Dynamic behavior of a biphasic cartilage model under cyclic compressive loading

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Suh, Jun-Kyo¹; Li, Zhengfang¹; Woo, Savio L-Y.¹

Dynamic behavior of a biphasic cartilage model under cyclic compressive loading

J Biomech. April 1995;28(4):357-364

©1995 Elsevier Science Ltd

Affiliations

¹Musculoskeletal Research Center, Depts of Orthopaedic Surgery, University of Pittsburgh, Pittsburgh, PA 15213, U.S.A.
Abstract

It is well known that dynamic mechanical loads can stimulate the biosynthetic activity of articular cartilage. Studying the mechanical environment of chondrocytes under dynamic loading conditions can help to explain this mechano-biological phenomenon in articular cartilage. In this study, the linear biphasic theory was used to examine the dynamic mechanical behavior of articular cartilage under a cyclic compressive force. We first studied the dynamic confined compression of a cartilage disk as a simplified one-dimensional model and then investigated the role of the relatively impermeable subchondral bone structure on the dynamic behavior of the cartilage extracellular matrix (ECM). Under an assumption of articular cartilage as a biphasic composite structure of a porous elastic solid matrix and interstitial fluid, the porous ECM of the articular cartilage was repeatedly compressed and expanded during the loading-unloading phases of the cyclic compressive force. One interesting finding of this study was the oscillating positive (supra-ambient)-negative (sub-ambient) hydrostatic pressure within the cartilage ECM under cyclic compressive loading. The pattern of the dynamic behavior of the cartilage ECM strongly depended on the loading frequency and the primary diffusion characteristic time, τ_d. This finding is consistent with those of previous studies (Guilak et al., 1990 Adv Biomech. ASME, 225–228; Mow et al., 1990, Biomechanics of Diarthrodial Joints, pp. 215–260.
Links

DOI: 10.1016/0021-9290(94)00103-B

PubMed: 7738045

WoS: A1995QM53600001
History

Revised: 1994-08-4

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Cited By (20)

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.
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2000	Eckstein F, Lemberger B, Stammberger T, Englmeier KH, Reiser M. Patellar cartilage deformation in vivo after static versus dynamic loading. J Biomech. July 2000;33(7):819-825.
2024	Rich MJ, Burnash S, Krishnan RR, Chubinskaya S, Loeser RF, Polacheck WJ, Diekman BO. Use of a novel magnetically actuated compression system to study the temporal dynamics of axial and lateral strain in human osteochondral plugs. J Biomech. January 2024;162:111887.
1998	Wu JZ, Herzog W, Epstein M. Articular joint mechanics with biphasic cartilage layers under dynamic loading. J Biomech Eng. February 1998;120(1):77-84.
2003	Ikenoue T, Trindade MCD, Lee MS, Lin EY, Schurman DJ, Goodman SB, Smith RL. Mechanoregulation of human articular chondrocyte aggrecan and type II collagen expression by intermittent hydrostatic pressure in vitro. J Orthop Res. January 2003;21(1):110-116.
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2000	Soltz MA. Investigation of a Boundary Friction Model for Articular Cartilage: Effects of Interstitial Fluid Pressurization and Surface Topography [PhD thesis]. Columbia University; 2000.
2001	Wang C. Digital Video Microscopy-Based Determination of Cartilage Inhomogeneity, Anisotropy and Tension -Compression Nonlinearity: Implications on Chondrocyte Environment [PhD thesis]. Columbia University; 2001.
2008	Cao L. Micromechanics of the Pericellular Matrix and Cells in the Intervertebral Disc: Three-Dimensional Finite Element Modeling Based on in Situ Morphology [PhD thesis]. Duke University; 2008.
2019	Cutcliffe HC. In Vivo Mechanical Metrics for the Quantitative Assessment of Cartilage Health [PhD thesis]. Duke University; 2019.
2013	Vernon LL. Articular Cartilage Response Following Impact Injury [PhD thesis]. University of Miami; August 2013.
2020	Hazbun L. Anti-Inflammatory Effects of Dynamic Joint Loading on Knee Articular Cartilage Post Traumatic Acute Joint Injury [PhD thesis]. University of Miami; August 2020.
2003	Gil JE. Development of a Biomechanical Testing Platform for the Study of the Human Knee Joint [Master's thesis]. University of Pittsburgh; 2003.
2009	Wong BL. Biomechanics of Cartilage Articulation: Effects of Degeneration, Lubrication, and Focal Articular Defects [PhD thesis]. San Diego (UCSD), University of California; 2009.
2014	Pourmohammadali H. Mechanical and Hydromechanical Stimulation of Chondrocytes for Articular Cartilage Tissue Engineering [PhD thesis]. University of Waterloo; 2014.
2007	Shields KJ. The Development of a Multi-Directional Wear Apparatus and the Characterization and Correlation of Biomechanical and Biotribological Properties of Bovine Articular Cartilage [PhD thesis]. Richmond, VA: Virginia Commonwealth University; December 2007.