Modeling evolution of cell morphology under stretching.

The mechanical stimulation of cells from the surrounding environment is an important life activity. However, there has been a lack of dynamically quantitative analysis of cell morphology under mechanical stimulations. A theoretical model for the evolution of cell morphology under stretching is proposed by analyzing the transformation between cell deformation energy and adhesion energy. The images of the evolution show that detachment of the adhesion membrane or re-adhesion of the cell, causes a decrease or increase of the adhesion area, respectively. In addition to the stretching amplitude and velocity, we found that the duration of the stretching stage and the no stretching stage can affect the cell morphology during cyclic stretching. The theoretical model explains some counter-intuitive experimental results and provides many quantitative insights into understanding the physical mechanisms of cell adhesion under stretching. This study can provide a useful guide to control cell adhesion under mechanical stimulations.