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Physiologically based boundary conditions in finite element modelling

Physiologically based boundary conditions in finite element modelling
Physiologically based boundary conditions in finite element modelling
Finite element analysis has been used extensively in the study of bone loading and implant performance, such as in the femur. The boundary conditions applied vary widely, generally producing excessive femoral deformation, and although it has been shown that the muscle forces influence femoral deflections and loading, little consideration has been given to the displacement constraints. It is hypothesised that careful application of physiologically-based constraints can produce physiological deformation, and therefore straining, of the femur. Joint contact forces and a complete set of muscle forces were calculated based on the geometry of the Standardized Femur using previously validated musculoskeletal models. Five boundary condition cases were applied to a finite element model of the Standardized Femur: A) diaphyseally-constrained with hip contact and abductor forces; B) case A plus vasti forces; C) case A with complete set of muscle forces; D) distally-constrained with all muscle forces; E) physiological constraints with all muscle forces. It was seen that only the physiological boundary conditions, case E, produced physiological deflections (<2.0mm) of the femoral head in both the coronal and sagittal planes, which resulted in minimal reaction forces at the constrained nodes. Strains in the mid-diaphysis varied by up to 600 micro-strain under walking loads and 1000 micro-strain under stair climbing loads. The mode of loading, as indicated by the strain profiles on the cortex also varied substantially under these boundary conditions, which has important consequences for studies that examine localised bone loading such as fracture or bone remodelling simulations.
physiological boundary conditions, constraints, finite element, femoral loading
0021-9290
2318-2323
Speirs, A.D.
f06f0857-33b6-416f-a52a-17ce6e8a72a2
Heller, M.O.
3da19d2a-f34d-4ff1-8a34-9b5a7e695829
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Taylor, W.R.
4f1cd2b0-4963-4b10-bbde-da586c069e77
Speirs, A.D.
f06f0857-33b6-416f-a52a-17ce6e8a72a2
Heller, M.O.
3da19d2a-f34d-4ff1-8a34-9b5a7e695829
Duda, G.N.
32d09622-34ad-49dd-8314-3f61c99a764e
Taylor, W.R.
4f1cd2b0-4963-4b10-bbde-da586c069e77

Speirs, A.D., Heller, M.O., Duda, G.N. and Taylor, W.R. (2007) Physiologically based boundary conditions in finite element modelling. Journal of Biomechanics, 40 (10), 2318-2323. (doi:10.1016/j.jbiomech.2006.10.038).

Record type: Article

Abstract

Finite element analysis has been used extensively in the study of bone loading and implant performance, such as in the femur. The boundary conditions applied vary widely, generally producing excessive femoral deformation, and although it has been shown that the muscle forces influence femoral deflections and loading, little consideration has been given to the displacement constraints. It is hypothesised that careful application of physiologically-based constraints can produce physiological deformation, and therefore straining, of the femur. Joint contact forces and a complete set of muscle forces were calculated based on the geometry of the Standardized Femur using previously validated musculoskeletal models. Five boundary condition cases were applied to a finite element model of the Standardized Femur: A) diaphyseally-constrained with hip contact and abductor forces; B) case A plus vasti forces; C) case A with complete set of muscle forces; D) distally-constrained with all muscle forces; E) physiological constraints with all muscle forces. It was seen that only the physiological boundary conditions, case E, produced physiological deflections (<2.0mm) of the femoral head in both the coronal and sagittal planes, which resulted in minimal reaction forces at the constrained nodes. Strains in the mid-diaphysis varied by up to 600 micro-strain under walking loads and 1000 micro-strain under stair climbing loads. The mode of loading, as indicated by the strain profiles on the cortex also varied substantially under these boundary conditions, which has important consequences for studies that examine localised bone loading such as fracture or bone remodelling simulations.

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More information

e-pub ahead of print date: 14 December 2006
Published date: 2007
Keywords: physiological boundary conditions, constraints, finite element, femoral loading
Organisations: Bioengineering Group

Identifiers

Local EPrints ID: 348516
URI: http://eprints.soton.ac.uk/id/eprint/348516
ISSN: 0021-9290
PURE UUID: 5ac314a4-a137-42bb-8fdd-0af44026aca6
ORCID for M.O. Heller: ORCID iD orcid.org/0000-0002-7879-1135

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Date deposited: 26 Feb 2013 12:54
Last modified: 15 Mar 2024 03:43

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Contributors

Author: A.D. Speirs
Author: M.O. Heller ORCID iD
Author: G.N. Duda
Author: W.R. Taylor

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