Journal Article10.1016/J.JBIOMECH.2015.11.027
Continuum modeling of deformation and aggregation of red blood cells.
Daegeun Yoon,Donghyun You +1 more
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TL;DR: The present aggregation model is capable of predicting stress relaxation and stress-strain hysteresis, of which prediction is not possible using the commonly used Kelvin-Voigt model, and allows to predict various effects of physical parameters such as the osmotic pressure, the thickness of a glycocalyx layer, the penetration depth, and the permittivity, on the depletion and electrostatic energy among RBCs.
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About: This article is published in Journal of Biomechanics. The article was published on 26 Jul 2016. The article focuses on the topics: Continuum Modeling.
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Resolved CFD-DEM simulation of blood flow with a reduced-order RBC model
TL;DR: In this paper, the authors proposed an approach for efficient simulation of blood flow with several suspended red blood cells (RBCs), which can be employed for numerical investigation of bio-microfluidic applications.
Numerical simulation of deformed red blood cell by utilizing neural network approach and finite element analysis.
TL;DR: Considering the application of machine learning in material parameters identification, ML algorithm was combined with finite element (FE) method to identify the constitutive parameters and the non-linear relationship between material parameter and RBC deformation was established by building a FE-model.
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Sensing and Modelling Mechanical Response in Large Deformation Indentation of Adherent Cell Using Atomic Force Microscopy.
Tianyao Shen,Bijan Shirinzadeh,Yongmin Zhong,Julian A. Smith,Joshua Pinskier,Mohammadali Ghafarian +5 more
TL;DR: In this study, a rotationally symmetric prism-shaped tensegrity structure is introduced, and it forms the basis of the proposed multi-level tenseGrity model, and the modelling approach utilizes the force density method to mathematically assure self-equilibrium.
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References
•Book
Molecular Cell Biology
Harvey F. Lodish
- 01 Jan 1986
TL;DR: Molecular cell biology, Molecular cell biology , مرکز فناوری اطلاعات و اصاع رسانی, کδاوρزی
7.3K
Biological materials: Structure and mechanical properties
TL;DR: In this article, the basic building blocks are described, starting with the 20 amino acids and proceeding to polypeptides, polysaccharides, and polyprotein-saccharide.
2.3K
•Book
The Finite Element Method for Solid and Structural Mechanics
O. C. Zienkiewicz,R.L. Taylor,David Fox +2 more
- 07 Nov 2013
TL;DR: In this article, the Galerkin method of approximation is used to solve non-linear problems in solid mechanics and nonlinearity, such as finite deformation, contact and tied interfaces.
2.2K
Micropipette aspiration of living cells.
TL;DR: The mechanical behavior of living cells is studied with micropipette suction in which the surface of a cell is aspirated into a small glass tube while tracking the leading edge of its surface to get values for a cell's elastic and viscous properties.
1.4K