Chapter 2. Cell-Matrix Interactions that determine biomaterials function in vitro and in vivo] A. How cells pull onto and deform the matrix to which they attach themselves B Cell-matrix interactions control the spontaneous closure of wounds in organs. C. What happens when regeneration is induced?
Chapter 2. Cell-Matrix Interactions. [that determine biomaterials function in vitro and in vivo] A. How cells pull onto and deform the matrix to which they attach themselves. B. Cell-matrix interactions control the spontaneous closure of wounds in organs. C. What happens when regeneration is induced?
A. How cells pull onto and deform the matrix to which they attach themselves Cells develop contractile forces individually, not cooperatively Cell elongation, not contraction, eventually leads to matrix deformation Contractile forces are force-imited not displacement-limited
A. How cells pull onto and deform the matrix to which they attach themselves. • Cells develop contractile forces individually, not cooperatively. • Cell elongation, not contraction, eventually leads to matrix deformation. • Contractile forces are force-limited, not displacement-limited
a brief review or relevant structures cell membrane, transmembrane proteins, cell receptors(integrins), cytoplasm, matrix
A brief review or relevant structures: cell membrane, transmembrane proteins, cell receptors (integrins), cytoplasm, matrix
Definition of unit cell process Soluble Requlator A Cell Insoluble Product Soluble Requlator Regulator B Control volume dV Unit cel process confined conceptually in a control volume dv
5 Definition of unit cell process Cell + Insoluble Regulator Product Soluble Regulator A Soluble Regulator B Control volume dV Unit cell process confined conceptually in a control volume dV
a typified cell diagram showing cell-cell binding Image removed due to copyright considerations
A typified cell diagram showing cell-cell binding replace - redraw Image removed due to copyright considerations