Publication Details

Category Text Publication
Reference Category Journals
DOI 10.1115/1.4001312
Title (Primary) A large strain material model for soft tissues with functionally graded properties
Author Görke, U.-J.; Günther, H.; Nagel, T.; Wimmer, M.A.
Journal Journal of Biomechanical Engineering
Year 2010
Department ENVINF
Volume 132
Issue 7
Page From 074502-1
Page To 074502-6
Language englisch
Abstract The reaction of articular cartilage and other soft tissues to mechanical loads has been characterized by coupled hydraulic (H) and mechanical (M) processes. An enhanced biphasic material model is presented, which may be used to describe the load response of soft tissue. A large-strain numerical approach of HM coupled processes has been applied. Physical and geometrical nonlinearities, as well as anisotropy and intrinsic rate-dependency of the solid skeleton have been realized using a thermodynamically consistent approach. The presented material model has been implemented into the commercially available finite element code MSC MARC. Initial verification of the model has been conducted analytically in tendonlike structures. The poroelastic and intrinsic viscoelastic features of the model were compared with the experimental data of an unconfined compression test of agarose hydrogel. A recent example from the area of cartilage research has been modeled, and the mechanical response was compared with cell viability. All examples showed good agreement between numerical and analytical/experimental results.
Persistent UFZ Identifier
Görke, U.-J., Günther, H., Nagel, T., Wimmer, M.A. (2010):
A large strain material model for soft tissues with functionally graded properties
J. Biomech. Eng.-Trans. ASME 132 (7), 074502-1 - 074502-6