Load transfer across the pelvic bone

wbldb

Dalstra, M.¹; Huisker, R.¹

Load transfer across the pelvic bone

J Biomech. June 1995;28(6):715-724

©1995 Elsevier Science Ltd.

Affiliations

¹Biomechanics Section, Institute of Orthopaedics, University of Nijmegen, Nijmegen, The Netherlands
Abstract

arlier experimental and finite element studies notwithstanding, the load transfer and stress distribution in the pelvic bone and the acetabulum in normal conditions are not well understood. This hampers the development of orthopaedic reconstruction methods. The present study deals with more precise finite element analyses of the pelvic bone, which are used to investigate its basic load transfer and stress distributions under physiological loading conditions. The analyses show that the major part of the load is transferred through the cortical shell. Although the magnitude of the hip joint force varies considerably, its direction during normal walking remains pointed into the anterior/superior quadrant of the acetabulum. Combined with the fact that the principal areas of support for the pelvic bone are the sacro-iliac joint and the pubic symphysis, this caused the primary areas of load transfer to be found in the superior acetabular rim, the incisura ischiadaca region and, to a lesser extent, the pubic bone. Due to the ‘sandwich’ behavior of the pelvic bone, stresses in the cortical shell are about 50 times higher than in the underlying trabecular bone (15 to 20 MPa vs 0.3–0.4 MPa at one-legged stance). Highest intraarticular pressures are found to occur during one-legged stance and measured about 9 MPa. During the swing phase, these pressures decrease less than linearly with the magnitude of the hip joint force. Muscle forces have a stabilizing effect on the pelvic load transfer. Analysis without muscle forces show that at some locations stresses are actually higher than when muscle forces are included.
Links

DOI: 10.1016/0021-9290(94)00125-N

PubMed: 7601870

WoS: A1995QU12100007
History

Revised: 1994-08-16

Cited Works (12)

Year	Entry
1993	Dalstra M, Huiskes R, Odgaard A, van Erning L. Mechanical and textural properties of pelvic trabecular bone. J Biomech. April–May 1993;26(4-5):523-535.
1982	Vasu R, Carter DR, Harris WH. Stress distributions in the acetabular region, I: before and after total joint replacement. J Biomech. 1982;15(3):155-164.
1981	Dostal WF, Andrews JG. A three-dimensional biomechanical model of hip musculature. J Biomech. 1981;14(11):803-812.
1982	Pedersen DR, Crowninshield RD, Brand RA, Johnston RC. An axisymmetric model of acetabular components in total hip arthroplasty. J Biomech. 1982;15(4):305-315.
1981	Crowninshield RD, Brand RA. A physiologically based criterion of muscle force prediction in locomotion. J Biomech. 1981;14(11):793-801.
1983	Brown TD, Shaw DT. In vitro contact stress distributions in the natural human hip. J Biomech. 1983;16(6):373-384.
1977	Carter DR, Hayes WC. The compressive behavior of bone as a two-phase porous structure. J Bone Joint Surg. 1977;59A(7):954-962.
1991	Linde F, Nørgaard P, Hvid I, Odgaard A, Søballe K. Mechanical properties of trabecular bone: dependency on strain rate. J Biomech. 1991;24(9):803-809.
1983	Oonishi H, Isha H, Hasegawa T. Mechanical analysis of the human pelvis and its application to the artificial hip joint: by means of the three dimensional finite element method. J Biomech. 1983;16(6):427-444.
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.
1981	Carter DR, Caler WE, Spengler DM, Frankel VH. Fatigue behavior of adult cortical bone: the influence of mean strain and strain range. Acta Orthop Scand. 1981;52(5):481-490.
1976	Jacob HAC, Huggler AH, Dietschi C, Schreiber A. Mechanical function of subchondral bone as experimentally determined on the acetabulum of the human pelvis. J Biomech. 1976;9(10):625-627.

Cited By (18)

Year	Entry
2004	Haug E, Choi H-Y, Robin S, Beaugonin M. Human models for crash and impact simulation. In: Ayache N, ed. Computational Models for the Human Body. Amsterdam, The Netherlands: Elsevier B.V; 2004:231-452. Ciarlet PG, ed. Handbook of Numerical Analysis; vol 12.
2005	Song E, Fontaine L, Trosseille X, Guillemot H. Pelvis bone fracture modeling in lateral impact. In: Proceedings of the 19th International Technical Conference on the Enhanced Safety of Vehicles (ESV). June 6-9, 2005; Washington, DC.
2004	Li Z, Kim J-E, Eberhardt AW. Nonlinear viscoelastic finite element modeling of a female pubic symphysis. In: Proceedings of the 32nd International Workshop on Human Subjects for Biomechanical Research. 2004.179-188.
1998	Besnault B, Lavaste F, Guillemot H, Robin S, Le Coz J-Y. A parametric finite element model of the human pelvis. In: Proceedings of the 42nd Stapp Car Crash Conference. November 2-4, 1998; Tempa, AZ. Warrendale, PA: Society of Automotive Engineers:33-46. SAE 983147.
2006	Song E, Trosseille X, Guillemot H. Side impact: influence of impact conditions and bone mechanical properties on pelvic response using a fracturable pelvis model. Stapp Car Crash J. 2006;50:75-95. SAE 2006-22-0004.
1997	Pedersen DR, Brand RA, Davy DT. Pelvic muscle and acetabular contact forces during gait. J Biomech. September 1997;30(9):959-965.
2007	Li Z, Kim J-E, Davidson JS, Etheridge BS, Alonso JE, Eberhardt AW. Biomechanical response of the pubic symphysis in lateral pelvic impacts: a finite element study. J Biomech. 2007;40(12):2758-2766.
2023	Xu Z, Chen N, Wang B, Yang J, Liu H, Zhang X, Li Y, Liu L, Wu Y. Creation of the biomechanical finite element model of female pelvic floor supporting structure based on thin-sectional high-resolution anatomical images. J Biomech. January 2023;146:111399.
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.
2020	Vieth R. Weaker bones and white skin as adaptions to improve anthropological "fitness" for northern environments [published correction appears in Osteoporos Int. April 2020;31(4):803-804]. Osteoporos Int. April 2020;31(4):617-624.
2022	Khakpour S. Multi-Component Finite Element Analysis of Low- Energy Acetabular Fracture: Computational Study of Pelvic Girdle Fracture Mechanism [PhD thesis]. University of Oulu; 2022.
2012	Tozzi G. In Vitro Studies of Bone-Cement Interface and Related Work on Cemented Acetabular Replacement [PhD thesis]. Portsmouth, England: University of Portsmouth; May 29, 2012.
2020	Salem M. Investigation of Pelvic Bone Fracture Mechanism and Simulated Treatment [PhD thesis]. Edmonton, AB: University of Alberta; 2020.
2007	Anderson AE. Computational Modeling of Hip Joint Mechanics [PhD thesis]. University of Utah; April 2007.
2013	Henak CR. Cartilage and Labrum Mechanics in the Normal and Pathomorphologic Human Hip [PhD thesis]. University of Utah; August 2013.
2018	Atkins PR. Characterization of Cam Femoroacetabular Impingement Using Subject-Specific Biomechanics and Population-Based Morphological Measurements [PhD thesis]. University of Utah; August 2018.
2021	Salo Z. Characterizing the Mechanical Behaviour of the Human Pelvis Through Finite Element Analysis [PhD thesis]. University of Toronto; 2021.
2018	Volinski BJ. A Numerical Study of the Infix Percutaneous Anterior Pelvic Fixation: Analysis and Recommendations [PhD thesis]. Detroit, MI: Wayne State University; 2018.