Patellar cartilage deformation in vivo after static versus dynamic loading

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Eckstein, F.¹; Lemberger, B.¹; Stammberger, T.²; Englmeier, K. H²; Reiser, M.³

Patellar cartilage deformation in vivo after static versus dynamic loading

J Biomech. July 2000;33(7):819-825

©2000 Elsevier Science Ltd. All rights reserved.

Affiliations

¹Musculoskeletal Research Group, Institute of Anatomy, Ludwig-Maximilians Universität München, Pettenkoferstr. 11, D 80336 München, Germany

²Institute for Medical Informatis (MEDIS), GSF National Research Center Neuherberg, Ingolstädter Landstr. 1, D-85764 Oberschleißheim, Germany

³Institute for Clinical Radiology, Klinikum der LMU München, Standort Großhadern, Marchioninistr. 15, D-81377 München, Germany
Abstract and keywords

The objective of this study was to test the hypothesis that static loading (squatting at a 90° angle) and dynamic loading (30 deep knee bends) cause different extents and patterns of patellar cartilage deformation in vivo. The two activities were selected because they imply different types of joint loading and reflect a realistic and appropriate range of strenuous activity. Twelve healthy volunteers were examined and the volume and thickness of the patellar cartilage determined before and from 90 to 320 s after loading, using a water excitation gradient echo MR sequence and a three-dimensional (3D) distance transformation algorithm. Following knee bends, we observed a residual reduction of the patellar cartilage volume (−5.9±2.1%; p<0.01) and of the maximal cartilage thickness (−2.8±2.6%), the maximal deformation occurring in the superior lateral and the medial patellar facet. Following squatting, the change of patellar cartilage volume was −4.7±1.6% (p<0.01) and that of the maximal cartilage thickness −4.9±1.4% (p<0.01), the maximal deformation being recorded in the central aspect of the lateral patellar facet. The volume changes were significantly lower after squatting than after knee bends (p<0.05), but the maximal thickness changes higher (p<0.05). The results obtained in this study can serve to validate computer models of joint load transfer, to guide experiments on the mechanical regulation of chondrocyte biosynthesis, and to estimate the magnitude of deformation to be encountered by tissue-engineered cartilage within its target environment.

Keywords: Articular cartilage; Cartilage mechanics; MR imaging; Joint loading
Links

DOI: 10.1016/S0021-9290(00)00034-8
History

Accepted: 2000-02-2

Cited Works (23)

Year	Entry
1991	Ateshian G, Soslowsky L, Mow V. Quantitation of articular surface topography and cartilage thickness in knee joints using stereophotogrammetry. J Biomech. January 1991;24(8):761-776.
1999	Herberhold C, Faber S, Stammberger T, Steinlechner M, Putz R, Englmeier K, Reiser M, Eckstein F. In situ measurement of articular cartilage deformation in intact femoropatellar joints under static loading. J Biomech. December 1999;32(12):1287-1295.
1993	Mow VC, Ateshian GA, Spilker RL. Biomechanics of diarthrodial joints: a review of twenty years of progress. J Biomech Eng. November 1993;115(4B):460-467.
1996	Buschmann MD, Hunziker EB, Kim YJ, Grodzinsky AJ. Altered aggrecan synthesis correlates with cell and nucleus structure in statically compressed cartilage. J Cell Sci. February 1996;109(2):499-508.
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.
1998	Lee DA, Noguchi T, Knight MM, O'Donnell L, Bentley G, Bader DL. Response of chondrocyte subpopulations cultured within unloaded and loaded agarose. J Orthop Res. November 1998;16(6):726-733.
1989	Sah RL-Y, Kim Y-J, Doong J-YH, Grodzinsky AJ, Plass AHK, Sandy JD. Biosynthetic response of cartilage explants to dynamic compression. J Orthop Res. 1989;7(5):619-636.
1995	Guilak F, Ratcliffe A, Mow VC. Chondrocyte deformation and local tissue strain in articular cartilage: a confocal microscopy study. J Orthop Res. May 1995;13(3):410-421.
1997	Wu JZ, Herzog W, Epstein M. An improved solution for the contact of two biphasic cartilage layers. J Biomech. April 1997;30(4):371-375.
1998	Bachrach NM, Mow VC, Guilak F. Incompressibility of the solid matrix of articular cartilage under high hydrostatic pressures. J Biomech. May 1998;31(5):445-451.
1996	Wu JZ, Herzog W, Ronsky J. Modeling axi-symmetrical joint contact with biphasic cartilage layers: an asymptotic solution. J Biomech. October 1996;29(10):1263-1281.
1995	Duncan RL, Turner CH. Mechanotransduction and the functional response of bone to mechanical strain. Calcif Tiss Int. December 1995;57(5):344-358.
1994	Urban JPG. The chondrocyte: a cell under pressure. Br J Rheumatol. October 1994;33(10):901-908.
1984	Lanyon LE, Rubin CT. Static vs dynamic loads as an influence on bone remodelling. J Biomech. 1984;17(12):897-905.
1984	Mow VC, Holmes MH, Lai WM. Fluid transport and mechanical properties of articular cartilage: a review. J Biomech. 1984;17(5):377-394.
1995	Suh J-K, Li Z, Woo SL-Y. Dynamic behavior of a biphasic cartilage model under cyclic compressive loading. J Biomech. April 1995;28(4):357-364.
1999	Cohen ZA, McCarthy DM, Kwak SD, Legrand P, Fogarasi F, Ciaccio EJ, Ateshian GA. Knee cartilage topography, thickness, and contact areas from MRI: in-vitro calibration and in-vivo measurements. Osteoarthritis Cartilage. January 1999;7(1):95-109.
1995	Guilak F. Compression-induced changes in the shape and volume of the chondrocyte nucleus. J Biomech. December 1995;28(12):1529-1541.
1979	Armstrong CG, Bahrani AS, Gardner DL. In vitro measurement of articular cartilage deformations in the intact human hip joint under load. J Bone Joint Surg. July 1979;61A(5):744-755.
1991	Athanasiou KA, Rosenwasser MP, Buckwalter JA, Malinin TI, Mow VC. Interspecies comparisons of in situ intrinsic mechanical properties of distal femoral cartilage. J Orthop Res. May 1991;9(3):330-340.
1995	Bachrach NM, Valhmu WB, Stazzone E, Ratcliffe A, Lai WM, Mow VC. Changes in proteoglycan synthesis of chondrocytes in articular cartilage are associated with the time-dependent changes in their mechanical environment. J Biomech. December 1995;28(12):1561-1569.
1995	Kim Y-J, Bonassar LJ, Grodzinsky AJ. The role of cartilage streaming potential, fluid flow and pressure in the stimulation of chondrocyte biosynthesis during dynamic compression. J Biomech. September 1995;28(9):1055-1066.
1997	Eckstein F, Adam C, Sittek H, Becker C, Milz S, Schulte E, Reiser M, Putz R. Non-invasive determination of cartilage thickness throughout joint surfaces using magnetic resonance imaging. J Biomech. March 1997;30(3):285-289.

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2003	Wong M, Carter DR. Articular cartilage functional histomorphology and mechanobiology: a research perspective. Bone. July 2003;33(1):1-13.
2001	Guilak F, Butler DL, Goldstein SA. Functional tissue engineering: the role of biomechanics in articular cartilage repair. Clin Orthop Relat Res. October 2001;391(suppl):S295-S305.
2004	Carter DR, Beaupré GS, Wong M, Smith RL, Andriacchi TP, Schurman DJ. The mechanobiology of articular cartilage development and degeneration. Clin Orthop Relat Res. October 2004;427(suppl):S69-S77.
2001	Quinn TM, Morel V, Meister JJ. Static compression of articular cartilage can reduce solute diffusivity and partitioning: implications for the chondrocyte biological response. J Biomech. November 2001;34(11):1463-1469.
2007	Klein TJ, Chaudhry M, Bae WC, Sah RL. Depth-dependent biomechanical and biochemical properties of fetal, newborn, and tissue-engineered articular cartilage. J Biomech. January 2007;40(1):182-190.
2004	Park S, Hung CT, Ateshian GA. Mechanical response of bovine articular cartilage under dynamic unconfined compression loading at physiological stress levels. Osteoarthritis Cartilage. January 2004;12(1):65-73.
2011	Bansal PN. Contrast Enhanced Computed Tomographic Imaging of Articular Cartilage: Interrelationships With Biochemical and Biomechanical Properties [PhD thesis]. Boston University; 2011.
2017	Wahlquist JA. Zonal Articular Cartilage Possesses Complex Mechanical Behavior Spanning Multiple Length Scales: Dependence on Chemical Heterogeneity, Anisotropy, and Microstructure [PhD thesis]. Boulder, CO: University of Colorado; 2017.
2003	Mauck RL. Functional Tissue Engineering of Articular Cartilage: The Effect of Physical Forces on the in Vitro Growth of Engineered Constructs [PhD thesis]. Columbia University; 2003.
2005	Park S. Interstitial Fluid Flow-Dependent and Flow-Independent Mechanical and Tribological Response of Articular Cartilage [PhD thesis]. Columbia University; 2005.
2006	Chahine NO. Multi-Scale Measurements of the Mechanical and Transport Properties of Native and Engineered Articular Cartilage [PhD thesis]. Columbia University; 2006.
2009	Canal Guterl C. Contact Mechanics of Articular Layers: 2D Strain Fields and Their Relation to Tissue Inhomogeneity [PhD thesis]. Columbia University; 2009.
2019	Cutcliffe HC. In Vivo Mechanical Metrics for the Quantitative Assessment of Cartilage Health [PhD thesis]. Duke University; 2019.
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2013	Johnson JE. Effects of Surgical Repair or Reconstruction on Radiocarpal Mechanics from Wrists With Scapholunate Ligament Injury [PhD thesis]. Lawrence, KS: University of Kansas; 2013.
2017	Kleinhans KL. Transport Properties in Porcine Meniscus Fibrocartilage [PhD thesis]. University of Miami; August 2017.
2010	Bahney CS. Cartilage Engineering: Designing an Improved System for Effecting Repair of Articular Cartilage Defects [PhD thesis]. Portland, OR: Oregon Health & Science University; August 2010.
2012	Chan DD. Displacements Under Applied Loading With MRI for the Estimation of High-Precision Strains in Soft Tissues [PhD thesis]. Purdue University; 2012.
2009	Song Y. Fibro-Cartilaginous Structures about the Knee and Hip: Relation to Development of Osteoarthritis [PhD thesis]. Stanford University; September 2009.
2004	McWalter EJ. Links Between Three-Dimensional Patellar Kinematics, Cartilage Morphology and Varus/valgus Alignment in Early Knee Osteoarthritis [Master's thesis]. Vancouver, BC: University of British Columbia; December 2004.
2015	Buchan LL. Open MRI Investigation of Contact Mechanics in Cam Femoroacetabular Impingement [Master's thesis]. Vancouver, BC: University of British Columbia; March 2015.
2001	Moss RT. Quantification of Patellofemoral Contact Area Using MR Imaging, a Validation and Comparative Study [Master's thesis]. Calgary, AB: University of Calgary; September 2001.
2002	Couillard S. Cartilage Deformation of the Feline Patellofemoral Joint Obtained from Laser Scanning [Master's thesis]. Calgary, AB: University of Calgary; April 2002.
2004	Neu CP. An MRI-Based Technique for Determining Three-Dimensional Deformations in Articular Cartilage Explants [PhD thesis]. Davis, University of California; 2004.
2006	Schmidt TA. Proteoglycan 4 Metabolism and Boundary Lubrication of Articular Cartilage [PhD thesis]. San Diego (UCSD), University of California; 2006.
2009	Wong BL. Biomechanics of Cartilage Articulation: Effects of Degeneration, Lubrication, and Focal Articular Defects [PhD thesis]. San Diego (UCSD), University of California; 2009.
2012	Nguyen QT. Mechanobiology and Biomechanics of Articular Cartilage Repair [PhD thesis]. San Diego (UCSD), University of California; 2012.
2017	Hsu F. Articulation of Human Articular Cartilage Induces Anisotropic Structural Deterioration and Age-Dependent Cellular Responses [PhD thesis]. San Diego (UCSD), University of California; 2017.
2018	Graham B. Novel Approaches to Determine the Role of Diffusive and Convective Transport Environments in Articular Cartilage Function [PhD thesis]. University of Delaware; 2018.