Effects of interfacial debonding on fatigue damage of cemented hip prostheses

Journal of the Chinese Institute of Engineers, Transactions of the Chinese Institute of Engineers,Series A/Chung-kuo Kung Ch'eng Hsuch K'an

Volumn 26, Issue 6, 2003, Pages 791-801

  Hung, Jui Pin ^a   Wu, James Shih Shyn ^b   Chen, Jian Horng ^c  

^a NANYA INSTITUTE OF TECHNOLOGY   (Taiwan)

^b NATIONAL CHUNG HSING UNIVERSITY   (Taiwan)

^c CHUNG SHAN MEDICAL UNIVERSITY   (Taiwan)

Author keywords

Cemented hip prostheses; Fatigue damage

Indexed keywords

BONE CEMENT; CONTINUUM MECHANICS; DEBONDING; FAILURE ANALYSIS; FATIGUE OF MATERIALS; FINITE ELEMENT METHOD; FRACTURE; INTERFACES (MATERIALS); STRESS CONCENTRATION;

CEMENT MANTLES; CEMENTED HIP PROSTHESES; DAMAGE; INTERFACIAL DEBONDING;

HIP PROSTHESES;

EID: 0345412034     PISSN: 02533839     EISSN: 21587299     Source Type: Journal    
DOI: 10.1080/02533839.2003.9670833     Document Type: Article

References (34)

1. Beer, G., 1985. “An Isoparametric Joint/Interface Element for Finite Element Analysis,”. International Journal of Numerical Method in Engineering, 21 (4):585–600.
2. Colombi, P., 2002. “ Fatigue Analysis of Cemented Hip Prostheses:Damage Accumulation Scenario and Sensitivity Analysis,”. International Journal of Fatigue, 24 (7):739–746.
3. Culleton, T. P., Prendergast, P. J., and Taylor, D., 1993. “ Fatigue Failure in the Cement Mantle of an Artificial Hip Joint,”. Clinical Materials, 12 (2):95–102.
4. Davies, J.P., Burke, D.W., O'Connor, D. O., and Harris, W. H., 1987. “Comparison of Fatigue Characteristics of Centrifuged and Uncentrifuged Simplex Bone Cement,”. Journal of Orthopaedic Research, 5 (3):366–371.
5. Dennis, W. B., Evalyn, I. G., William, H. H., and Boston, M., 1984. “Centrifugation as a Method of Improving Tensile and Fatigue Properties of Acrylic Bone Cement,”. Journal of Bone and Joint Surgery, 66A (8):1265–1273.
6. Ebramzadeh, E., Sarmiento, A., McKellop, H. A., Llinas, A., and Gogan, A., 1994. “The Cement Mantle in Total Hip Arthroplasty,”. Journal of Bone and Joint Surgery, 76A (1):77–87.
7. El-Sheikh, H.F., Macdonald, B.J., and Hashmi, M.S. J., 2002. “Material Selections in the Design of the Femoral Components of Cemented Total Hip Replacement,”. Journal of Materials Processing Technology, 122 (2–3):309–317.
8. Gross, S., and Abel, E. W., 2001. “A Finite Element Analysis of Hollow Stemmed Hip Prostheses as a Means of Reducing Stress Shielding of the Femur,”. Journal of Biomechanics, 34 (8):995–1003.
9. Hampton, S. J., 1981. “A Nonlinear Finite Element Model of Adhesive Bond Failure and Application to Total Hip Replacement Analysis,”, IL, USA:University of Illnois. Ph.D. Dissertation
10. Harper, E. J., and Bonfield, W., 2000. “Tensile Characteristics of Ten Commercial Acrylic Bone Cements,”. Journal of Biomedical Materials Research, 53 (5):605–616.
11. Harrigan, T. P., and Harris, W. H., 1991. “Three Dimensional Nonlinear Finite Element Study of the Effect of Cement-Prostheses Debonding in Cemented Femoral Total Hip Components,”. Journal of Biomechanics, 24 (11):1047–1058.
12. Hedia, H. S., Barton, D. C., Fisher, J., and Elmidany, T. T., 1996. “A Method for Shape Optimization of a Hip Prosthesis to Maximize the Fatigue Life of the Cement,”. Medical Engineering & Physics, 18 (8):647–654.
13. Hertzler, J., Miller, M. A., and Kenneth, A. M., 2002. “Fatigue Crack Growth Rate does not Depend on Mantle Thickness:An Idealized Cemented Stem Construct under Torsional Loading,”. Journal of Orthopaedic Research, 20 (4):676–682.
14. James, S.P., Jasty, M., Davies, J., Piehler, H., and Harris, W. H., 1992. “A Fractographic Investigation of PMMA Bone Cement Focusing on the Relationship between Porosity Reduction and Increased Fatigue Life,”. Journal of Biomedical Materials Research, 26 (5):651–662.
15. Jasty, M., Maloney, W.J., Bradgon, C.R., O'Conner, D., Harie, T., and Harris, W. H., 1990. “Histomorphological Studies of the Long-Term Skeletal Responses to Well Fixed Cemented Femoral Components,”. Journal of Bone and Joint Surgery, 72A (8):1220–1229.
16. Jasty, M., Maloney, W.J., Bradgon, C.R., O'Conner, D., Harie, T., and Harris, W. H., 1991. “The Initiation of Failure in Cemented Femoral Components of Hip Arthroplasties,”. Journal of Bone and Joint Surgery, 73(B) (4):551–558.
17. Krause, W., and Mathis, R. S., 1988. “Fatigue Properties of Acrylic Bone Cements:Review of the Literature,”. Journal of Biomedical Materials Research, 22 (A1-Suppl):37–53.
18. Lennon, A. B., and Prendergast, P. J., 2001. “Evaluation of Cement Stresses in Finite Element Analyses of Cemented Orthopaedic Implants,”. Journal of Biomechanical Engineering, 123 (6):623–628.
19. Lewis, G. G., 1997. “Properties of Acrylic Bone Cement State of Art Review,”. Journal of Biomedical Materials Research, 38 (2):155–182.
20. Mann, K. A., Bartel, D. L., and Ayers, D. C., 1997. “Influence of Stem Geometry on Mechanics of Cemented Femoral Hip Components with a Proximal Bond,”. Journal of Orthopaedic Research, 15 (5):700–706.
21. Mann, K. A., Bartel, D. L., Wright, T. M., and Burstein, A. H., 1995. “Coulomb Frictional Interfaces in Modeling Cemented Total Hip Replacements:A More Realistic Model,”. Journal of Biomechanics, 28 (9):1067–1078.
22. Mann, K. A., Bartel, D. L., Wright, T. M., and Ingraffea, A. R., 1991. “Mechanical Characteristics of the Stem-Cement Interface,”. Journal of Orthopaedic Research, 9 (5):798–808.
23. Marrison, J. P., 1967. “The Force Transmitted at the Human Knee Joint during Activity,”, Scotland, UK:University of Strathclyde. Ph.D. Dissertation
24. McCormack, B.A. O., and Prendergast, P. J., 1999. “Microdamage Accumulation in the Cement Layer of Hip Replacements under Flexural Loading,”. Journal of Biomechanics, 32 (5):467–475.
25. McCormack, B.A. O., Prendergast, P. J., and Gallagher, D. G., 1996. “An Experimental Study of Damage Accumulation in Cemented Hip Prostheses,”. Clinical Biomechanics, 11 (4):214–219.
26. Murphy, B. P., and Prendergast, P. J., 1999. “Measurement of Non-Linear Microcrack Accumulation Rates in Polymethylmethacrylate Bone Cement under Cyclic Loading,”. Journal of Materials Science:Materials in Medicine, 10 (12):779–781.
27. Nicolella, D. P., Thacker, B. H., Katoozian, H., and Davy, D. T., “Probabilistic Risk Analysis of a Cemented Hip Implant,”. Proceedings of the 2001 Bioengineering Conference. Vol. 50, pp. 427–428. ASME, Bioengineering Division.
28. Nuno, N., Amabili, M., Groppetti, R., and Rossi, A., 2002. “ Static Coefficient of Friction between Ti-6Al-4V and PMMA used in Cemented Hip and Knee Implants,”. Journal of Biomedical Materials Research, 59 (1):191–200.
29. Ohashi, K. L., Romero, A. C., McGowan, P. D., Maloney, W. J., and Dauskardt, R. H., 1998. “Adhesion and Reliability of Interfaces in Cemented Total Joint Arthroplasties,”. Journal of Orthopaedic Research, 16 (6):705–714.
30. Paul, J. P., 1967. “Force at the Human Hip Joint,”, Glasgow, Scotland, UK:University of Glasgow. Ph.D. Dissertation
31. Stolk, J., Verdonschot, N., and Huiskes, R., “FE Simulation of Damage Accumulation in Cement around a Prosthetic Hip Stem,”. Proceedings of 12th Conference of the European Society of Biomechanics. Dublin. pp. 112
32. Topoleski, L.D. T., 1990. “Fractorgraphic Analysis of in Vivo PMMA Bone Cement Failure Mechanism,”. Journal of Biomedical Materials Research, 24 (2):135–154.
33. Verdonschot, N., and Huiskes, R., 1997. “The Effects of Cement-Stem Debonding in THA on the Long-Term Failure Probability of Cement,”. Journal of Biomechanics, 30 (8):795–802.
34. Wu, J.S. S., Wu, J. M., Chou, Y. L., and Yang, C. L., 1989. “Stress Analysis of the Human Femur by Using Three-Dimensional Finite Element Method,”. Chinese Journal of Medical and Biological Engineering, 9 (2):58–63.