A viscoelastic analysis of the tensile weakening of deep femoral head articular cartilage

Abstract

Articular cartilage from below the surface of the femoral head of the hip joint shows a profound age-dependent weakening in its tensile mechanical properties. This ageing is also associated with a reduced viscoelastic response in the older tissue. A constitutive model of the viscoelastic behaviour of deep articular cartilage (as discussed by Egan in 1988) is used to generate a graphical pattern which represents the mechanical behaviour. This constitutive approach suggests that the tensile weakening of the older cartilage is due to an age-related reduction in the recruitment of load-carrying structures as the tissue is deformed.

The viscoelastic constitutive model also predicts a reduction in the tensile strength of deep articular cartilage with rate of deformation. This prediction is supported by experimental fracture stress data.

A weakening of the tensile integrity of the microstructure of articular cartilage could make the tissue less able to sustain normal compressive physiological loading without damage and thus make the tissue more susceptible to osteoarthritic degeneration. The constitutive approach indicates that the weakening of the older tissue may be related to changes within the microstructure which determine how applied mechanical energy is stored and dissipated.

Keywords

hip articular cartilage tensile mechanical behaviour viscoelasticity constitutive model fracture strength ageing

Get full access to this article

View all access options for this article.

References

Bergmann

Kniggendorf

Graichen

Rohlmann

Influence of shoes and heel strike on the loading of the hip joint. J. Biomechanics, 1995, 28, 817–827.

Maroudas

Physicochemical properties of articular cartilage. In Adult Articular Cartilage (Ed. Freeman

M. A. R.

), 2nd edition, 1979, pp. 215–290 (Pitman Medical, Tunbridge Wells, Kent).

Zhu

Mow

V. C.

Koob

T. J.

Eyre

D. R.

Viscoelastic shear properties of articular cartilage and the effects of glycosidase treatments. J. Orthop. Res., 1993, 11, 771–781.

Mow

V. C.

Holmes

M. H.

Lai

W. M.

Fluid transport and the mechanical properties of articular cartilage a review. J. Biomechanics, 1984, 17, 377–394.

Kempson

G. E.

Mechanical properties of articular cartilage. In Adult Articular Cartilage (Ed. Freeman

M. A. R.

), 2nd edition, 1979, pp. 333–414 (Pitman Medical, Tunbridge Wells, Kent).

Bader

D. L.

Kempson

G. E.

Barrett

A. J.

Webb

The effects of leucocyte elastase on the mechanical properties of adult human articular cartilage in tension. Biochim. Biophys. Acta, 1981, 677, 103–108.

Kempson

G. E.

Tuke

M. A.

Dingle

J. T.

Barrett

A. J.

Horsfield

P. H.

The effects of proteolytic enzymes on the mechanical properties of adult human articular cartilage. Biochim. Biophys. Acta, 1976, 428, 741–760.

Schmidt

M. B.

Mow

V. C.

Chun

L. E.

Eyre

D. R.

Effects of proteoglycan extraction on the tensile behavior of articular cartilage. J. Orthop. Res., 1990, 8, 353–363.

Broom

N. D.

Silyn-Roberts

Collagen-collagen versus collagen-proteoglycan interactions in the determination of cartilage strength. Arthritis Rheum., 1990, 33, 1512–1517.

10.

Akizuki

Mow

V. C.

Müller

Pita

J. C.

Howell

D. S.

Manicourt

D. H.

Tensile properties of human knee joint cartilage. I: Influence of ionic conditions, weight bearing, and fibrillation on the tensile modulus. J. Orthop. Res., 1986, 4, 379–392.

11.

Roberts

Weightman

Urban

Chappell

Mechanical and biochemical properties of human articular cartilage in osteoarthritic femoral heads and in autopsy specimens. J. Bone Jt Surg., 1986, 68B, 278–288.

12.

Kempson

G. E.

Relationship between the tensile properties of articular cartilage from the human knee and age. Ann. Rheum. Dis., 1982, 41, 508–511.

13.

Egan

J. M.

A constitutive study of the age-dependent mechanical behaviour of deep articular cartilage: Model construction and simulated failure. Clin. Biomechanics, 1988, 3, 204–214.

14.

Kempson

G. E.

Age-related changes in the tensile properties of human articular cartilage: A comparative study between the femoral head of the hip joint and the talus of the ankle joint. Biochim. Biophys. Acta, 1991, 1075, 223–230.

15.

Venn

M. F.

Variation of chemical composition with age in human femoral head cartilage. Ann. Rheum. Dis., 1977, 37, 168–174.

16.

Mort

J. S.

Poole

R. A.

Roughley

P. J.

Age-related changes in the structure of proteoglycan link proteins in normal human articular cartilage. Biochim. J., 1983, 214, 269–272.

17.

Buckwalter

J. A.

Roughley

P. J.

Rosenberg

L. C.

Age-related changes in cartilage proteoglycans: Quantitative electron microscopic studies. Microsc. Res. Technol., 1994, 28, 398–408.

18.

Roughley

P. J.

Lee

E. R.

Cartilage proteoglycans: Structure and potential functions. Microsc. Res. Technol., 1994, 28, 385–397.

19.

Dudhia

Davidson

C. M.

Wells

T. M.

Vynios

D. H.

Hardingham

T. E.

Bayliss

M. T.

Age-related changes in the content of the C-terminal region of aggrecan in human articular cartilage. Biochem. J., 1996, 319, 489–498.

20.

Egan

J. M.

A constitutive model for the mechanical behaviour of soft connective tissues. J. Biomechanics, 1987, 20, 681–692.

21.

Egan

J. M.

A new look at linear visco-elasticity. Mater. Lett., 1997, 31, 351–357.

22.

Aspden

R. M.

Hulkins

D. W. L.

Collagen orientation in articular cartilage, determined by X-ray diffraction, and its relationship to tissue function. Proc. R. Soc. Land. B, 1981, 212, 299–304.

23.

Kelly

P. A.

Transmission of rapidly applied loads through articular cartilage. Part 1: Uncracked cartilage. Proc. Instn Mech. Engrs, Part H, Journal of Engineering in Medicine, 1996, 210 (H1), 27–37.