Add to ORKGThe well-established dependence of cell traction forces on the compliance of supporting matrices has been attributed to levels of force exerted on components in focal contacts. Here, use of novel, force-limited nanoscale tension gauges revealed that both force and substrate deformations govern cell decision-making during initial attachment to compliant substrates. We propose a mechanical model consistent with observed behavior. Upon formation of stable cell contacts, bond tension and tether rupture govern cell attachment, spreading, and focal adhesion maturation at force levels on individual receptors predicted by prior studies
For many cell types, growth, differentiation, and motility are dependent on receptor-mediated adhesi...
To address the question of how cell-generated forces regulate the organization and function of endot...
International audienceThere is compelling evidence that substrate stiffness affects cell adhesion as...
The well-established dependence of cell traction forces on the compliance of supporting matrices has...
Cell adhesion regulates critical cellular functions in adherent cells. Yet, the fundamental mechanis...
AbstractCells generate mechanical stresses via the action of myosin motors on the actin cytoskeleton...
By forming attachments and contracting, cells are able to exert forces on their surroundings and inf...
Numerous experimental studies have established that cells can sense the stiffness of underlying subs...
In this talk I describe our work to understand how cells sense and exert mechanical force across mul...
Extracellular protein matrices provide a rigidity interface exhibiting nano-mechanical cues that gui...
It is becoming increasingly clear that the mechanical properties of their environment play a crucial...
Numerous experimental studies have established that cells can sense the stiffness of underlying subs...
AbstractCell focal adhesions are micrometer-sized aggregates of proteins that anchor the cell to the...
Cells can sense the density and distribution of extracellular matrix (ECM) molecules by means of ind...
Strong mechanical forces can, obviously, disrupt cell-cell and cell-matrix adhesions, e.g., cyclic u...
For many cell types, growth, differentiation, and motility are dependent on receptor-mediated adhesi...
To address the question of how cell-generated forces regulate the organization and function of endot...
International audienceThere is compelling evidence that substrate stiffness affects cell adhesion as...
The well-established dependence of cell traction forces on the compliance of supporting matrices has...
Cell adhesion regulates critical cellular functions in adherent cells. Yet, the fundamental mechanis...
AbstractCells generate mechanical stresses via the action of myosin motors on the actin cytoskeleton...
By forming attachments and contracting, cells are able to exert forces on their surroundings and inf...
Numerous experimental studies have established that cells can sense the stiffness of underlying subs...
In this talk I describe our work to understand how cells sense and exert mechanical force across mul...
Extracellular protein matrices provide a rigidity interface exhibiting nano-mechanical cues that gui...
It is becoming increasingly clear that the mechanical properties of their environment play a crucial...
Numerous experimental studies have established that cells can sense the stiffness of underlying subs...
AbstractCell focal adhesions are micrometer-sized aggregates of proteins that anchor the cell to the...
Cells can sense the density and distribution of extracellular matrix (ECM) molecules by means of ind...
Strong mechanical forces can, obviously, disrupt cell-cell and cell-matrix adhesions, e.g., cyclic u...
For many cell types, growth, differentiation, and motility are dependent on receptor-mediated adhesi...
To address the question of how cell-generated forces regulate the organization and function of endot...
International audienceThere is compelling evidence that substrate stiffness affects cell adhesion as...