INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT

K.C. Wong; J. Tong

doi:10.1302/0301-620X.88BSUPP_III.0880384c

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INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT

K.C. Wong
J. Tong

INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT

Wong K, Tong J. INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT. Orthop Procs. 2006;88-B(SUPP_III):384-385. doi:10.1302/0301-620X.88BSUPP_III.0880384c

Wong, K.C., and J. Tong. “INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT.” Orthopaedic Proceedings, vol. 88-B, no. SUPP_III, 2006, pp. 384-385., https://doi.org/10.1302/0301-620X.88BSUPP_III.0880384c

Wong, K., & Tong, J. (2006). INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT. Orthopaedic Proceedings, 88-B(SUPP_III), 384-385. https://doi.org/10.1302/0301-620X.88BSUPP_III.0880384c

Wong, K. and Tong, J. (2006) “INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT.” Orthopaedic Proceedings, 88-B(SUPP_III), pp. 384-385. Available at: https://doi.org/10.1302/0301-620X.88BSUPP_III.0880384c

Wong, K.C., and J. Tong. “INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT.” Orthopaedic Proceedings 88-B, no. SUPP_III (2006): 384-385. https://doi.org/10.1302/0301-620X.88BSUPP_III.0880384c

Wong K, Tong J. INTERFACIAL STRESS DISTRIBUTION IN THE ACETABULAR REGION BEFORE AND AFTER TOTAL HIP REPLACEMENT. Orthop Procs. 2006 Oct 1;88-B(SUPP_III):384-385. https://doi.org/10.1302/0301-620X.88BSUPP_III.0880384c

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Abstract

Interfacial stress distributions in the acetabular region have been studied using plane strain finite element models before and after total hip replacement. The model was adapted from a roentgenogram of a 4 mm slice normal to the acetabulum through the pubic and ilium. The model was divided into 24 regions of different elastic constants with isotropic material properties assumed in each region. The femoral head was modelled as a spherical surface that was mated with a congruent spherical acetabular socket. The implanted hip model was developed by modifying the natural hip model. Contact analyses were carried out between the articulating cartilage layers and between a cobalt chromium head and a cemented ultra-high molecular weight polyethylene (UHMWPE) cup under selected hip contact load cases during normal walking. Local polar coordinates were employed to facilitate the calculation of the interfacial stress components between the cup and cement, cement and subchondral bone as well as between the subchondral and underlying cancellous bones.

The results show that severe reductions in the local stresses in subchondral and cancellous bones were found in the reconstructed case. Both the peak stress and the range of the stress were reduced substantially, suggesting stress shielding in the acetabular region. Load transfer in the reconstructed case was found to occur primarily in the cement layer superior to the cup. Both the peak stress and the stress variation in the cement mantle are substantial, whilst abrupt changes in interfacial stresses occurred between the cement and cup, and cement and subchondral bone. The influence of subchondral bone retention and thickness of the cement (up to 6 mm) on the interfacial stress distribution appears to be insignificant.

The work represents the first stage of research towards developing a numerical tool for pre/post operative assessment of cement/cementless acetabular components.

Correspondence should be addressed to Dr Carlos Wigderowitz, Honorary Secretary of BORS, Division of Surgery & Oncology, Section of Orthopaedic & Trauma Surgery, Ninewells Hospital & Medical School Tort Centre, Dundee, DD1 9SY.