A novel indentation method was used to investigate the response of articular cartilage in the non-directly loaded region. The indenter contained a relief channel that allowed a tissue bulge to develop within it under load. Healthy bovine tissue samples were statically loaded at a nominal compressive stress of 3.6 MPa. The tissue's equilibrium deformed state was chemically fixed. Differential interference contrast microscopy was used to obtain high-resolution images of the deformed microstructure in the region of the tissue bulge.
At the submicro-level, the fibrillar resistance to load is highly complex such that regions of relative compression and tension coincide along a single radial direction. This fibrillar level response is manifested as large-scale matrix shear effects within the bulge region. Further, the surface layer, besides being strain-limiting in the tangential direction, has an intrinsic resistance to axial load. Finally, the pattern of load-induced fluid flow is seen to traverse zonal depths and hence suggests an added complexity to the overall permeability in the deformed tissue matrix.
MaroudasA.Physico-chemical properties of articular cartilage. In Adult articular cartilage, 2nd edition (Ed. FreemanM. A. R.), 1979 (Pitman Medical, Tunbridge Wells).
2.
MankinH. J.MowV. C.BuckwalterJ. A.IannottiJ. P.RatcliffeA.Articular cartilage structure, composition, and function. In Orthopae-dic basic science: biology and biomechanics of the musculoskeletal system, 2nd edition (Eds BuckwalterJ. A.EinhornT. A.SimonS. R.), 2000, pp. 443–470 (American Academy of Orthopaedic Surgeons, Rosemont, Illinois).
3.
MartinR. B.BurrD. M.SharkeyN. A.Skeletal biology. Skeletal tissue mechanics, 1998, pp. 29–79 (Springer-Verlag, New York).
4.
KempsonG. E.FreemanM. A.SwansonS. A.The determination of a creep modulus for articular cartilage from indentation tests of the human femoral headJ. Biomech.4 (4) (1971239–250
5.
HayesW. C.KeerL. M.HerrmannG.MockrosL. F.A mathematical analysis for indentation tests of articular cartilageJ. Biomech.5 (5) (1972541–551
6.
HoriR. Y.MockrosL. F.Indentation tests of human articular cartilageJ. Biomech.9 (4) (1976259–268
7.
HochD. H.GrodzinskyA. J.KoobT. J.AlbertM. L.EyreD. R.Early changes in material properties of rabbit articular cartilage after meniscectomyJ. Orthop. Res.1 (1) (19834–12
MowV. C.GibbsM. C.LaiW. M.ZhuW. B.AthanasiouK. A.Biphasic indentation of articular cartilage–II. A. numerical algorithm and an experimental studyJ. Biomech.22 (8–9) (1989853–861
10.
ColettiJ. M.Jr.AkesonW. H.WooS. L.A comparison of the physical behavior of normal articular cartilage and the arthroplasty surfaceJ. Bone Jt Surg. Am.54 (1) (1972147–160
11.
BrownT. D.SingermanR. J.Experimental determination of the linear biphasic constitutive coefficients of human fetal proximal femoral chondroepiphysisJ. Biomech.19 (8) (1986597–605
12.
CohenB.LaiW. M.MowV. C.A transversely isotropic biphasic model for unconfined compression of growth plate and chondroepiphysisJ. Biomech. Engng120 (4) (1998491–496
13.
BursaćP. M.ObitzT. W.EisenbergS. R.StamenovićD.Confined and unconfined stress relaxation of cartilage: Appropriateness of a transversely isotropic analysisJ. Biomech.32 (10) (19991125–1130
14.
GarciaJ. J.AltieroN. J.HautR. C.An approach for the stress analysis of transversely isotropic biphasic cartilage under impact loadJ. Biomech. Engng120 (5) (1998608–613
15.
DonzelliP. S.SpilkerR. L.AteshianG. A.MowV. C.Contact analysis of biphasic transversely isotropic cartilage layers and correlations with tissue failureJ. Biomech.32 (10) (19991037–1047
16.
GarciaJ. J.AltieroN. J.HautR. C.Estimation of in situ elastic properties of biphasic cartilage based on a transversely isotropic hypo-elastic modelJ. Biomech. Engng122 (1) (20001–8
17.
WilsonW.van RietbergenB.van DonkelaarC. C.HuiskesR.Pathways of load-induced cartilage damage causing cartilage degeneration in the knee after meniscectomyJ. Biomech.36 (6) (2003845–851
18.
WilsonW.van DonkelaarC. C.van RietbergenB.ItoK.HuiskesR.Stresses in the local collagen network of articular cartilage: A poroviscoelastic fibril-reinforced finite element studyJ. Biomech.37 (3) (2004357–366
19.
WilsonW.DriessenN. J.van DonkelaarC. C.ItoK.Prediction of collagen orientation in articular cartilage by a collagen remodeling algorithmOsteoarthritis Cartilage14 (11) (20061196–1202
20.
ThambyahA.BroomN.Micro-anatomical response of cartilage-on-bone to compression: Mechanisms of deformation within and beyond the directly loaded matrixJ. Anat.209 (5) (2006611–622
21.
ThambyahA.BroomN.On how degeneration influences load-bearing in the cartilage-bone system: A microstructural and micromechanical studyOsteoarthritis Cartilage15 (12) (20071410–1423
22.
KääbM. J.RichardsR. G.ItoK.Ap GwynnI.NötzliH.P.Deformation of chondrocytes in articular cartilage under compressive load: A morphological studyCells Tissues Organs175 (3) (2003133–139
23.
ShiraziR.Shirazi-AdlA.Deep vertical collagen fibrils play a significant role in mechanics of articular cartilageJ. Orthop. Res.26 (5) (2008608–615
24.
FedericoS.GrilloA.La RosaG.GiaquintaG.HerzogW.A transversely isotropic, transversely homogeneous microstructural-statistical model of articular cartilageJ. Biomech.38 (10) (20052008–2018
25.
BroomN. D.MarraD. L.Ultrastructural evidence for fibril-to-fibril associations in articular cartilage and their functional implicationJ. Anat.146 (1986185–200
26.
ChenM. H.BroomN.On the ultrastructure of softened cartilage: A possible model for structural transformationJ. Anat.192 (Pt 3) (1998329–341
27.
ChenM. H.BroomN. D.Concerning the ultrastructural origin of large-scale swelling in articular cartilageJ. Anat.194 (Pt 3) (1999445–461
28.
BroomN.ChenM. H.HardyA.A degeneration-based hypothesis for interpreting fibrillar changes in the osteoarthritic cartilage matrixJ. Anat.199 (Pt 6) (2001683–698
