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- Title
Cellular mechanosensitivity to substrate stiffness decreases with increasing dissimilarity to cell stiffness.
- Authors
Abdalrahman, Tamer; Dubuis, Laura; Green, Jason; Davies, Neil; Franz, Thomas
- Abstract
Computational modelling has received increasing attention to investigate multi-scale coupled problems in micro-heterogeneous biological structures such as cells. In the current study, we investigated for a single cell the effects of (1) different cell-substrate attachment (2) and different substrate modulus $$\textit{E}_\mathrm{s}$$ on intracellular deformations. A fibroblast was geometrically reconstructed from confocal micrographs. Finite element models of the cell on a planar substrate were developed. Intracellular deformations due to substrate stretch of $$\lambda =1.1$$ , were assessed for: (1) cell-substrate attachment implemented as full basal contact (FC) and 124 focal adhesions (FA), respectively, and $$\textit{E}_\mathrm{s}\,=\,$$ 140 KPa and (2) $$\textit{E}_\mathrm{s}\,=\,10$$ , 140, 1000, and 10,000 KPa, respectively, and FA attachment. The largest strains in cytosol, nucleus and cell membrane were higher for FC (1.35 $$\text {e}^{-2}$$ , 0.235 $$\text {e}^{-2}$$ and 0.6 $$\text {e}^{-2}$$ ) than for FA attachment (0.0952 $$\text {e}^{-2}$$ , 0.0472 $$\text {e}^{-2}$$ and 0.05 $$\text {e}^{-2}$$ ). For increasing $$\textit{E}_\mathrm{s}$$ , the largest maximum principal strain was 4.4 $$\text {e}^{-4}$$ , 5 $$\text {e}^{-4}$$ , 5.3 $$\text {e}^{-4}$$ and 5.3 $$\text {e}^{-4}$$ in the membrane, 9.5 $$\text {e}^{-4}$$ , 1.1 $$\text {e}^{-4}$$ , 1.2 $$\text {e}^{-3}$$ and 1.2 $$\text {e}^{-3}$$ in the cytosol, and 4.5 $$\text {e}^{-4}$$ , 5.3 $$\text {e}^{-4}$$ , 5.7 $$\text {e}^{-4}$$ and 5.7 $$\text {e}^{-4}$$ in the nucleus. The results show (1) the importance of representing FA in cell models and (2) higher cellular mechanical sensitivity for substrate stiffness changes in the range of cell stiffness. The latter indicates that matching substrate stiffness to cell stiffness, and moderate variation of the former is very effective for controlled variation of cell deformation. The developed methodology is useful for parametric studies on cellular mechanics to obtain quantitative data of subcellular strains and stresses that cannot easily be measured experimentally.
- Subjects
MECHANOTRANSDUCTION (Cytology); STIFFNESS (Mechanics); FIBROBLASTS; CELL morphology; MATHEMATICAL models; FINITE element method
- Publication
Biomechanics & Modeling in Mechanobiology, 2017, Vol 16, Issue 6, p2063
- ISSN
1617-7959
- Publication type
Article
- DOI
10.1007/s10237-017-0938-y