Biological tissues like intervertebral discs and articular cartilage primarily consist of interstitial fluid, collagen fibrils and negatively charged proteoglycans. Due to the fixed charges of the proteoglycans, the total ion concentration inside the tissue is higher than in the surrounding synovial fluid (cation concentration is higher and the anion concentration is lower). This excess of ion particles leads to an osmotic pressure difference, which causes swelling of the tissue. In the last decade several mechano-electrochemical models, which include this mechanism, have been developed. As these models are complex and computationally expensive, it is only possible to analyze geometrically relatively small problems. Furthermore, there is still no commercial finite element tool that includes such a mechano-electrochemical theory. Lanir (Biorheology, 24, pp. 173–187, 1987) hypothesized that electrolyte flux in articular cartilage can be neglected in mechanical studies. Lanir’s hypothesis implies that the swelling behavior of cartilage is only determined by deformation of the solid and by fluid flow. Hence, the response could be described by adding a deformation-dependent pressure term to the standard biphasic equations. Based on this theory we developed a biphasic swelling model. The goal of the study was to test Lanir’s hypothesis for a range of material properties. We compared the deformation behavior predicted by the biphasic swelling model and a full mechano-electrochemical model for confined compression and 1D swelling. It was shown that, depending on the material properties, the biphasic swelling model behaves largely the same as the mechano-electrochemical model, with regard to stresses and strains in the tissue following either mechanical or chemical perturbations. Hence, the biphasic swelling model could be an alternative for the more complex mechano-electrochemical model, in those cases where the ion flux itself is not the subject of the study. We propose thumbrules to estimate the correlation between the two models for specific problems.

1.
Urban
,
J. P. G.
,
Maroudas
,
A.
,
Bayliss
,
M. T.
, and
Dillon
,
J.
,
1979
, “
Swelling Pressures of Proteoglycans at the Concentrations Found in Cartilagenous Tissues
,”
Biorheology
,
16
, pp.
447
464
.
2.
Mow
,
V. C.
,
Kuei
,
S. C.
,
Lai
,
W. M.
, and
Armstrong
,
C. G.
,
1980
, “
Biphasic Creep and Stress Relaxation of Articular Cartilage in Compression: Theory and Experiments
,”
J. Biomech. Eng.
,
102
, pp.
73
84
.
3.
Lai
,
W. M.
,
Hou
,
J. S.
, and
Mow
,
V. C.
,
1991
, “
A Triphasic Theory for the Swelling and Deformation Behaviors of Articular Cartilage
,”
J. Biomech. Eng.
,
113
, pp.
245
258
.
4.
Huyghe
,
J. M.
, and
Janssen
,
J. D.
,
1997
, “
Quadriphasic Theory of Swelling Incompressible Porous Media
,”
Int. J. Eng. Sci.
,
35
, pp.
793
802
.
5.
Gu
,
W. Y.
,
Lai
,
W. M.
, and
Mow
,
V. C.
,
1998
, “
A Mixture Theory for Charged-Hydrated Soft Tissues Containing Multi-Electrolytes: Passive Transport and Swelling Behaviors
,”
J. Biomech. Eng.
,
120
, pp.
169
180
.
6.
Simon
,
B. R.
,
Liable
,
J. P.
,
Pflaster
,
D.
,
Yuan
,
Y.
, and
Krag
,
M. H.
,
1996
, “
A Poroelastic Finite Element Formulation Including Transport and Swelling in Soft Tissue Structures
,”
J. Biomech. Eng.
,
118
, pp.
1
9
.
7.
Frijns
,
A. J. H.
,
Huyghe
,
J. M.
, and
Janssen
,
J. D.
,
1997
, “
A Validation of the Quadriphasic Mixture Theory for Intervertebral Disc Tissue
,”
Int. J. Eng. Sci.
,
35
, pp.
1419
1429
.
8.
Levenston
,
M. E.
,
Frank
,
E. H.
, and
Grodzinksy
,
A. J.
,
1999
, “
Electrokinetic and Poroelastic Coupling During Finite Deformations of Charged Porous Media
,”
J. Appl. Mech.
,
66
, pp.
323
333
.
9.
Sun
,
D. N.
,
Gu
,
W. Y.
,
Guo
,
X. E.
,
Lai
,
W. M.
, and
Mow
,
V. C.
,
1999
, “
A Mixed Finite Element Formulation of Triphasic Mechano-Electrochemical Theory for Charged, Hydrated Biological Soft Tissues
,”
Int. J. Numer. Methods Eng.
,
45
, pp.
1375
1402
.
10.
van Meerveld
,
J.
,
Molenaar
,
M. M.
,
Huyghe
,
J. M.
, and
Baaijens
,
F. P. T.
,
2003
, “
Analytical Solution of Compression, Free Swelling and Electrical Loading of Saturated Charged Porous Media
,”
Transp. Porous Media
,
50
, pp.
111
126
.
11.
van Loon
,
R.
,
Huyghe
,
J. M. R. J.
,
Wijlaars
,
M. W.
, and
Baaijens
,
F. P. T.
,
2003
, “
3D FE Implementation of an Incompressible Quadriphasic Mixture Model
,”
Int. J. Numer. Methods Eng.
,
57
, pp.
1243
1258
.
12.
Lanir
,
Y.
,
1987
, “
Biorheology and Fluid Flux in Swelling Tissues. I. Bicomponent Theory for Small Deformations, Including Concentration Effects
,”
Biorheology
,
24
, pp.
173
187
.
13.
Maroudas
,
A.
,
1975
, “
Biophysical Chemistry of Cartilaginous Tissues With Special Reference to Solute and Fluid Transport
,”
Biorheology
,
12
, pp.
233
248
.
14.
Maroudas, A., 1979, “Physiochemical Properties of Articular Cartilage,” in Adult Articular Cartilage, 2nd ed., Freemam, M. A. R., ed., Pitman Medical, pp. 233–248.
15.
Simo
,
J. C.
, and
Ortiz
,
M.
,
1985
, “
A Unified Approach to Finite Deformation Plasticity Based on the Use of Hyperelastic Constitutive Equations
,”
Comput. Methods Appl. Mech. Eng.
,
49
, pp.
221
245
.
16.
Mow
,
V. C.
,
Atheshian
,
G. A.
,
Lai
,
W. M.
, and
Gu
,
W. Y.
,
1998
, “
Effects of Fixed Charges on the Stress–Relaxation Behavior of Hydrated Soft Tissues in a Confined Compression Problem
,”
Int. J. Solids Struct.
,
35
, pp.
4945
4962
.
17.
Wilson
,
W.
,
van Donkelaar
,
C. C.
,
van Rietbergen
,
C.
,
Ito
,
K.
, and
Huiskes
,
R.
,
2004
, “
Stresses in the Local Collagen Network of Articular Cartilage: A Poroviscoelastic Fibril-Reinforced Finite Element Study
,”
J. Biomech.
,
37
, pp.
357
366
.
18.
Huyghe
,
J. M.
,
Janssen
,
C. F.
,
van Donkelaar
,
C. C.
, and
Lanir
,
Y.
,
2002
, “
Measuring Principles of Frictional Coefficients in Cartilaginous Tissues and Its Substitutes
,”
Biorheology
,
39
, pp.
47
53
.
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