Compression data on bovine bone confirms that a “stressed volume” principle explains the variability of fatigue strength results

Taylor, David; O'Brien, Fergal; Prina-Mello, Adriele; Ryan, Colm; O'Reilly, Peter; Lee, T. Clive

Affiliations

¹Mechanical Engineering Department, Bioengineering Research Group, Trinity College, Dublin 2, Ireland

²Department of Anatomy, Royal College of Surgeons in Ireland, Dublin, Ireland

Abstract and keywords

The literature contains many measurements of the fatigue properties of compact bone, but these experimental results have been difficult to interpret and use due to a large amount of apparent scatter: variation in the number of cycles to failure for a given cyclic stress or strain range. Recently Taylor (1998a, Journal of Orthopaedic Research, 16, 163–169) showed that much of this scatter could be explained using a statistical model which took into account specimen size, or more specifically stressed volume. The present paper describes an attempt to test this model by using it to predict some new data, for bovine bone tested in compressive loading at room temperature at physiological loading rates. Twenty specimens were tested at the same applied load range (100 MPa). The theory was able to predict the mean behaviour of the specimens very well, with an accuracy (expressed in terms of stress) of 2%. It was also able to predict the degree of scatter (i.e. the variation of N_f), which was shown to be similar to that measured by other workers.

Keywords: Fatigue; Compact bone; Bovine bone; Compression; Weibull analysis

Links

DOI: 10.1016/S0021-9290(99)00112-8

PubMed: 10541070

WoS: 000083125800009

History

Received: 1998-11-25

Accepted: 1999-05-31

Online: 1999-10-5

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Cited By (22)

Year	Entry
2002	Currey JD. Bones: Structure and Mechanics. Princeton, NJ: Princeton University Press; 2002.
2008	Kennedy OD, Brennan O, Mauer P, Rackard SM, O'Brien FJ, Taylor D, Lee TC. The effects of increased intracortical remodeling on microcrack behaviour in compact bone. Bone. November 2008;43(5):889-893.
2021	Loundagin LL, Pohl AJ, Edwards WB. Stressed volume estimated by finite element analysis predicts the fatigue life of human cortical bone: the role of vascular canals as stress concentrators. Bone. February 2021;143:115647.
2020	Loundagin LL, Haider IT, Cooper DML, Edwards WB. Association between intracortical microarchitecture and the compressive fatigue life of human bone: a pilot study. Bone Rep. June 2020;12:100254.
2003	Martin RB. Fatigue microdamage as an essential element of bone mechanics and biology. Calcif Tiss Int. August 2003;73(2):101-107.
2009	Currey J. Measurement of the mechanical properties of bone: a recent history. Clin Orthop Relat Res. August 2009;467(8):1948-1954.
2003	O’Brien FJ, Taylor D, Lee TC. Microcrack accumulation at different intervals during fatigue testing of compact bone. J Biomech. July 2003;36(7):973-980.
2021	Haider IT, Lee M, Page R, Smith D, Edwards WB. Mechanical fatigue of whole rabbit-tibiae under combined compression-torsional loading is better explained by strained volume than peak strain magnitude. J Biomech. June 9, 2021;122:110434.
2004	Moore TLA, O’Brien FJ, Gibson LJ. Creep does not contribute to fatigue in bovine trabecular bone. J Biomech Eng. June 2004;126(3):321-329.
2020	Loundagin LL, Edwards WB. Stressed volume around vascular canals explains compressive fatigue life variation of secondary osteonal bone but not plexiform bone. J Mech Behav Biomed Mater. November 2020;110:104002.
2005	O'Brien FJ, Taylor D, Lee TC. The effect of bone microstructure on the initiation and growth of microcracks. J Orthop Res. March 2005;23(2):475-480.
2001	Zioupos P, Currey JD, Casinos A. Tensile fatigue in bone: are cycles-, or time to failure, or both, important? J Theo Biol. June 7, 2001;210(3):389-399.
2004	Currey J. Incompatible mechanical properties in compact bone. J Theo Biol. December 21, 2004;231(4):569-580.
2015	Gargac J. Evaluation of Bone Healing, Damage, and Adaptation Using Computational Modeling and Image Processing Techniques [PhD thesis]. University of Notre Dame; July 2015.
2000	O’Brien FJ. Microcracks and the Fatigue Behaviour of Compact Bone [PhD thesis]. Trinity College Dublin; October 2000.
2008	Kennedy OD. The Effect of Bone Turnover on Bone Quality and Material Properties [PhD thesis]. Trinity College Dublin; 2008.
2017	Fung A. Experimental Validation of Finite Element Predicted Bone Strain in the Human Metatarsal [Master's thesis]. Calgary, AB: University of Calgary; April 2017.
2020	Loundagin LL. The Influence of Intracortical Microarchitecture on the Mechanical Fatigue of Bone [PhD thesis]. Calgary, AB: University of Calgary; July 2020.
2023	Bruce OL. Tibial-Fibular Morphology: Variation, Sexual Dimorphism, and Mechanical Implications [PhD thesis]. Calgary, AB: University of Calgary; May 2023.
2023	Koshyk A. Influence of Microarchitecture on the Mechanical Fatigue Behaviour of Equine Subchondral Bone [Master's thesis]. Calgary, AB: University of Calgary; September 2023.
2007	Bigley RF. Volume Effects on Strength and Fatigue Life of Equine Cortical Bone [PhD thesis]. Davis, University of California; September 2007.
2019	Martig S. Compressive Fatigue Life and Micromorphology of Equine Metacarpal Subchondral Bone [PhD thesis]. University of Melbourne; June 2019.