Thermo-mechanics aspects of isochoric cryopreservation: A new modeling approach and comparison with experimental data

A new mathematical model is proposed for the analysis of thermo-mechanics effects during isochoric cryopreservation. In that process, some ice crystallization in a fixed-volume container drives pressure elevation, which may be favorable to the preservation of biological material when it resides in t...

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Bibliographic Details
Published in:PloS one Vol. 17; no. 4; p. e0267852
Main Authors: Solanki, Prem K, Rabin, Yoed
Format: Journal Article
Language:English
Published: United States Public Library of Science 28-04-2022
Public Library of Science (PLoS)
Subjects:
Atmospheric conditions
Atmospheric models
Biological materials
Biology and Life Sciences
Computer and Information Sciences
Containers
Cooling
Cryopreservation
Cryopreservation - methods
Cryopreservation of organs, tissues, etc
Crystallization
Domains
Enthalpy
Experimental data
Experimentation
Fluid mechanics
Freezing
Heat transfer
Ice
Isochores
Laboratories
Mathematical models
Mechanical engineering
Mechanical properties
Mechanics
Methods
Modelling
Physical properties
Physical Sciences
Research and Analysis Methods
Shear stress
Solid mechanics
Temperature
Temperature measurement
Thermodynamics
Viscoelasticity
Viscosity
Vitrification
Water
United States
United States > US
Pittsburgh Pennsylvania
Pennsylvania
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Description
Summary:A new mathematical model is proposed for the analysis of thermo-mechanics effects during isochoric cryopreservation. In that process, some ice crystallization in a fixed-volume container drives pressure elevation, which may be favorable to the preservation of biological material when it resides in the unfrozen portion of the same container. The proposed model is comprehensive, integrating for the first time concepts from the disparate fields of thermodynamics, heat transfer, fluid mechanics, and solid mechanics. The novelty in this study is in treating the cryopreserved material as having a pseudo-viscoelastic behavior over a very narrow temperature range, without affecting the mechanical behavior of the material in the rest of the domain. This unique approach permits treating the domain as a continuum, while avoiding the need to trace freezing fronts and sperate the analysis to liquid and solid subdomains. Consistent with the continuum approach, the heat transfer problem is solved using the enthalpy approach. The presented analysis focusses on isochoric cooling of pure water between standard atmospheric conditions and the triple point of liquid water, ice Ih, and ice III (-22°C and 207.4 MPa). The proposed model is also applicable to isochoric vitrification, by substituting the pseudo-viscoelastic material model with the real viscosity model of the vitrifying material. Results of this study display good agreement with phase-diagram data at steady state, and with experimental data from the literature. Furthermore, this study provides a venue to discussing experimentation aspects of isochoric cryopreservation. The proposed model is further demonstrated on a 3D problem, while discussing scale considerations, crystallization conditions, and transient effects. Notably, the new model can be used to bridge the gap between limited pressure and temperature measurements during cryopreservation and the analysis of the continuum. Arguably, this study presents the most advanced thermo-mechanics model to solve practical problems relating to isochoric cryopreservation.
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Competing Interests: The authors have declared that no competing interests exist.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0267852