Multiphase poroelastic finite element models for soft tissue structures

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Simon, Bruce R.¹

Multiphase poroelastic finite element models for soft tissue structures

Appl Mech Rev. June 1992;45(6):191-218

©1992 American Society of Mechanical Engineers

Affiliations

¹Department of Aerospace and Mechanical Engineering, The University of Arizona, Tucson, AZ 85721
Abstract

During the last two decades, biological structures with soft tissue components have been modeled using poroelastic or mixture-based constitutive laws, i.e., the material is viewed as a deformable (porous) solid matrix that is saturated by mobile tissue fluid. These structures exhibit a highly nonlinear, history-dependent material behavior; undergo finite strains; and may swell or shrink when tissue ionic concentrations are altered. Given the geometric and material complexity of soft tissue structures and that they are subjected to complicated initial and boundary conditions, finite element models (FEMs) have been very useful for quantitative structural analyses. This paper surveys recent applications of poroelastic and mixture-based theories and the associated FEMs for the study of the biomechanics of soft tissues, and indicates future directions for research in this area. Equivalent finite-strain poroelastic and mixture continuum biomechanical models are presented. Special attention is given to the identification of material properties using a porohyperelastic constitutive law and a total Lagrangian view for the formulation. The associated FEMs are then formulated to include this porohyperelastic material response and finite strains. Extensions of the theory are suggested in order to include inherent viscoelasticity, transport phenomena, and swelling in soft tissue structures. A number of biomechanical research areas are identified, and possible applications of the porohyperelastic and mixture-based FEMs are suggested.
Links

DOI: 10.1115/1.3121397

Cited Works (11)

Year	Entry
1980	Bowen RM. Incompressible porous media models by use of the theory of mixtures. Int J Eng Sci. 1980;18(9):1129-1148.
1986	Holmes MH. Finite deformation of soft tissue: analysis of a mixture model in uni-axial compression. J Biomech Eng. November 1986;108(4):372-381.
1986	Mak AF. The apparent viscoelastic behavior of articular cartilage: the contributions from the intrinsic matrix viscoelasticity and interstitial fluid flows. J Biomech Eng. May 1986;108(2):123-130.
1984	Myers ER, Lai WM, Mow VC. A continuum theory and an experiment for the ion-induced swelling behavior of articular cartilage. J Biomech Eng. May 1984;106(2):151-158.
1941	Biot MA. General theory of three‐dimensional consolidation. J Appl Phys. February 1941;12(2):155-164.
1980	Mow VC, Kuei SC, Lai WM, Armstrong CG. Biphasic creep and stress relaxation of articular cartilage in compression: theory and experiments. J Biomech Eng. February 1980;102(1):73-84.
1962	Biot MA. Mechanics of deformation and acoustic propagation in porous media. J Appl Phys. April 1962;33(4):1482-1498.
1972	Fung Y-CB. Stress-strain-history relations of soft tissues in simple elongation. In: Fung YC, Perrone N, Anliker M, eds. Biomechanics: Its Foundations and Objectives. Symposium on Biomechanics, its Foundations and Objectives; July 29-31, 1970. Englewood Cliff, NJ: Inc., Prentice-Hall International; 1972:181-208.
1985	Simon BR, Wu JSS, Carlton MW, Evans JH, Kazarian LE. Structural models for human spinal motion segments based on a poroelastic view of the intervertebral disk. J Biomech Eng. November 1985;107(4):327-335.
1990	Lai WM, Hou JS, Mow VC. A triphasic theory for the swelling properties of hydrated charged soft biological tissues. In: Mow VC, Ratcliffe A, Woo SL-Y, eds. Biomechanics of Diarthrodial Joints. Vol 1. New York, NY: Springer-Verlag; 1990:283-312.
1990	Spilker RL, Suh J-K, Vermilyea ME, Maxian TA. Alternate hybrid, mixed, and penalty finite element formulations for the biphasic model of soft hydrated tissues. In: Mow VC, Ratcliffe A, Woo SL-Y, eds. Biomechanics of Diarthrodial Joints. Vol 1. New York, NY: Springer-Verlag; 1990:401-435.

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2001	Cowin SC. Bone poroelasticity. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:23-1–23-31.
1997	Bilston LE, Liu Z, Phan-Thien N. Linear viscoelastic properties of bovine brain tissue in shear. Biorheology. November–November 1997;34(6):377-385.
2001	Weiss JA, Gardiner JC. Computational modeling of ligament mechanics. Crit Rev Biomed Eng. 2001;29(3):303-371.
1997	Prendergast PJ, Huiskes R, Søballe K. Biophysical stimuli on cells during tissue differentiation at implant interfaces. J Biomech. June 1997;30(6):539-548.
1997	Lemmon D, Shiang TY, Hashmi A, Ulbrecht JS, Cavanagh PR. The effect of insoles in therapeutic footwear: a finite element approach. J Biomech. June 1997;30(6):615-620.
1998	Wu JZ, Herzog W, Epstein M. Evaluation of the finite element software ABAQUS for biomechanical modelling of biphasic tissues. J Biomech. February 1998;31(2):165-169.
1999	Cowin SC. Bone poroelasticity. J Biomech. March 1999;32(3):217-238.
2000	Ferguson SJ, Bryant JT, Ganz R, Ito K. The influence of the acetabular labrum on hip joint cartilage consolidation: a poroelastic finite element model. J Biomech. August 2000;33(8):953-960.
2007	Cheng S, Bilston LE. Unconfined compression of white matter. J Biomech. 2007;40(2):117-124.
2001	Chen SS, Falcovitz YH, Schneiderman R, Maroudas A, Sah RL. Depth-dependent compressive properties of normal aged human femoral head articular cartilage: relationship to fixed charge density. Osteoarthritis Cartilage. August 2001;9(6):561-569.
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