Continuum Mechanics Analysis of Fracture Progression in the Vitrified Cryoprotective Agent DP6

Overview

Journal J Biomech Eng

Publisher American Society of Mechanical Engineers

Date 2008 Apr 17

PMID 18412493

Citations 13

Authors

Paul S Steif

Matthew C Palastro

Yoed Rabin

Affiliations

Soon will be listed here.

Abstract

As part of an ongoing effort to study the continuum mechanics effects associated with cryopreservation, the current report focuses on the prediction of fracture formation in cryoprotective agents. Fractures had been previously observed in 1 ml samples of the cryoprotective agent cocktail DP6, contained in a standard 15 ml glass vial, and subjected to various cooling rates. These experimental observations were obtained by means of a cryomacroscope, which has been recently presented by the current research team. High and low cooling rates were found to produce very distinct patterns of cracking. The current study seeks to explain the observed patterns on the basis of stresses predicted from finite element analysis, which relies on a simple viscoelastic constitutive model and on estimates of the critical stress for cracking. The current study demonstrates that the stress, which results in instantaneous fracture at low cooling rates, is consistent with the stress to initiate fracture at high cooling rate. This consistency supports the credibility of the proposed constitutive model and analysis, and the unified criterion for fracturing, that is, a critical stress threshold.

Citing Articles

Large surface deformation due to thermo-mechanical effects during cryopreservation by vitrification - mathematical model and experimental validation.

Vispute D, Solanki P, Rabin Y PLoS One. 2023; 18(3):e0282613.

PMID: 36893176 PMC: 9997942. DOI: 10.1371/journal.pone.0282613.

PERSPECTIVE: Temperature-dependent density and thermal expansion of cryoprotective cocktails.

Solanki P, Rabin Y Cryo Letters. 2022; 43(1):1-9.

PMID: 35315864 PMC: 9248856.

Mathematical modeling of surface deformation during vitrification.

Rabin Y Cryobiology. 2021; 102:34-41.

PMID: 34331902 PMC: 9006162. DOI: 10.1016/j.cryobiol.2021.07.014.

Ultrarapid Inductive Rewarming of Vitrified Biomaterials with Thin Metal Forms.

Manuchehrabadi N, Shi M, Roy P, Han Z, Qiu J, Xu F Ann Biomed Eng. 2018; 46(11):1857-1869.

PMID: 29922954 PMC: 6208886. DOI: 10.1007/s10439-018-2063-1.

Polarized light scanning cryomacroscopy, part II: Thermal modeling and analysis of experimental observations.

Feig J, Solanki P, Eisenberg D, Rabin Y Cryobiology. 2016; 73(2):272-81.

PMID: 27343139 PMC: 5420076. DOI: 10.1016/j.cryobiol.2016.06.004.

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