2013
DOI: 10.1016/j.actbio.2012.12.021
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Computational investigation of in situ chondrocyte deformation and actin cytoskeleton remodelling under physiological loading

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Cited by 35 publications
(33 citation statements)
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“…This framework has previously been implemented for the modeling of stress fiber contractility in a range of cell phenotypes (30)(31)(32)(33) and for simulation of the response of cells to applied shear (34) and compression (35,36) loading. Here it is adapted for the simulation of sarcomeric filaments in cardiomyocytes on the basis that both stress fibers and sarcomeric filaments are composed of and operate via actinmyosin interactions.…”
Section: Finite-element Modeling Predicts Stress-mediated Assembly Andmentioning
confidence: 99%
“…This framework has previously been implemented for the modeling of stress fiber contractility in a range of cell phenotypes (30)(31)(32)(33) and for simulation of the response of cells to applied shear (34) and compression (35,36) loading. Here it is adapted for the simulation of sarcomeric filaments in cardiomyocytes on the basis that both stress fibers and sarcomeric filaments are composed of and operate via actinmyosin interactions.…”
Section: Finite-element Modeling Predicts Stress-mediated Assembly Andmentioning
confidence: 99%
“…Stress fibre remodelling due to dynamic loading is not just important for an endothelial cell, but also for chondrocytes embedded in cartilage tissue, as investigated in the computational study of Dowling et al (2013). However, the modelling of the cell-substrate interface using a passive cohesive zone framework still represents a significant simplification.…”
Section: Case Study I: Resultsmentioning
confidence: 99%
“…At the lower spatial scale, cell deformation metrics can be used to drive cellular-subcellular scale models, i.e. incorporating the cytoskeleton (actin and tubulin) [30], to understand the mechanical load transmission to intracellular components, in particular to the nucleus. Similar submodelling can be performed for the extracellular matrix, for example, to evaluate microstructural-level loading of collagen fibres, which may provide the relationship between macroscopic tissue damage accumulation and microscale fibre failure [31].…”
Section: High-throughput Frameworkmentioning
confidence: 99%