Comparative two- and three-dimensional finite element modelling techniques for tibial fractures

Abstract Often the choice of a two-dimensional modelling approach over a three-dimensional approach is made on the basis of available resources, and not on task appropriateness. In the case of simulating the mechanical behaviour of irregular anatomical structures in biomedical engineering, the authe...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine Journal of engineering in medicine, 2001-01, Vol.215 (2), p.255-258
Main Authors: Mishra, S, Gardner, T N
Format: Article
Language:English
Subjects:
Biological and medical sciences
Biomechanical Phenomena
Biomedical engineering
Bone
Bony Callus
Computer simulation
Diseases of the osteoarticular system
Finite Element Analysis
Finite element method
Humans
Imaging, Three-Dimensional
Medical sciences
Miscellaneous. Osteoarticular involvement in other diseases
Models, Biological
Radiography
Reproducibility of Results
Strain
Stress, Mechanical
Stresses
Tibial Fractures - diagnostic imaging
Tibial Fractures - physiopathology
United Kingdom
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Summary:Abstract Often the choice of a two-dimensional modelling approach over a three-dimensional approach is made on the basis of available resources, and not on task appropriateness. In the case of simulating the mechanical behaviour of irregular anatomical structures in biomedical engineering, the authenticity of two-dimensional model behaviour and the interpretation of model solutions is of particular concern since little comparable two-dimensional and three-dimensional data have been published. As part of a research programme, a comparison was made between two-dimensional and three-dimensional finite element models (FEMs) that examine the stress-strain environment of a clinical bone fracture and callus. In comparison with the three-dimensional model, the two-dimensional model substantially underestimated peak compressive principal stresses in the callus tissue and peak equivalent strains. This was a consequence of geometrical and structural asymmetry in a plane perpendicular to the two-dimensional model. However, the two-dimensional model predicted similar patterns of stress and strain distribution to the corresponding mid-longitudinal plane of the three-dimensional model, and underestimates of peak stress and strain were much reduced. This confirmed that despite the irregular geometry and structure of the subject, the two-dimensional model provided a valid mechanical simulation in the plane of the fracture that it represented.
ISSN:0954-4119
2041-3033
DOI:10.1243/0954411011533652