Swelling and curling behaviors of articular cartilage

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Setton, L. A.¹; Tohyama, H.²; Mow, V. C.³

Swelling and curling behaviors of articular cartilage

J Biomech Eng. June 1998;120(3):355-361

©1998 ASME

Affiliations

¹Assistant Professor, Departments of Biomedical Engineering and Surgery, Duke University, Durham, NC 27708-0281

²Assistant Professor, Department of Medical Biomechanics, Hokkaido University Sctiool of Medicine, Sapporo, Japan

³Professor, Departments of Mechanical Engineering and Orthopaedic Surgery, Columbia University, New York, NY 10032
Abstract

A new experimental method was developed to quantify parameters of swelling-induced shape change in articular cartilage. Full-thickness strips of cartilage were studied in free-swelling tests and the swelling-induced stretch, curvature, and areal change were measured. In general, swelling-induced stretch and curvature were found to increase in cartilage with decreasing ion concentration, reflecting an increasing tendency to swell and “curl” at higher swelling pressures. An exception was observed at the articular surface, which was inextensible for all ionic conditions. The swelling-induced residual strain at physiological ionic conditions was estimated from the swelling-induced stretch and found to be tensile and from 3–15 percent. Parameters of swelling were found to vary with sample orientation, reflecting a role for matrix anisotropy in controlling the swelling-induced residual strains. In addition, the surface zone was found to be a structurally important element, which greatly limits swelling of the entire cartilage layer. The findings of this study provide the first quantitative measures of swelling-induced residual strain in cartilage ex situ, and may be readily adapted to studies of cartilage swelling in situ.
Links

DOI: 10.1115/1.2798002

PubMed: ID10412403

WoS: 000074607700007
History

Received: 1996-10-24

Revised: 1997-009-03

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Year	Entry
2003	Ateshian GA, Hung CT. Functional properties of native articular cartilage. In: Guilak F, Butler DL, Goldstein SA, Mooney DJ, eds. Functional Tissue Engineering. New York, NY: Inc., Springer-Verlag; 2003:46-68.
2002	Mow VC, Guo XE. Mechano-electrochemical properties of articular cartilage: their inhomogeneities and anisotropies. Annu Rev Biomed Eng. 2002;4:175-209.
2003	Wong M, Carter DR. Articular cartilage functional histomorphology and mechanobiology: a research perspective. Bone. July 2003;33(1):1-13.
1999	Narmoneva DA, Wang JY, Setton LA. Nonuniform swelling-induced residual strains in articular cartilage. J Biomech. April 1999;32(4):401-408.
2004	Ateshian GA, Chahine NO, Basalo IM, Hung CT. The correspondence between equilibrium biphasic and triphasic material properties in mixture models of articular cartilage. J Biomech. March 2004;37(3):391-400.
2004	Chahine NO, Wang CC-B, Hung CT, Ateshian GA. Anisotropic strain-dependent material properties of bovine articular cartilage in the transitional range from tension to compression. J Biomech. August 2004;37(8):1251-1261.
2000	Bursać P, McGrath CV, Eisenberg SR, Stamenović D. A microstructural model of elastostatic properties of articular cartilage in confined compression. J Biomech Eng. August 2000;122(4):347-353.
2000	Butler DL, Goldstein SA, Guilak F. Functional tissue engineering: the role of biomechanics. J Biomech Eng. December 2000;122(6):570-575.
2000	Soltz MA, Ateshian GA. A conewise linear elasticity mixture model for the analysis of tension-compression nonlinearity in articular cartilage. J Biomech Eng. December 2000;122(6):576-586.
2024	Moo EK, Sibole SC, Federico S, Korhonen RK, Herzog W. Microscale investigation of the anisotropic swelling of cartilage tissue and cells in response to hypo-osmotic challenges. J Orthop Res. January 2024;42(1):54-65.
1999	Mow VC, Wang CC, Hung CT. The extracellular matrix, interstitial fluid and ions as a mechanical signal transducer in articular cartilage. Osteoarthritis Cartilage. January 1999;7(1):41-58.
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