Stress distributions in the acetabular region, I:​ before and after total joint replacement

Vasu, R.; Carter, D. R.; Harris, W. H.

Affiliations

¹Orthopaedic Research Laboratories, Massachusetts General Hospital and Harvard Medical School, Boston, MA 02114, U.S.A.

Abstract

Two-dimensional finite element analyses of the acetabular region before and after hip replacement were conducted. The distribution of pressure at the acetabular surface for the single limb stance phase of gait was transformed to nodal loads to simulatein vivo loading conditions. A nonhomogeneous distribution of bone elastic properties was incorporated in the models. The results demonstrated that the principal stresses in the normal acetabulum were aligned with the principal orientations of the trabeculae. Total joint replacement increased the von Mises' equivalent stresses in the cancellous bone immediately superior to the acetabular cup, and increased stresses in the medial wall of the ilium. Biaxial, tensioncompression stresses were created in the layer of bone cement and introduced in the medial wall of the ilium. Tensile stresses in the bone cement were greatest at the superior roof and at the inferior margin of the cup. Tensile stresses in the cup were more pronounced at the margins, particulaly near the inferior lip. The cup tended to close in such a manner as to grip the head of the femoral component as it was pressed between the medial and lateral walls of the ilium.

Links

DOI: 10.1016/0021-9290(82)90247-0

PubMed: 7096368

WoS: A1982NP93100003

History

Received: 1981-04-16

Revised: 1981-08-20

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Cited By (12)

Year	Entry
1982	Carter DR, Vasu R, Harris WH. Stress distributions in the acetabular region, II: effects of cement thickness and metal backing of the total hip acetabular component. J Biomech. 1982;15(3):165-170.
1983	Huiskes R, Chao EYS. A survey of finite element analysis in orthopedic biomechanics: the first decade. J Biomech. 1983;16(6):385-409.
1984	Brown TD, DiGioia AM III. A contact-coupled finite element analysis of the natural adult hip. J Biomech. 1984;17(6):437-448.
1988	Harrigan TP, Jasty M, Mann RW, Harris WH. Limitations of the continuum assumption in cancellous bone. J Biomech. 1988;21(4):269-275.
1989	Carter DR, Orr TE, Fyhrie DP. Relationships between loading history and femoral cancellous bone architecture. J Biomech. 1989;22(3):231-244.
1995	Dalstra M, Huisker R. Load transfer across the pelvic bone. J Biomech. June 1995;28(6):715-724.
1984	Hart RT, Davy DT, Heiple KG. A computational method for stress analysis of adaptive elastic materials with a view toward applications in strain-induced bone remodeling. J Biomech Eng. November 1984;106(4):342-350.
1995	Dalstra M, Huiskes R, van Erning L. Development and validation of a three-dimensional finite element model of the pelvic bone. J Biomech Eng. August 1995;117(3):272-278.
2005	Anderson AE, Peters CL, Tuttle BD, Weiss JA. Subject-specific finite element model of the pelvis: development, validation and sensitivity studies. J Biomech Eng. June 2005;127(3):365-373.
2017	Webster CE. The Blast Pelvis [PhD thesis]. Imperial College London; October 2017.
2017	Fung A. Experimental Validation of Finite Element Predicted Bone Strain in the Human Metatarsal [Master's thesis]. Calgary, AB: University of Calgary; April 2017.
2007	Anderson AE. Computational Modeling of Hip Joint Mechanics [PhD thesis]. University of Utah; April 2007.