We present results on the growth of damage in 29 fatigue tests of human femoral cortical bone from four individuals, aged 53–79. In these tests we examine the interdependency of stress, cycles to failure, rate of creep strain, and rate of modulus loss. The behavior of creep rates has been reported recently for the same donors as an effect of stress and cycles (Cotton, J. R., Zioupos, P., Winwood, K., and Taylor, M., 2003, “Analysis of Creep Strain During Tensile Fatigue of Cortical Bone,” J. Biomech. 36, pp. 943–949). In the present paper we first examine how the evolution of damage (drop in modulus per cycle) is associated with the stress level or the “normalized stress” level (stress divided by specimen modulus), and results show the rate of modulus loss fits better as a function of normalized stress. However, we find here that even better correlations can be established between either the cycles to failure or creep rates versus rates of damage than any of these three measures versus normalized stress. The data indicate that damage rates can be excellent predictors of fatigue life and creep strain rates in tensile fatigue of human cortical bone for use in practical problems and computer simulations.
Skip Nav Destination
Article navigation
April 2005
Technical Papers
Damage Rate is a Predictor of Fatigue Life and Creep Strain Rate in Tensile Fatigue of Human Cortical Bone Samples
John R. Cotton,
John R. Cotton
Department of Engineering Science and Mechanics and Virginia Tech–Wake Forest School of Biomedical Engineering and Science
, Virginia Tech, Mail code 0219, Blacksburg, VA 24061
Search for other works by this author on:
Keith Winwood,
Keith Winwood
Institute for Biophysical and Clinical Research into Human Movement
, Manchester Metropolitian University, Alsager, UK
Search for other works by this author on:
Peter Zioupos,
Peter Zioupos
Center for Materials Science and Engineering
, Cranfield Postgraduate Medical School, Cranfield University, Shrivenham, UK
Search for other works by this author on:
Mark Taylor
Mark Taylor
Bioengineering Science Research Group
, School of Engineering Science, University of Southampton, Southampton, UK
Search for other works by this author on:
John R. Cotton
Department of Engineering Science and Mechanics and Virginia Tech–Wake Forest School of Biomedical Engineering and Science
, Virginia Tech, Mail code 0219, Blacksburg, VA 24061
Keith Winwood
Institute for Biophysical and Clinical Research into Human Movement
, Manchester Metropolitian University, Alsager, UK
Peter Zioupos
Center for Materials Science and Engineering
, Cranfield Postgraduate Medical School, Cranfield University, Shrivenham, UK
Mark Taylor
Bioengineering Science Research Group
, School of Engineering Science, University of Southampton, Southampton, UKJ Biomech Eng. Apr 2005, 127(2): 213-219 (7 pages)
Published Online: September 28, 2004
Article history
Received:
August 7, 2003
Revised:
September 28, 2004
Citation
Cotton, J. R., Winwood, K., Zioupos, P., and Taylor, M. (September 28, 2004). "Damage Rate is a Predictor of Fatigue Life and Creep Strain Rate in Tensile Fatigue of Human Cortical Bone Samples." ASME. J Biomech Eng. April 2005; 127(2): 213–219. https://doi.org/10.1115/1.1865188
Download citation file:
Get Email Alerts
Simulating the Growth of TATA-Box Binding Protein-Associated Factor 15 Inclusions in Neuron Soma
J Biomech Eng (December 2024)
Related Articles
Creep Does Not Contribute to Fatigue in Bovine Trabecular Bone
J Biomech Eng (June,2004)
Analysis of Crack Growth in a 3D Voronoi Structure: A Model for Fatigue in Low Density Trabecular Bone
J Biomech Eng (October,2002)
Characterization of the Fatigue Behavior of the Medial Collateral Ligament Utilizing Traditional and Novel Mechanical Variables for the Assessment of Damage Accumulation
J Biomech Eng (January,2010)
Cycle-Dependent and Time-Dependent Bone Fracture With Repeated Loading
J Biomech Eng (May,1983)
Related Proceedings Papers
Related Chapters
Introduction and Definitions
Handbook on Stiffness & Damping in Mechanical Design
Analysis of Components in VIII-2
Guidebook for the Design of ASME Section VIII Pressure Vessels, Third Edition
Understanding the Problem
Design and Application of the Worm Gear