RESUMO
The mechanical microenvironment of cells plays a critical role in regulating the physiological function of cells. Cells in vivo are often subjected to a variety of mechanical forces from their mechanical micro-environment, such as shear, tension, and compression. At the same time, cells can adhere to the extracellular matrix (ECM) through adhesion molecules (such as integrin-ligand binding), and further sense the stiffness of the ECM. Cell mechanics mainly studies the properties and behavior of living cells under mechanical forces, and how they relate to cell functions. This review summarized the advances in cell mechanics in 2022, focusing on integrin-ligand interactions and the effects of matrix stiffness and mechanical forces on cell physiological behavior and morphogenesis.
RESUMO
Cells are in complicated mechanical and physical microenvironment in vivo. The former mainly includes flow shear, tension, compression or torsion, and the latter covers stiffness and topography of extracellular matrix, spatial location, volume constraint or osmotic pressure, featured with various types, patterns, and parameters of mechanical or physical loading. Cell biomechanics mainly focuses on the alteration of mechanical properties of cells and the mechanical remodeling of subcellular components, the cell development, growth, proliferation, differentiation, and apoptosis under distinct mechanical stimuli, and the cellular sensation, transmission, transduction, and responses to external forces. This review summarized the major progresses in cell biomechanics in 2021, including studies on cardiomyocytes, endothelial cells, osteoblasts, immune cells, cancer cells and stem cells, as well as the related new techniques.
RESUMO
With the regulation of mechanical microenvironment being realized as an important role playing in the differentiation of bone marrow mesenchymal stem cells (BMSCs), the systematic researches on stem cells are gradually deepened into the extended cellular biomechanical field, which lead to a hot research focus on cellular biomechanical properties, basic mechanical structure units and network-like mechanical architecture among cells. In this paper the analysis on mechanical properties of BMSCs and mechanical molecular basic research on integrins and cadherins are reviewed, and the main frame of network like mechanical regulation is speculated and constructed, combined with the internal bony structure and mechanical geometric properties of the tunneling nanotubes (TNTs). The possibility of synergistic effect among the above important mechanical structures in the network-like mechanical microenvironment is also investigated.