Sage Journals: Discover world-class research

Abstract

Residual stresses resulting from the shrinkage of polymethyl methacrylate (PMMA) bone cement have been implicated in the formation of cracks in cement mantles following total hip arthroplasty. This study investigates whether two such cements, with differentiated solidification characteristics (i.e. working and setting times), display significant differences in their residual stress characteristics in an experiment designed to replicate the physical conditions of total hip arthroplasty. Experiments were performed using a representative femoral construct to measure and compare the temperatures and residual strains developed for standard PMMA cement mantles (CMW® 1 Gentamicin) and slow curing cement mantles (SmartSet® HV Gentamicin) during and following polymerization. These experimental results revealed no statistically significant difference (t-test, p > 0.05) for peak exotherm temperature and residual strain levels between the cements (measured after 3 h). The tailored polymerization characteristics of the slow-curing cement do not significantly affect residual stress generation, compared with the standard cement. It is often considered that residual stresses significantly relax following polymerization and before biomechanical loads are first applied during rehabilitation (up to 3 days later). This was examined for durations of 18 h to 3 days. Axial strains in the model femur and stem reduced by averages of 5.5 and 7.9 per cent respectively, while hoop strains in the stem exhibited larger reductions. An axisymmetric transient thermoelastic finite element model of the experiment was developed, allowing residual stresses to be predicted based on differential scanning calorimetry (DSC) measurements of the heat released throughout the exothermic curing reaction. The model predictions closely replicated the experimental measurements of both temperature and residual strain at 3 h, suggesting that residual strains can be fully accounted for by the thermal contraction mechanism associated with cooling after solidification.

Keywords

residual stress bone cement total hip arthroplasty

Get full access to this article

View all access options for this article.

References

Australian Orthopaedic Association. National Joint Replacement Registry; Annual Report 2004, available from http://www.aoa.org.au/ (accessed 10 October 2005).

McCormack

B. A.

Prendergast

P. J.

Microdamage accumulation in the cement layer of hip replacements under flexural loading. J. Biomechanics, 1999, 32(5), 467–475.

Kuhn

K. D.

Bone cements: Up to date comparison of physical and chemical properties of commercial materials, 2000, pp. 1–115 (Springer-Verlag, Berlin).

Dunne

N. J.

Orr

J. F.

Thermal characteristics of curing acrylic bone cement. ITBM-RBM, 2000, 22, 88–97.

Dunne

N. J.

Orr

J. F.

Curing characteristics of acrylic bone cement. J. Mater. Sci. Mater. Med., 2002, 13(1), 17–22.

Dunne

N. J.

Evaluation of static and dynamic properties of polymethyl methacrylate bone cements and their effects on implant fixation. PhD. Thesis, The Queen's University Belfast, Belfast, UK, 1996.

Rahman

M. M.

Olabi

A. G.

Hashmi

M. S. J.

Thermal properties of curing acrylic bone cement mixed at different vacuum level. In Proceedings of the 12th International Conference on Experimental Mechanics, Politecnico di Bari, Italy 2004.

Harper

E. J.

Bonfield

Tensile characteristics of ten commercial acrylic bone cements. J. Biomed. Mater. Res., 2000, 53(5), 605–616.

Lewis

Properties of acrylic bone cement: State of the art review. J. Biomed. Mater. Res., 1997, 38(2), 155–182.

10.

Charnley

Acrylic cement in orthopaedic surgery, 1970, pp. 1–550 (E. and S. Livingstone, Edinburgh and London).

11.

Gilbert

J. L.

Hasenwinkel

J. M.

Wixson

R. L.

Lautenshlager

E. P.

A theoretical and experimental analysis of polymerisation shrinkage of bone cement: A potential major source of porosity. J. Biomed. Mater. Res., 2000, 52(1), 210–218.

12.

Silikas

Al-Kheraif

Watts

D. C.

Influence of P/L ratio and peroxide/amine concentrations on shrinkage-strain kinetics during setting of PMMA/MMA biomaterials formulations. Biomaterials, 2005, 26(2), 197–204.

13.

Huiskes

Some fundamental aspects of human joint replacement. Analyses of stresses and heat conduction in bone-prosthesis structures. Acta Orthopaedica Scand. Suppl., 1980, 185, 1–208.

14.

Stachiewicz

J. W.

Miller

Burke

D. L.

Hoop stress generated by shrinkage of polymethyl-methacrylate as a source of prosthetic loosening. In Digest of the 11th International Conference on Medical and Biological Engineering, Ottawa 1976, pp. 532–533.

15.

Whelan

M. P.

Kenny

R. P.

Cavalli

Lennon

A. B.

Prendergast

P. J.

Application of optical fibre Bragg gating sensors to the study of PMMA curing. In Proceedings of the 12th Conference of the European Society of Biomechanics (Eds Prendergast

P. J.

Lee

T. C.

Carr

A. J.

), Dublin, Ireland, 2000.

16.

Lennon

A. B.

Prendergast

P. J.

Whelan

M. P.

Kenny

R. P.

Cavalli

Modelling of temperature history and residual stress generation due to curing in polymethylmethacrylate. In Proceedings of the 12th Conference of the European Society of Biomechanics (Eds Prendergast

P. J.

Lee

T. C.

Carr

A. J.

), Dublin, Ireland, 2000.

17.

Orr

J. F.

Dunne

N. J.

Quinn

J. C.

Shrinkage stresses in bone cement. Biomaterials, 2000, 24(17), 2933–2940.

18.

Ahmed

A. M.

Pak

Burke

D. L.

Miller

Transient and residual stresses and displacements in self-curing bone cement - part I: Characterization of relevant volumetric behavior of bone cement. J. Biomech. Engng, 1982, 104(1), 21–27.

19.

Roques

Browne

Taylor

New

Baker

Quantitative measurement of the stresses induced during polymerisation of bone cement. Biomaterials, 2004, 25(18), 4415–4424.

20.

Nuno

Amabili

Modelling debonded stem-cement interface for hip implants: Effect of residual stresses. Clin. Biomech. (Bristol Avon), 2002, 17(1), 41–48.

21.

Zor

Kucuk

Aksoy

Residual stress effects on fracture energies of cement-bone and cement-implant interfaces. Biomaterials, 2002, 23(7), 1595–1601.

22.

Ahmed

A. M.

Nair

Burke

D. L.

Miller

Transient and residual stresses and displacements in self-curing bone cement - part II: Thermoelastic analysis of the stem fixation system. J. Biomech. Engng, 1982, 104(1), 28–37.

23.

Nuno

Avanzolini

Residual stresses at the stem-cement interface of an idealized cemented hip stem. J. Biomechanics, 2002, 35(6), 849–852.

24.

Mann

K. A.

Bartel

D. L.

Wright

T. M.

Ingraffea

A. R.

Mechanical characteristics of the stem-cement interface. J. Orthop. Res., 1991, 9(6), 798–808.

25.

Lennon

A. B.

Prendergast

P. J.

Residual stress due to curing can initiate damage in porous bone cement: Experimental and theoretical evidence. J. Biomech. Engng, 2002, 35(3), 311–321.

26.

Wang

Mason

The effects of curing history on residual stresses in bone cement during hip arthroplasty. J. Biomed. Mater. Res. Part B: Appl. Biomater., 2004, 70(1), 30–36.

27.

Eden

O. R.

Lee

A. J.

Hooper

R. M.

Stress relaxation modelling of polymethylmethacrylate bone cement. Proc. Instn Mech. Engrs Part H: J. Engineering in Medicine, 2002, 216(3), 195–199.

28.

Lee

A. J.

Ling

R. S.

Gheduzzi

Simon

J. P.

Renfro

R. J.

Factors affecting the mechanical and viscoelastic properties of acrylic bone cement. J. Mater. Sci.; Mater. Med., 2002, 13(11), 1021–1028.

29.

DePuy CMW® 1 Gentamicin. Available from http://www.jnjgateway.com/homejhtmlloc=USENGviewContent09008b98807c074109008b98807c0741 (accessed 9 July 2007).

30.

SmartSet® HV. Available from http://www.jnjgateway.com/home.jhtmlloc=USENGview-Content=09008b9880768228Id=09008b9880768228 (accessed 9 July 2007).

31.

National Instruments Inc, USA. Available from http://sine.ni.com/nips/cds/view/p/lang/en/nid/1867 (accessed 9 July 2007).

Effect of curing characteristics on residual stress generation in polymethyl methacrylate bone cements

Abstract

Abstract

Keywords

Get full access to this article

References