Matrix elasticity, cytoskeletal forces and physics of the nucleus: how deeply do cells ‘feel’ outside and in?

Buxboim, Amnon; Ivanovska, Irena L.; Discher, Dennis E.

doi:10.1242/jcs.041186

Cited by 364 publications

(352 citation statements)

References 107 publications

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“…The main objective here is to define a velocity-dependent opposing force associated with the viscous character of the substrate. Referring to Stokes' drag regime, the drag force acting on a spherical cell can be presented as [48,71] F drag = 6πrηv (8) where r and v are cell radius and velocity, respectively, while η is medium viscosity. Cells send out local protrusions to probe their environment by exerting a random protrusion force.…”

Section: Cells Effective Forcesmentioning

confidence: 99%

“…Here, it is assumed that there are magnetic nanoparticles encapsulated within a rigid sphere located in the middle of the substrate. Initially, the substrate stiffness is set to lower bounds of neurogenic (0.1-1 kPa), chondrogenic (20-25 kPa) and osteogenic cells (30-45 kPa) tissue stiffness [8]. Then, cell-cultured hydrogel is induced by a force in the longitudinal direction to increase the substrate rigidity.…”

Section: Force-induced Substrate Deformationmentioning

confidence: 99%

“…To avoid repeating MSC proliferation, the results are represented starting from the instant of MSC differentiation. First, it is con- sidered that the substrate stiffness is equal to the lower bound of osteogenic substrates (30 kPa) [8] without inducing any internal force within the substrate. In order to study the effect of forceinduced substrate, an internal force (5 µN) is applied in the middle of the substrate in the longitudinal direction which increases the substrate local stiffness around a rigid sphere.…”

Section: Msc Lineage Specification Within Force-free and Forceinducedmentioning

confidence: 99%

“…Again, to avoid the demonstration of the MSC proliferation process, the results are presented starting from the moment of MSC differentiation. The substrate stiffness is set to be the lower bound of chondrogenic tissue stiffness (20 kPa) [8] and it is induced by a 3 µN force in the longitudinal direction. MSC located near the rigid sphere is gradually maturated.…”

Section: Msc Lineage Specification Within Force-free and Forceinducedmentioning

confidence: 99%

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Numerical modeling of cell differentiation and proliferation in force-induced substrates via encapsulated magnetic nanoparticles

Mousavi

Doweidar

2016

Computer Methods and Programs in Biomedicine

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Cell migration, differentiation, proliferation and apoptosis are the main processes in tissue regeneration. Mesenchymal Stem Cells (MSCs) have the potential to differentiate into many cell phenotypes such as tissue-or organ-specific cells to perform special functions. Experimental observations illustrate that differentiation and proliferation of these cells can be regulated according to internal forces induced within their Extracellular matrix (ECM). The process of how exactly they interpret and transduce these signals is not well understood. Therefore, a previously developed three-dimensional (3D) computational model is here extended and employed to study how force-free substrates (FFS) and force-induced substrate (FIS) control cell differentiation and/or proliferation during the mechanosensing process. Consistent with experimental observations, it is assumed that cell internal deformation (a mechanical signal) in correlation with the cell maturation state directly triggers cell differentiation and/or proliferation. ECM is modeled as Neo-Hookean hyperelastic material assuming that cells are cultured within 3D nonlinear hydrogels. In agreement with wellknown experimental observations, the findings here indicate that within neurogenic (0.1-1 kPa), chondrogenic (20-25 kPa) and osteogenic (30-45 kPa) substrates, MSC differentiation and cell proliferation can be precipitated by inducing the substrate with an internal force. Therefore, cells require a longer time to grow and maturate within force-free substrates than withen force-induced substrates. In the instance of MSC differentiation into a compatible phenotype, the magnitude of the net traction force increases within chondrogenic and osteogenic substrates while it reduces within neurogenic substrates. This is consistent with experimental studies and numerical works recently published by the same authors. However, in all cases the magnitude of the net traction force considerably increases at the instant of cell proliferation because of cell-cell interaction. Consequently, the present model provides new perspectives to delineate the role of force-induced substrates in remotely controlling the cell fate during cell-matrix interaction, which open the door for new tissue regeneration methodologies.

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Section: Cells Effective Forcesmentioning

confidence: 99%

Section: Force-induced Substrate Deformationmentioning

confidence: 99%

Section: Msc Lineage Specification Within Force-free and Forceinducedmentioning

confidence: 99%

Section: Msc Lineage Specification Within Force-free and Forceinducedmentioning

confidence: 99%

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Numerical modeling of cell differentiation and proliferation in force-induced substrates via encapsulated magnetic nanoparticles

Mousavi

Doweidar

2016

Computer Methods and Programs in Biomedicine

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“…Previous experimental studies have established the mechanical link between the cytoskeleton and the nucleus (Buxboim et al 2010), and, in particular, that the removal of nuclear lamins also leads to disruption of the cytoskeleton (Broers et al 2004). In the current study, the nucleus and the cytoplasm are simulated as two separate but continuous regions and it is important to note that no movement is permitted between the cytoplasm and the nucleus.…”

Section: Simulations Reveal Thatmentioning

confidence: 99%

Cellular contractility and substrate elasticity: a numerical investigation of the actin cytoskeleton and cell adhesion

Ronan

Deshpande

McMeeking

et al. 2013

Biomech Model Mechanobiol

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Publication InformationRonan, William, Deshpande, Vikram S., McMeeking, Robert M., & McGarry, J. Patrick. (2014). Cellular contractility and substrate elasticity: a numerical investigation of the actin cytoskeleton and cell adhesion. Biomechanics found to alter the range of substrate stiffness that cause the most significant changes in stress fibre and focal adhesion formation. Furthermore, stress fibre and focal adhesion formation evolve as a cell spreads on a substrate and leading to the formation of bands of fibres leading from the cell periphery over the nucleus. Inhibiting the formation of FAs during cell spreading is found to limit stress fibre formation. The predictions of this mutually dependent material-interface framework are strongly supported by experimental observations of cells adhered to elastic substrates and offer insight into the interdependent biomechanical processes regulating stress fibre and focal adhesion formation.

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Strategy for a Biomimetic Paradigm in Dental and Craniofacial Tissue Engineering

et al. 2013

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Matrix elasticity, cytoskeletal forces and physics of the nucleus: how deeply do cells ‘feel’ outside and in?

Cited by 364 publications

References 107 publications

Numerical modeling of cell differentiation and proliferation in force-induced substrates via encapsulated magnetic nanoparticles

Numerical modeling of cell differentiation and proliferation in force-induced substrates via encapsulated magnetic nanoparticles

Cellular contractility and substrate elasticity: a numerical investigation of the actin cytoskeleton and cell adhesion

Strategy for a Biomimetic Paradigm in Dental and Craniofacial Tissue Engineering

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