An affine continuum mechanical model for cross-linked F-actin networks with compliant linker proteins

constitutive model excluding fibers under compression: application to extension-inflation of a residually stressed carotid artery. Mathematics and Mechanics of Solids, (doi:10.1177/1081286517712077) This is the author's final accepted version.There may be differences between this version and the published version. You are advised to consult the publisher's version if you wish to cite from it.http://eprints.gla.ac.uk/142898/ Abstract. Detailed information on the three-dimensional dispersion of collagen fibers within layers of healthy and diseased soft biological tissues has been reported recently. Previously we have proposed a constitutive model for soft fibrous solids based on the angular integration approach which allows the exclusion of any compressed collagen fiber within the dispersion.In addition, a computational implementation of that model in a general purpose finite element program has been investigated and verified with the standard fiber-reinforcing model for fiber contributions. In this study, we develop the proposed fiber dispersion model further using an exponential form of the strain-energy function for the fiber contributions. The finite element implementation of this model with a rotationally symmetrical dispersion of fibers is also pre-

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“…Note that Ψ n here incorporates the factor n used previously in [31] to represent the number of fibers per unit reference volume.…”

Section: Fiber Dispersion Modelmentioning

confidence: 99%

An exponential constitutive model excluding fibres under compression: Application to extension–inflation of a residually stressed carotid artery

Ogden

Holzapfel

2017

Mathematics and Mechanics of Solids

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“…Note that with the given normalization we have r ¼ 1 for isotropy. The total strain energy per unit reference volume for all collagen fibres in the tissue is [17] …”

Section: Strain Energy Of the Tissuementioning

confidence: 99%

Constitutive modelling of arteries considering fibre recruitment and three-dimensional fibre distribution

Weisbecker

Unterberger

Holzapfel

2015

J. R. Soc. Interface.

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Structurally motivated material models may provide increased insights into the underlying mechanics and physics of arteries under physiological loading conditions. We propose a multiscale model for arterial tissue capturing three different scales (i) a single collagen fibre; (ii) bundle of collagen fibres; and (iii) collagen network within the tissue. The waviness of collagen fibres is introduced by a probability density function for the recruitment stretch at which the fibre starts to bear load. The three-dimensional distribution of the collagen fibres is described by an orientation distribution function using the bivariate von Mises distribution, and fitted to experimental data. The strain energy for the tissue is decomposed additively into a part related to the matrix material and a part for the collagen fibres. Volume fractions account for the matrix/fibre constituents. The proposed model only uses two parameters namely a shear modulus of the matrix material and a (stiffness) parameter related to a single collagen fibre. A fit of the multiscale model to representative experimental data obtained from the individual layers of a human thoracic aorta shows that the proposed model is able to adequately capture the nonlinear and anisotropic behaviour of the aortic layers.

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“…Recently, two nonlinear springs connected in a series were used to show the effect of the linker stiffness on the rheological properties [83]. Unterberger and co-workers' nonaffine homogenization method can show the negative normal stress behavior [84,85].…”

Section: June 2015mentioning

confidence: 99%

Modeling and simulation of biopolymer networks: Classification of the cytoskeleton models according to multiple scales

Banerjee

Park

2015

Korean J. Chem. Eng.

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We reviewed numerical/analytical models for describing rheological properties and mechanical behaviors of biopolymer networks with a focus on the cytoskeleton, a major component of a living cell. The cytoskeleton models are classified into three categories: the cell-scale continuum-based model, the structure-based model, and the polymerbased model, according to the length scales of the phenomena of interest. The criteria for classification of the models are modified and extended from those used by Mofrad [M. R. K. Mofrad, Annual Rev. Fluid Mech. 41, 433 (2009)]. The main principles and characteristics of each model are summarized and discussed by comparison with each other.Since the stress-deformation relation of cytoskeleton is dependent on the length scale of stress elements, our model classification helps systematic understanding of biopolymer network modeling.

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An affine continuum mechanical model for cross-linked F-actin networks with compliant linker proteins

Cited by 40 publications

References 37 publications

An exponential constitutive model excluding fibres under compression: Application to extension–inflation of a residually stressed carotid artery

An exponential constitutive model excluding fibres under compression: Application to extension–inflation of a residually stressed carotid artery

Constitutive modelling of arteries considering fibre recruitment and three-dimensional fibre distribution

Modeling and simulation of biopolymer networks: Classification of the cytoskeleton models according to multiple scales

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