Atomistic-continuum model for probing the biomechanical properties of human erythrocyte membrane under extreme conditions
DOI10.1016/J.CMA.2017.06.033zbMath1439.74189OpenAlexW2735282800MaRDI QIDQ2310004
A. S. Ademiloye, L. W. Zhang, Kim Moew Liew
Publication date: 6 April 2020
Published in: Computer Methods in Applied Mechanics and Engineering (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.cma.2017.06.033
temperature effectelastic propertieserythrocyte membrane deformabilitylarge strains and deformationmultiscale Cauchy-Born framework
Membranes (74K15) Biomechanical solid mechanics (74L15) Cell biology (92C37) Molecular, statistical, and kinetic theories in solid mechanics (74A25)
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Cites Work
- Efficient and accurate simulations of deformable particles immersed in a fluid using a combined immersed boundary lattice Boltzmann finite element method
- Systematic coarse-graining of spectrin-level red blood cell models
- Numerical computation of the elastic and mechanical properties of red blood cell membrane using the higher-order Cauchy-Born rule
- A quasi-continuum model for human erythrocyte membrane based on the higher order Cauchy-Born rule
- A three-dimensional quasicontinuum approach for predicting biomechanical properties of malaria-infected red blood cell membrane
- The buckling of single-walled carbon nanotubes upon bending: the higher-order gradient continuum and mesh-free method
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