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A macroscopic approach for stress-driven anisotropic growth in bioengineered soft tissues

Lukas Lamm, Hagen Holthusen, Tim Brepols, Stefan Jockenhövel, Stefanie Reese

2022Biomechanics and Modeling in Mechanobiology26 citationsDOIOpen Access PDF

Abstract

The simulation of growth processes within soft biological tissues is of utmost importance for many applications in the medical sector. Within this contribution, we propose a new macroscopic approach for modelling stress-driven volumetric growth occurring in soft tissues. Instead of using the standard approach of a-priori defining the structure of the growth tensor, we postulate the existence of a general growth potential. Such a potential describes all eligible homeostatic stress states that can ultimately be reached as a result of the growth process. Making use of well-established methods from visco-plasticity, the evolution of the growth-related right Cauchy-Green tensor is subsequently defined as a time-dependent associative evolution law with respect to the introduced potential. This approach naturally leads to a formulation that is able to cover both, isotropic and anisotropic growth-related changes in geometry. It furthermore allows the model to flexibly adapt to changing boundary and loading conditions. Besides the theoretical development, we also describe the algorithmic implementation and furthermore compare the newly derived model with a standard formulation of isotropic growth.

Topics & Concepts

IsotropyCauchy stress tensorAnisotropyProcess (computing)Tensor (intrinsic definition)Stress (linguistics)A priori and a posterioriBoundary value problemBoundary (topology)Computer scienceStatistical physicsBiological systemMaterials scienceMathematical optimizationMathematicsPhysicsGeometryMathematical analysisLinguisticsBiologyOperating systemQuantum mechanicsPhilosophyEpistemologyElasticity and Material ModelingConnective tissue disorders researchCellular Mechanics and Interactions
A macroscopic approach for stress-driven anisotropic growth in bioengineered soft tissues | Litcius