TY - JOUR
T1 - The effect of EIF dynamics on the cryopreservation process of a size distributed cell population
AU - Fadda, S.
AU - Briesen, H.
AU - Cincotti, A.
N1 - Funding Information:
The Fondazione Banco di Sardegna , Italy, and DAAD ( Deutscher Akademischer Austausch Dienst ), Germany, are gratefully acknowledged for the financial support of the project “Crioconservazione di cellule staminali da cordone ombelicale (2010)” and the fellowship within the academic exchange program (2010), respectively. Finally, we would like to thank Dr. Anthony M. Reilly for careful proofreading of the manuscript.
PY - 2011/6
Y1 - 2011/6
N2 - Typical mathematical modeling of cryopreservation of cell suspensions assumes a thermodynamic equilibrium between the ice and liquid water in the extracellular solution. This work investigates the validity of this assumption by introducing a population balance approach for dynamic extracellular ice formation (EIF) in the absence of any cryo-protectant agent (CPA). The population balance model reflects nucleation and diffusion-limited growth in the suspending solution whose driving forces are evaluated in the relevant phase diagram.This population balance description of the extracellular compartment has been coupled to a model recently proposed in the literature [Fadda et al., AIChE Journal, 56, 2173-2185, (2010)], which is capable of quantitatively describing and predicting internal ice formation (IIF) inside the cells. The cells are characterized by a size distribution (i.e. through another population balance), thus overcoming the classic view of a population of identically sized cells.From the comparison of the system behavior in terms of the dynamics of the cell size distribution it can be concluded that the assumption of a thermodynamic equilibrium in the extracellular compartment is not always justified. Depending on the cooling rate, the dynamics of EIF needs to be considered.
AB - Typical mathematical modeling of cryopreservation of cell suspensions assumes a thermodynamic equilibrium between the ice and liquid water in the extracellular solution. This work investigates the validity of this assumption by introducing a population balance approach for dynamic extracellular ice formation (EIF) in the absence of any cryo-protectant agent (CPA). The population balance model reflects nucleation and diffusion-limited growth in the suspending solution whose driving forces are evaluated in the relevant phase diagram.This population balance description of the extracellular compartment has been coupled to a model recently proposed in the literature [Fadda et al., AIChE Journal, 56, 2173-2185, (2010)], which is capable of quantitatively describing and predicting internal ice formation (IIF) inside the cells. The cells are characterized by a size distribution (i.e. through another population balance), thus overcoming the classic view of a population of identically sized cells.From the comparison of the system behavior in terms of the dynamics of the cell size distribution it can be concluded that the assumption of a thermodynamic equilibrium in the extracellular compartment is not always justified. Depending on the cooling rate, the dynamics of EIF needs to be considered.
KW - Cell number density distribution
KW - Extracellular ice formation
KW - Intracellular ice formation
KW - Membrane permeability
KW - Population balance
UR - http://www.scopus.com/inward/record.url?scp=79956066198&partnerID=8YFLogxK
U2 - 10.1016/j.cryobiol.2011.03.006
DO - 10.1016/j.cryobiol.2011.03.006
M3 - Article
C2 - 21463613
AN - SCOPUS:79956066198
SN - 0011-2240
VL - 62
SP - 218
EP - 231
JO - Cryobiology
JF - Cryobiology
IS - 3
ER -