Finite element simulation of the fatigue behaviour of cortical and cancellous bone
Finite element simulation of the fatigue behaviour of cortical and cancellous bone
Fatigue failure of bone has been implicated in a number of clinical failure scenarios. At the material level, the fatigue behaviour of cancellous bone is poorly understood. At the continuum level, the fatigue behaviour of cortical and cancellous bone are similar, exhibiting material degradation during a fatigue test. Using a combined continuum damage mechanics and finite element approach, two key questions were addressed: (i) What purpose does material degradation serve in vivo? (ii) Can the fatigue behaviour of cancellous bone be predicted by applying cortical bone data at the trabecular tissue level? Material degradation significantly increases the life of a sample, by reducing the peak stresses and redistributing the load to the surrounding tissue. The application of cortical bone data to trabecular tissue appears to give reasonable estimates of the fatigue life of cancellous bone. Modulus degradation appears to be a result of trabecular fracture rather than as a result of tissue level material degradation. At present, the models only predict permanent strains of approximately 10% of the initial applied strains, as compared to the 100-200% reported in experimental studies.
Taylor, M.
e368bda3-6ca5-4178-80e9-41a689badeeb
Cotton, J.R.
c755dd79-bca6-46b5-85ea-0b14f5b844fa
Zioupos, P.
11b6158a-2969-43b4-b19b-a01b00ee65fa
2001
Taylor, M.
e368bda3-6ca5-4178-80e9-41a689badeeb
Cotton, J.R.
c755dd79-bca6-46b5-85ea-0b14f5b844fa
Zioupos, P.
11b6158a-2969-43b4-b19b-a01b00ee65fa
Taylor, M., Cotton, J.R. and Zioupos, P.
(2001)
Finite element simulation of the fatigue behaviour of cortical and cancellous bone.
15th AIMETA Congress of Theoretical and Applied Mechanics, Taormina, Sicily.
25 - 28 Sep 2001.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Fatigue failure of bone has been implicated in a number of clinical failure scenarios. At the material level, the fatigue behaviour of cancellous bone is poorly understood. At the continuum level, the fatigue behaviour of cortical and cancellous bone are similar, exhibiting material degradation during a fatigue test. Using a combined continuum damage mechanics and finite element approach, two key questions were addressed: (i) What purpose does material degradation serve in vivo? (ii) Can the fatigue behaviour of cancellous bone be predicted by applying cortical bone data at the trabecular tissue level? Material degradation significantly increases the life of a sample, by reducing the peak stresses and redistributing the load to the surrounding tissue. The application of cortical bone data to trabecular tissue appears to give reasonable estimates of the fatigue life of cancellous bone. Modulus degradation appears to be a result of trabecular fracture rather than as a result of tissue level material degradation. At present, the models only predict permanent strains of approximately 10% of the initial applied strains, as compared to the 100-200% reported in experimental studies.
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Published date: 2001
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Bio 12
Venue - Dates:
15th AIMETA Congress of Theoretical and Applied Mechanics, Taormina, Sicily, 2001-09-25 - 2001-09-28
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Local EPrints ID: 21801
URI: http://eprints.soton.ac.uk/id/eprint/21801
PURE UUID: ee2c0707-e1d2-4da0-b319-6012d95d0623
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Date deposited: 26 Feb 2007
Last modified: 11 Dec 2021 14:33
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Author:
M. Taylor
Author:
J.R. Cotton
Author:
P. Zioupos
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