This paper is a sequel to previously published findings showing that mechanical indentation alone cannot clearly discriminate between normal and degraded articular cartilage. Consequently, the structural elasticity potential ℜc = ɛr/σi, which combines indentation stress σi with near-instantaneous rebound ɛr following unloading, is hypothesized as a potential cartilage assessment parameter, which arguably measures the integrity of the collagen fibre—proteoglycan entrapment system. To establish the validity of our hypothesis, samples of normal intact, artificially degraded, and osteoarthritic bovine cartilage were subjected to quasi-static compression at 0.1 s−1 and 0.025 s−1 to 30 per cent strain and then unloaded. A significant reduction in recovery was observed for artificially and naturally degraded samples in the first 5 s following unloading (p<0.01). The structural elasticity potential provided a considerable improvement over the results obtained using the individual indentation and rebound parameters to distinguish between paired normal and artificially degraded samples and indicated a high statistical significance of p<0.005 when applied to the differentiation of normal and osteoarthritic samples.
BrownC. P.CrawfordR. W.OloyedeA.‘Indentation stiffness does not discriminate between normal and degraded articular cartilage.’Clin. Biomechanics22 (2007): 843–848
2.
SwannA. C.SeedhomB. B.‘The stiffness of normal articular cartilage and the predominant acting stress levels.’Br. J. Rheumatology32 (1993): 16–25
3.
BroomN. D.FlachsmannR.‘Physical indicators of cartilage health: The relevance of compliance, thickness, swelling and fibrillar texture.’J. Anat.202 (6) (2003): 481–494
4.
KempsonG. E.‘Relationship between the tensile properties of articular cartilage from the human knee and age.’Ann. Rheumatic Dis.41 (1982): 508–511
5.
YaoJ. Q.SeedhomB. B.‘Mechanical conditioning of articular cartilage to prevalent stress.’Br. J. Rheumatology33 (1993): 16–25
6.
VasaraA. I.JurvelinJ.PetersonL.KivirantaI.‘Arthroscopic cartilage indentation and cartilage lesions of anterior cruciate ligament-deficient knees.’Int. J. Sports Medicine33 (3) (2005): 408–414
7.
ElmoreS. M.SokoloffL.NorrisG.CarmeciP.‘Nature of imperfect elasticity of articular cartilage.’J. Appl. Physiology18 (2) (1963): 393–396
8.
SokoloffL.‘Elasticity of ageing cartilage.’Fed. Proc.25 (3) (1966): 1089–1095
9.
HarrisE. D. J.ParkerH. G.RadinE. L.KraneS. M.‘Effects of proteolytic enzymes on structural and mechanical properties of cartilage.’Arthritis Rheumatism15 (5) (1972): 497–503
10.
KempsonG. E.SpiveyC. J.SwansonS. A. V.FreemanM. A. R.‘Patterns of cartilage stiffness on normal and degenerative human femoral heads.’J. Biomechanics4 (1971): 597–609
11.
KempsonG. E.TukeM. A.DingleJ. T.BarrettA. J.HorsfieldP. H.‘The effects of proteolytic enzymes on the mechanical properties of adult human articular cartilage.’Biochimica Biophysica Acta428 (1976): 741–760
12.
AppleyardR. C.GhoshP.SwainM. V.‘Biomechanical, histological and immunohistological studies of patellar cartilage in an ovine model of osteoarthritis induced by lateral meniscectomy.’Osteoarthritis Cartilage7 (3) (1999): 281–294
13.
ArokoskiJ.JurvelinJ.KivirantaI.TammiM.HelminenH. J.‘Softening of the lateral condyle articular cartilage in the canine knee joint after long distance (up to 40 km/day) running training lasting one year.’Int. J. Sports Medicine15 (1994): 254–260
14.
International Cartilage Repair Society, ‘ICRS cartilage injury evaluation package.’ In Proceedings of the ICRS 2000 Standards Workshop, Schloss Münchenwiler, Switzerland, 27–30 January 2000 (International Cartilage Repair Society, Zollikon).
15.
LangelierE.BuschmannM. D.‘Increasing strain and strain rate strengthen transient stiffness, but weaken the response to subsequent compression for articular cartilage in unconfined compression.’J. Biomechanics36 (2003): 853–859
16.
FicklinT.ThomasG.BarthelJ. C.AsanbaevaA.ThonarE. J.MasudaK.ChenA. C.SahR. L.DavolA.KlischS. M.‘Articular cartilage mechanical and biochemical property relations before and after in vitro growth.’J. Biomechanics40 (2007): 3607–3614
17.
FranzT.HaslerE. M.HaggR.WeilerC.JakobR. P.Mainil-VarletP.‘In situ compressive stiffness, biochemical composition, and structural integrity of articular cartilage in the human knee joint.’Osteoarthritis Cartilage9 (6) (2001): 582–592
18.
BrownC. P.MoodyH.CrawfordR.OloyedeA.‘A novel approach to the development of bencharking parameters for characterising cartilage health.’Connective Tissue Res.48 (2007): 52–61
19.
MoodyH. R.BrownC. P.BowdenJ. C.McElwainD. L. S.CrawfordR. W.OloyedeA.‘In vitro degradation of articular cartilage — does trypsin treatment produce consistent results?’J. Anat.209 (2006): 259–267
20.
BroomN. D.‘Further insights into the structural principles governing the function of articular cartilage.’J. Anat.139 (1984): 275–294
WongM.CarterD. R.‘Articular cartilage functional histomorphology and mechanobiology: A research perspective.’Bone33 (2003): 1–13
23.
HunzikerE. B.‘Articular cartilage repair: Basic science and clinical progress. A review of the current status and prospects.’Osteoarthritis Cartilage10 (6) (2002): 432–463
HarriganT. P.MannR. W.‘State variables for modelling physical aspects of articular cartilage.’Int. J. Solids Structs23 (9) (1987): 1205–1218
26.
OloyedeA.BroomN. D.‘Is classical consolidation theory applicable to articular cartilage deformation?’Clin. Biomechanics6 (1991): 206–212
27.
MaroudasA.‘Physico-chemical properties of articular cartilage In Adult articular cartilage (Ed. FreemanM. A. R.) 1997, pp. 215–290 (Pitman Medical, Tunbridge Wells, Kent).
28.
MaroudasA.MizrahiJ.KatzE. P.WachtelE. J.SoudryM.‘Physicochemical properties and functional behaviour of normal and osteoarthritic human cartilage In Articular cartilage biochemistry (Eds KuettnerK. E., SchleyerbachR., HascallV. C.) 1986, (Raven Press, New York) pp. 311–329.
29.
MaroudasA.VennM.‘Chemical composition and swelling of normal and osteoarthrotic femoral head cartilage: II. Swelling.’Ann. Rheumatic Dis.36 (1977): 399–406
30.
BarkerM. K.SeedhomB. B.‘The relationship of the compressive modulus of articular cartilage with its deformation response to cyclic loading: Does cartilage optimise its modulus so as to minimize the strains arising in it due to the prevalent loading regime?’Rheumatology40 (2001): 274–284
31.
PooleA. R.RizkallaG.IonescuM.ReinerA.BrooksE.RorabeckC.BourneR.BogochE.‘Osteoarthritis in the human knee — a dynamic process of cartilage matrix degradation, synthesis and reorganization.’Agents Actions Suppl.39 (1993): 3–13
32.
LippielloL.HallD.MankinH. J.‘Collagen synthesis in normal and osteoarthritic human cartilage.’J. Clin. Invest.59 (1977): 593–600
33.
SandellL. J.HeringT. M.‘Biochemistry and molecular and cell biology of articular cartilage in osteoarthritis.’ In Osteoarthritis: diagnosis and medical/surgical management (Eds MoskowitzR. W.HowellD. S.AltmanR. D.BuchwalterJ. A.GoldbergV. M.), 3rd edition, 2001, pp. 115–143 (Saunders, Philadelphia, Pennsylvania).
LyyraT.JurvelinJ.PitkänenP.VäätäinenU.KivirantaI.‘Indentation instrument for the measurement of cartilage stiffness under arthroscopic control.’Physics Medicine Biology17 (5) (1995): 395–399
36.
DudaG. N.KleemannR. U.BluecherU.WeilerA.‘A new device to detect early cartilage degeneration.’Am. J. Sports Medicine32 (2004): 693–698
