Thermodynamic properties of muscle contraction models and associated discrete-time principles

François Kimmig; Dominique Chapelle; Philippe Moireau

doi:10.1186/s40323-019-0128-9

Thermodynamic properties of muscle contraction models and associated discrete-time principles

Université Paris-Saclay

Research output: Contribution to journal › Article › peer-review

Abstract

Considering a large class of muscle contraction models accounting for actin–myosin interaction, we present a mathematical setting in which solution properties can be established, including fundamental thermodynamic balances. Moreover, we propose a complete discretization strategy for which we are also able to obtain discrete versions of the thermodynamic balances and other properties. Our major objective is to show how the thermodynamics of such models can be tracked after discretization, including when they are coupled to a macroscopic muscle formulation in the realm of continuum mechanics. Our approach allows to carefully identify the sources of energy and entropy in the system, and to follow them up to the numerical applications.

Original language	English
Article number	6
Journal	Advanced Modeling and Simulation in Engineering Sciences
Volume	6
Issue number	1
DOIs	https://doi.org/10.1186/s40323-019-0128-9
Publication status	Published - 1 Dec 2019
Externally published	Yes

Keywords

Clausius–Duhem inequality
Muscle contraction
Sliding filaments
Thermodynamically consistent time-discretization

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10.1186/s40323-019-0128-9

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title = "Thermodynamic properties of muscle contraction models and associated discrete-time principles",

abstract = "Considering a large class of muscle contraction models accounting for actin–myosin interaction, we present a mathematical setting in which solution properties can be established, including fundamental thermodynamic balances. Moreover, we propose a complete discretization strategy for which we are also able to obtain discrete versions of the thermodynamic balances and other properties. Our major objective is to show how the thermodynamics of such models can be tracked after discretization, including when they are coupled to a macroscopic muscle formulation in the realm of continuum mechanics. Our approach allows to carefully identify the sources of energy and entropy in the system, and to follow them up to the numerical applications.",

keywords = "Clausius–Duhem inequality, Muscle contraction, Sliding filaments, Thermodynamically consistent time-discretization",

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AU - Chapelle, Dominique

AU - Moireau, Philippe

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N2 - Considering a large class of muscle contraction models accounting for actin–myosin interaction, we present a mathematical setting in which solution properties can be established, including fundamental thermodynamic balances. Moreover, we propose a complete discretization strategy for which we are also able to obtain discrete versions of the thermodynamic balances and other properties. Our major objective is to show how the thermodynamics of such models can be tracked after discretization, including when they are coupled to a macroscopic muscle formulation in the realm of continuum mechanics. Our approach allows to carefully identify the sources of energy and entropy in the system, and to follow them up to the numerical applications.

AB - Considering a large class of muscle contraction models accounting for actin–myosin interaction, we present a mathematical setting in which solution properties can be established, including fundamental thermodynamic balances. Moreover, we propose a complete discretization strategy for which we are also able to obtain discrete versions of the thermodynamic balances and other properties. Our major objective is to show how the thermodynamics of such models can be tracked after discretization, including when they are coupled to a macroscopic muscle formulation in the realm of continuum mechanics. Our approach allows to carefully identify the sources of energy and entropy in the system, and to follow them up to the numerical applications.

KW - Clausius–Duhem inequality

KW - Muscle contraction

KW - Sliding filaments

KW - Thermodynamically consistent time-discretization

UR - https://www.scopus.com/pages/publications/85064057216

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JO - Advanced Modeling and Simulation in Engineering Sciences

JF - Advanced Modeling and Simulation in Engineering Sciences

IS - 1

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ER -

Thermodynamic properties of muscle contraction models and associated discrete-time principles

Abstract

Keywords

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