Cartilage stress-relaxation is affected by both the charge concentration and valence of solution cations

Osteoarthritis and Cartilage

Volumn 17, Issue 5, 2009, Pages 669-676

  June, R K ^a   Mejia, K L ^a   Barone, J R ^b   Fyhrie, D P ^a  

^a UNIVERSITY OF CALIFORNIA   (United States)

^b VIRGINIA POLYTECHNIC INSTITUTE AND STATE UNIVERSITY   (United States)

Author keywords

Cartilage biomechanics; Cartilage mechanics; Flow independent viscoelasticity; Polymer dynamics

Indexed keywords

AGGRECAN; CALCIUM CHLORIDE; CATION; POLYMER; SODIUM CHLORIDE; BIOPOLYMER;

ANIMAL TISSUE; ARTICLE; ARTICULAR CARTILAGE; BIOMECHANICS; CONCENTRATION (PARAMETERS); CONTROLLED STUDY; EQUILIBRIUM CONSTANT; IONIC STRENGTH; LOADING TEST; MECHANICAL STRESS; MOLECULAR DYNAMICS; NONHUMAN; PATELLOFEMORAL JOINT; PRIORITY JOURNAL; TISSUE CULTURE; VISCOELASTICITY; ANIMAL; BOVINAE; COMPRESSIVE STRENGTH; ELASTICITY; PATHOPHYSIOLOGY; PHYSIOLOGY; VISCOSITY;

AGGRECANS; ANIMALS; BIOMECHANICS; BIOPOLYMERS; CARTILAGE, ARTICULAR; CATTLE; COMPRESSIVE STRENGTH; ELASTICITY; STRESS, MECHANICAL; VISCOSITY; BIOMECHANICAL PHENOMENA;

EID: 64849115114     PISSN: 10634584     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.joca.2008.09.011     Document Type: Article

References (30)

1. Eckstein F., Lemberger B., Gratzke C., Hudelmaier M., Glaser C., Englmeier K.H., et al. In vivo cartilage deformation after different types of activity and its dependence on physical training status. Ann Rheum Dis 64 2 (2005) 291-295
2. Setton L.A., Mow V.C., and Howell D.S. Mechanical behavior of articular cartilage in shear is altered by transection of the anterior cruciate ligament. J Orthop Res 13 4 (1995) 473-482
3. Sah R.L., Yang A.S., Chen A.C., Hant J.J., Halili R.B., Yoshioka M., et al. Physical properties of rabbit articular cartilage after transection of the anterior cruciate ligament. J Orthop Res 15 2 (1997) 197-203
4. Dean D., Han L., Grodzinsky A.J., and Ortiz C. Compressive nanomechanics of opposing aggrecan macromolecules. J Biomech 39 14 (2006) 2555-2565
5. Dean D., Seog J., Ortiz C., and Grodzinsky A.J. Molecular-level theoretical model for electrostatic interactions within polyelectrolyte brushes: applications to charged glycosaminoglycans. Langmuir 19 13 (2003) 5526-5539
6. Han L., Dean D., Mao P., Ortiz C., and Grodzinsky A.J. Nanoscale shear deformation mechanisms of opposing cartilage aggrecan macromolecules. Biophys J 93 5 (2007) L23-L25
7. Fyhrie D.P., and Barone J.R. Polymer dynamics as a mechanistic model for the flow-independent viscoelasticity of cartilage. J Biomech Eng 125 5 (2003) 578-584
8. June RK, Barone JR, Fyhrie DP. Cartilage stress-relaxation described by polymer dynamics. In: Annual Meeting of the Orthopaedic Research Society. Chicago, IL, 2006.
9. Franzen A., Bjornsson S., and Heinegard D. Cartilage proteoglycan aggregate formation. Role of link protein. Biochem J 197 3 (1981) 669-674
10. Miller E.J., and Matukas V.J. Chick cartilage collagen: a new type of alpha 1 chain not present in bone or skin of the species. Proc Natl Acad Sci U S A 64 4 (1969) 1264-1268
11. Doi M., and Edwards S.F. The Theory of Polymer Dynamics (1988), Oxford University Press, Oxford, UK
12. Khalafi A., and de Gennes P.G. Increased accumulation of superficial zone protein (SZP) in articular cartilage in response to bone morphogenetic protein-7 and growth factors. J Orthop Res 25 3 (2007) 293-303
13. de Gennes P. Relaxation anomalies in linear polymer melts. Macromolecules 35 (2002) 3785-3786
14. June RK, Barone JR, Fyhrie DP. The temperature-dependence of cartilage stress-relaxation rate. In: Annual Meeting of the Orthopaedic Research Society. San Diego, CA; 2007.
15. Heinegard D. Polydispersity of cartilage proteoglycans. Structural variations with size and buoyant density of the molecules. J Biol Chem 252 6 (1977) 1980-1989
16. Huang C.Y., Soltz M.A., Kopacz M., Mow V.C., and Ateshian G.A. Experimental verification of the roles of intrinsic matrix viscoelasticity and tension-compression nonlinearity in the biphasic response of cartilage. J Biomech Eng 125 1 (2003) 84-93
17. Fantner G.E., Hassenkam T., Kindt J.H., Weaver J.C., Birkedal H., Pechenik L., et al. Sacrificial bonds and hidden length dissipate energy as mineralized fibrils separate during bone fracture. Nat Mater 4 8 (2005) 612-616
18. Yeni Y.N., Kim D.G., Dong X.N., Turner A.S., Les C.M., Fyhrie D.P., et al. Do sacrificial bonds affect the viscoelastic and fracture properties of bone?. Clin Orthop Relat Res 443 (2006) 101-108
19. Basser P.J., Schneiderman R., Bank R.A., Wachtel E., and Maroudas A. Mechanical properties of the collagen network in human articular cartilage as measured by osmotic stress technique. Arch Biochem Biophys 351 2 (1998) 207-219
20. Maroudas A., and Bannon C. Measurement of swelling pressure in cartilage and comparison with the osmotic pressure of constituent proteoglycans. Biorheology 18 3-6 (1981) 619-632
21. Frank E.H., and Grodzinsky A.J. Cartilage electromechanics. I. Electrokinetic transduction and the effects of electrolyte pH and ionic strength. J Biomech 20 6 (1987) 615-627
22. Wong M., Ponticiello M., Kovanen V., and Jurvelin J.S. Volumetric changes of articular cartilage during stress relaxation in unconfined compression. J Biomech 33 9 (2000) 1049-1054
23. Buschmann M.D., and Grodzinsky A.J. A molecular model of proteoglycan-associated electrostatic forces in cartilage mechanics. J Biomech Eng 117 2 (1995) 179-192
24. Armstrong C.G., Lai W.M., and Mow V.C. An analysis of the unconfined compression of articular cartilage. J Biomech Eng 106 2 (1984) 165-173
25. Soltz M.A., and Ateshian G.A. A conewise linear elasticity mixture model for the analysis of tension-compression nonlinearity in articular cartilage. J Biomech Eng 122 6 (2000) 576-586
26. Lu X.L., Sun D.D., Guo X.E., Chen F.H., Lai W.M., and Mow V.C. Indentation determined mechanoelectrochemical properties and fixed charge density of articular cartilage. Ann Biomed Eng 32 3 (2004) 370-379
27. Frank E.H., and Grodzinsky A.J. Streaming potentials: a sensitive index of enzymatic degradation in articular cartilage. J Orthop Res 5 4 (1987) 497-508
28. Park S., Krishnan R., Nicoll S.B., and Ateshian G.A. Cartilage interstitial fluid load support in unconfined compression. J Biomech 36 12 (2003) 1785-1796
29. Grodzinsky A.J., Lipshitz H., and Glimcher M.J. Electromechanical properties of articular cartilage during compression and stress relaxation. Nature 275 5679 (1978) 448-450
30. Lux Lu X., Miller C., Chen F.H., Edward Guo X., and Mow V.C. The generalized triphasic correspondence principle for simultaneous determination of the mechanical properties and proteoglycan content of articular cartilage by indentation. J Biomech (2007)