Fracture simulation of the femoral bone using the finite-element method: how a fracture initiates and proceeds

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Ota, Toyotsugu¹; Yamamoto, Itsuo¹; Morita, Rikushi¹

Fracture simulation of the femoral bone using the finite-element method: how a fracture initiates and proceeds

J Bone Min Metab. May 1999;17(2):108-112

©1999 Springer-Verlag

Affiliations

¹Department of Radiology, Shiga University of Medical Science, Seta Tsukinowa, Otsu 520-2192, Japan
Abstract and keywords

Structural analysis of bones is now actively studied by many researchers using the finite-element method (FEM) to better understand the mechanism of bone fractures. Most previous studies, however, only obtained distribution patterns of stress or strain, and did not show how a fracture initiates and proceeds or how a fracture line grows. The purpose of this study was to simulate a fracture procedure using FEM and to assess its usefulness. Correlation of the strain value of the simulation and of the experiment was satisfactory (r = .81). The simulated fracture process and the consequent fracture lines were quite compatible with the experimental fracture. Quantitatively, however, there was a difference of yield load between the simulation and the experiment, i.e., 2000 N and 8400 N, respectively, likely caused by inaccuracies of material properties of the elements of the finite-element model.

Keywords: finite-element method ;fracture; simulation; human femur
Links

DOI: 10.1007/s007740050072

PubMed: 10340637

WoS: 000080161300004
History

Received: 1998-05-11

Accepted: 1998-10-02

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