The effect of three-dimensional shape optimization on the probabilistic response of a cemented femoral hip prosthesis

Reference 

1. Ang AH-S, Tang WH. Probability Concepts in Engineering Planning and Design. New York: Wiley; 1975;
2. Beckenbaugh RD, Ilstrup DM. Total hip arthroplasty. The Journal of Bone and Joint Surgery—American Volume. 1978;60:306–313
3. Bundy KJ, Penn RW. The effect of surface preparation on metal/bone cement interfacial strength. Journal of Biomedical Materials Research. 1987;21:773–805
   • MEDLINE
   • CrossRef
4. Chang PB, Mann KA, Bartel DL. Cemented femoral stem performance. Effects of proximal bonding, geometry, and neck length. Clinical Orthopaedics and Related Research. 1998;355:57–69
   • CrossRef
5. Chang PB, Williams BJ, Santner TJ, Notz WI, Bartel DL. Robust optimization of total joint replacements incorporating environmental variables. Journal of Biomechanical Engineering. 1999;121:304–310
   • MEDLINE
   • CrossRef
6. Davies JP, Harris WH. Tensile bonding strength of the cement–prosthesis interface. Orthopedics. 1994;17:171–173
   • MEDLINE
7. Gardiner RC, Hozack WJ. Failure of the cement–bone interface. A consequence of strengthening the cement–prosthesis interface?. The Journal of Bone and Joint Surgery—British Volume. 1994;76:49–52
8. Haldar A, Mahadevan S. Probability, Reliability, and Statistical Methods in Engineering Design. New York: Wiley; 2000;
9. Harrigan TP, Kareh JA, O’Connor DO, Burke DW, Harris WH. A finite element study of the initiation of failure of fixation in cemented femoral total hip components. Journal of Orthopaedic Research. 1992;10:134–144
10. Huiskes R, Boeklagen R. Mathematical shape optimization of hip prosthesis design. Journal of Biomechanics. 1989;22:793–804
    • MEDLINE
    • CrossRef
11. Jasty M, Maloney WJ, Bragdon CR, O’Connor DO, Haire T, Harris WH. The initiation of failure in cemented femoral components of hip arthroplasties. Journal of Bone and Joint Surgery—British Volume. 1991;73:551–558
12. Katoozian, H., 1993. Three dimensional design optimization of femoral components of total hip endoprosthesis. Ph.D. Thesis, Case Western Reserve University, Cleveland.
13. Katoozian H, Davy DT. Effects of loading conditions and objective function on three-dimensional shape optimization of femoral components of hip endoprostheses. Medical Engineering & Physics. 2000;22:243–251
    • Abstract
    • Full Text
    • Full-Text PDF (320 KB)
    • CrossRef
14. Keaveny TM, Bartel DL. Effects of porous coating and collar support on early load transfer for a cementless hip prosthesis. Journal of Biomechanics. 1993;26:1205–1216
    • MEDLINE
    • CrossRef
15. Keller JC, Lautenschlager EP, Marshall GW, Meyer PR. Factors affecting surgical alloy/bone cement interface adhesion. Journal of Biomedical Materials Research. 1980;14:639–651
    • MEDLINE
    • CrossRef
16. Krause W, Mathis RS, Grimes LW. Fatigue properties of acrylic bone cement: S–N, P–N, and P–S–N data. Journal of Biomedical Materials Research. 1988;22:221–244
    • MEDLINE
    • CrossRef
17. Lennon AB, Prendergast PJ. Evaluation of cement stresses in finite element analyses of cemented orthopaedic implants. Journal of Biomechanical Engineering. 2001;123:623–628
    • MEDLINE
    • CrossRef
18. Lewis G, Austin GE. Mechanical properties of vacuum-mixed acrylic bone cement. Journal of Applied Biomaterials. 1994;5:307–314
19. Maloney WJ, Schmalzried T, Harris WH. Analysis of long-term cemented total hip arthroplasty retrievals. Clinical Orthopaedics and Related Research. 2002;405:70–78
    • CrossRef
20. Mann KA, Bartel DL, Wright TM, Burstein AH. Coulomb frictional interfaces in modeling cemented total hip replacements: a more realistic model. Journal of Biomechanics. 1995;28:1067–1078
    • Abstract
    • Full-Text PDF (3192 KB)
    • CrossRef
21. Nicolella, D.P., 2001. A probabilistic analysis of the cemented femoral component of a total hip replacement. Ph.D. Thesis, Case Western Reserve University, Cleveland.
22. Nicolella, D.P., Wu, Y.T., Katoozian, H., Davy, D.T., 1997. Probabilistic analysis of the structural response of the cement in a cemented hip implant. In: Proceedings of the American Society of Mechanical Engineers Summer Bioengineering Conference, vol. 35, pp. 171–172.
23. Nicolella DP, Thacker BH, Katoozian H, Davy DT. Probabilistic risk analysis of a cemented hip implant. Journal of Mathematical Modeling and Scientific Computing. 2001;13:98–108
24. Pepin, J.E., Thacker, B.H., Rodriguez, E.A., Riha, D.S., 2002. A probabilistic analysis of a nonlinear structure using random fields to quantify geometric shape uncertainties. In: Proceedings AIAA/ASME/ASCE/AHS/ASC 43rd Structures, Structural Dynamics, and Materials (SDM) Conference, Denver, CO.
25. Rho, J., 1991. Mechanical properties of human cortical and cancellous bone. Ph.D. Thesis, University of Texas Southwestern Medical Center at Dallas.
26. Saha S, Pal S. Mechanical properties of bone cement: a review. Journal of Biomedical Materials Research. 1984;18:435–462
    • MEDLINE
    • CrossRef
27. Sih GC, Matic P, Berman AT. Failure prediction of the total hip prosthesis system. Journal of Biomechanics. 1981;14:833–841
    • MEDLINE
    • CrossRef
28. Thacker, B.H., 1996. Probabilistic finite element methods for transient analysis of nonlinear continua. Ph.D. Thesis, The University of Texas at Austin.
29. Wheeler JP, Miles AW, Clift SE. The influence of the stem–cement interface in total hip replacement—a comparison of experimental and finite element approaches. Proceedings of the Institution of Mechanical Engineers, Part H. 1997;211:181–186
30. Wu YT, Millwater HR, Cruse TA. An advanced probabilistic structural analysis method for implicit performance functions. AIAA Journal. 1990;28:1663–1669
31. Yoon YS, Jang GH, Kim YY. Shape optimal design of the stem of a cemented hip prosthesis to minimize stress concentration in the cement layer. Journal of Biomechanics. 1989;22:1279–1284
    • MEDLINE
    • CrossRef