Numerical treatment of the Filament Based Lamellipodium Model (FBLM)

A. Manhart; D. Oelz; C. Schmeiser; N. Sfakianakis

Numerical treatment of the Filament Based Lamellipodium Model (FBLM)

A. Manhart, D. Oelz, C. Schmeiser, N. Sfakianakis

Applied Mathematics

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

We describe in this work the numerical treatment of the Filament Based Lamellipodium Model (FBLM). The model itself is a two-phase two-dimensional continuum model, describing the dynamics of two interacting families of locally parallel F-actin filaments. It includes, among others, the bending stiffness of the filaments, adhesion to the substrate, and the cross-links connecting the two families. The numerical method proposed is a Finite Element Method (FEM) developed specifically for the needs of these problem. It is comprised of composite Lagrange-Hermite two dimensional elements defined over two dimensional space. We present some elements of the FEM and emphasise in the numerical treatment of the more complex terms. We also present novel numerical simulations and compare to in-vitro experiments of moving cells.

Original language	English
Title of host publication	Modeling Cellular Systems
Publisher	Springer
Publication status	Published - 1 May 2015

Keywords

Quantitative Biology - Cell Behavior

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http://adsabs.harvard.edu/abs/2015arXiv150504266M

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title = "Numerical treatment of the Filament Based Lamellipodium Model (FBLM)",

abstract = "We describe in this work the numerical treatment of the Filament Based Lamellipodium Model (FBLM). The model itself is a two-phase two-dimensional continuum model, describing the dynamics of two interacting families of locally parallel F-actin filaments. It includes, among others, the bending stiffness of the filaments, adhesion to the substrate, and the cross-links connecting the two families. The numerical method proposed is a Finite Element Method (FEM) developed specifically for the needs of these problem. It is comprised of composite Lagrange-Hermite two dimensional elements defined over two dimensional space. We present some elements of the FEM and emphasise in the numerical treatment of the more complex terms. We also present novel numerical simulations and compare to in-vitro experiments of moving cells.",

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T1 - Numerical treatment of the Filament Based Lamellipodium Model (FBLM)

AU - Manhart, A.

AU - Oelz, D.

AU - Schmeiser, C.

AU - Sfakianakis, N.

PY - 2015/5/1

Y1 - 2015/5/1

N2 - We describe in this work the numerical treatment of the Filament Based Lamellipodium Model (FBLM). The model itself is a two-phase two-dimensional continuum model, describing the dynamics of two interacting families of locally parallel F-actin filaments. It includes, among others, the bending stiffness of the filaments, adhesion to the substrate, and the cross-links connecting the two families. The numerical method proposed is a Finite Element Method (FEM) developed specifically for the needs of these problem. It is comprised of composite Lagrange-Hermite two dimensional elements defined over two dimensional space. We present some elements of the FEM and emphasise in the numerical treatment of the more complex terms. We also present novel numerical simulations and compare to in-vitro experiments of moving cells.

AB - We describe in this work the numerical treatment of the Filament Based Lamellipodium Model (FBLM). The model itself is a two-phase two-dimensional continuum model, describing the dynamics of two interacting families of locally parallel F-actin filaments. It includes, among others, the bending stiffness of the filaments, adhesion to the substrate, and the cross-links connecting the two families. The numerical method proposed is a Finite Element Method (FEM) developed specifically for the needs of these problem. It is comprised of composite Lagrange-Hermite two dimensional elements defined over two dimensional space. We present some elements of the FEM and emphasise in the numerical treatment of the more complex terms. We also present novel numerical simulations and compare to in-vitro experiments of moving cells.

KW - Quantitative Biology - Cell Behavior

M3 - Chapter

BT - Modeling Cellular Systems

PB - Springer

ER -

Numerical treatment of the Filament Based Lamellipodium Model (FBLM)

Abstract

Keywords

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