This work studied the viabilities of five types of cells (two yeast cells, Saccharomyces cerevisiae CBS 1171 and Candida utilis; two bacterial strains, Escherichia coli and Lactobacillus plantarum; and one human leukemia K562 cell) as a function of cooling rate during freezing. The range of investigated cooling rates extended from 5 to 30,000°C/min. Cell viability was classified into three ranges: (i) high viability for low cooling rates (5 to 180°C/min), which allow cell water outflow to occur completely and do not allow any intracellular crystallization; (ii) low viability for rapid cooling rates (180 to 5,000°C/min), which allow the heat flow to prevail over water outflow (in this case, cell water crystallization would occur as water was flowing out of the cell); (iii) high viability for very high cooling rates (>5,000°C/min), which allow the heat flow to be very rapid and induce intracellular crystallization and/or vitrification before any water outflow from the cell. Finally, an assumption relating cell death to the cell water crystallization as water is flowing out of the cell is made. In addition, this general cell behavior is different for each type of cell and seems to be moderated by the cell size, the water permeability properties, and the presence of a cell wall.The freeze-thawing process remains the principal method of cell preservation to date, and the high survival rates achieved by this method are of interest from both the biophysical and practical points of view. This is to ensure that the recovery of entire cell populations is free from the risk of possible subsequent alteration of its genetic composition.Cell cryopreservation, which is commonly used in the food and pharmaceutical industries, requires optimization for each type of microorganism. Moreover, each type of cell has its own protocol for freezing. Numerous researchers have attempted to develop methods that permit 100% preservation of freezethawing of diverse cellular specimens (3, 6), but some microorganisms cannot yet be preserved by freezing.For a better cell preservation some cryoprotectants such as glycerol or dimethyl sulfoxide can be used (8). These molecules improve the cell preservation by minimizing the cell water content (6) and/or supporting the vitrification occurrence (1) and finally by protecting the cell's constitutive macromolecules (2, 5).The freeze-thawing process constitutes a double stress for the cell, i.e., thermal and hyperosmotic stresses, which act simultaneously during cooling (15, 16). The scenario of cell evolution during slow freezing is well known (13). The water surrounding the cell freezes before the cell contents, because the cytoplasm is more concentrated than the growth medium, and because thermodynamically, the component with the largest volume will nucleate first (6, 16). This freezing increases the osmotic pressure of the medium, and the extracellular solutes become concentrated in the remaining liquid extracellular water. Consecutive osmosis will then dehydrate cells as water diffuses from the cy...