Anisotropic micro-sphere-based finite elasticity applied to blood vessel modelling

Journal of the Mechanics and Physics of Solids

Volumn 57, Issue 1, 2009, Pages 178-203

  Alastrue V ^a,b   Martinez M A ^a,b   Doblare M ^a,b   Menzel, A ^c,d  

^a UNIVERSITY OF ZARAGOZA   (Spain)

^b BIOMATERIALES Y NANOMEDICINA CIBER BBN   (Spain)

^c TU DORTMUND UNIVERSITY   (Germany)

^d LUND UNIVERSITY   (Sweden)

Author keywords

Anisotropy; Micro sphere; Soft tissue; Vascular modelling; Worm like chain

Indexed keywords

ANISOTROPY; BLOOD; BLOOD VESSELS; BOUNDARY VALUE PROBLEMS; CEMENTS; DEFORMATION; DIFFERENTIAL EQUATIONS; DISTRIBUTION FUNCTIONS; INITIAL VALUE PROBLEMS; INTEGRATION; NUMERICAL ANALYSIS; PROBABILITY DENSITY FUNCTION; STRAIN ENERGY; TENSILE TESTING; THREE DIMENSIONAL;

ANISOTROPIC ELASTICS; ANISOTROPIC PROBLEMS; ARTERIAL TISSUES; BIOLOGICAL TISSUES; BOUNDARY VALUES; COMPUTATIONAL COSTS; DEFORMATION GRADIENT TENSORS; DEVIATORIC; EXPERIMENTAL DATUMS; FINITE ELASTICITIES; HOMOGENEOUS DEFORMATIONS; HOMOGENISATION; INHOMOGENEOUS DEFORMATIONS; INTERNAL PRESSURES; LINEAR FINITE ELEMENTS; MACROSCOPIC RESPONSES; MATERIAL PARAMETERS; MECHANICAL MODELS; MICRO-SPHERE; MICRO-SPHERES; MULTIPLICATIVE DECOMPOSITIONS; NUMERICAL INTEGRATIONS; ORIENTATION DISTRIBUTION FUNCTIONS; SIMPLE SHEARS; SIMULATION RESULTS; SOFT TISSUE; STRAIN ENERGY DENSITY FUNCTIONS; STRUCTURAL LEVELS; TENSION TESTS; VASCULAR MODELLING; VASCULAR TISSUES; VON MISES; WORM-LIKE CHAIN;

SPHERES;

EID: 56949103255     PISSN: 00225096     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jmps.2008.09.005     Document Type: Article

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