Freezing damage of bovine erythrocytes: Simulation using glycerol concentration changes at subzero temperatures

Abstract

When a cell is frozen and thawed, it is exposed to (i) lowered temperature, (ii) increased solute concentration during freezing, and (iii) decreased solute concentration during thawing. Without actually freezing the cells, an attempt has been made to simulate physical-chemical changes to which bovine erythrocytes are exposed when frozen and thawed in glycerol solutions. Experimentally, the study consisted of suspending erythrocytes in 1, 2, or 3 m glycerol at 20 °C for various times and then exposing them to each of several dilution sequences. The dilution sequences were: (i) transfer from the initial glycerol concentration at 20 °C into the same concentration at −5 °C, (ii) transfer into an increased glycerol concentration at 20 °C, (iii) transfer into an increased followed by a decreased glycerol concentration at 20 °C, (iv) transfer into an increased glycerol concentration at −5 °C, and (v) transfer into an increased followed by a decreased glycerol concentration at −5 °C. This last sequence is analogous to the exposure that cells undergo at subzero temperatures to increased solute concentration during freezing and decreased solute concentration during thawing. This dilution sequence yielded a survival pattern very similar to that obtained when bovine erythrocytes are frozen and thawed, and thus does appear to mimic freezing damage. It is concluded that a major factor in freezing damage is the extent to which a cell must shrink or swell to achieve osmotic equilibrium at subzero temperatures in partially frozen or thawed solutions.