The response of equine cortical bone to loading at strain rates experienced in vivo by the galloping horse

Evans, G. P.<sup>1</sup>; Behiri, J. C.<sup>2</sup>; Vaughan, L. C.<sup>3</sup>; Bonfield, W.<sup>2</sup>

Affiliations

¹Biomedical Research Department, AEA Technology, 8551, Hatwell Laboratory, Oxfordshire OX1 1 ORA, UK

²Department of Materials, Queen Mary and Westfield College, University of London, Mile End Road, London, E1 4NS, UK

³Department of Surgery and Obstetrics, Royal Veterinary College, University of London, Hawkshead Lane, North Mymms, Herts, UK

Abstract

The behaviour of cortical bone under load is strain rate‐dependent, i.e. it is dependent on the rate at which the load is applied. This is particularly relevant in the galloping horse since the strain rates experienced by the bone are far in excess of those recorded for any other species. In this study the effect of strain rates between 0.0001 and 1 sec⁻¹ on the mechanical properties of equine cortical bone were assessed. Initially, increasing strain rates resulted in increased mechanical properties. Beyond a critical value, however, further increases in strain rate resulted in lower strain to failure and energy absorbing capacity. This critical rate occurred around 0.1 sec⁻¹ which is within the in vivo range for a galloping racehorse. Analysis of the stress‐strain curves revealed a transition in the type of deformation at this point from pseudo‐ductile to brittle. Bones undergoing brittle deformation are more likely to fail under load, leading to catastrophic fracture and destruction of the animal.

Links

DOI: 10.1111/j.2042-3306.1992.tb02796.x

PubMed: 1582390

WoS: A1992HL12700012

History

Received: 1990-06-01

Accepted: 1991-10-22

Cited Works (14)

Year	Entry
1974	Crowninshield RD, Pope MH. The response of compact bone in tension at various strain rates. Ann Biomed Eng. 1974;2(2):217-225.
1984	Behiri JC, Bonfield W. Fracture mechanics of bone: the effects of density, specimen thickness and crack velocity on longitudinal fracture. J Biomech. 1984;17(1):25-34.
1970	Piekarski K. Fracture of bone. J Appl Phys. January 1970;41(1):215-223.
1966	Sedlin‌ ED, Hirsch C. Factors affecting the determination of the physical properties of femoral cortical bone. Acta Orthop Scand. 1966;37(1):29-48.
1975	Lanyon LE, Hampson WGJ, Goodship AE, Shah JS. Bone deformation recorded in vivo from strain gauges attached to the human tibial shaft. Acta Orthop Scand. 1975;46(2):256-268.
1976	Wright TM, Hayes WC. Tensile testing of bone over a wide range of strain rates: effects of strain rate, microstructure and density. Med Biol Eng. November 1976;14(6):671-680.
1973	Margel-Robertson DR. Studies of Fracture in Bone [PhD thesis]. Stanford University; March 1973.
1976	Carter DR, Hayes WC. Bone compressive strength: the influence of density and strain rate. Science. September 10, 1976;194(4270):1174-1176.
1971	Wood JL. Dynamic response of human cranial bone. J Biomech. January 1971;4(1):1-12.
1982	Rubin CT, Lanyon LE. Limb mechanics as a function of speed and gait: a study of functional strains in the radius and tibia of horse and dog. J Exp Biol. December 1982;101:187-211.
1978	Robertson DM, Smith DC. Compressive strength of mandibular bone as a function of microstructure and strain rate. J Biomech. 1978;11(10-12):455-471.
1988	Currey JD. The effects of drying and re-wetting on some mechanical properties of cortical bone. J Biomech. 1988;21(5):439-441.
1975	Currey JD. The effects of strain rate, reconstruction and mineral content on some mechanical properties of bovine bone. J Biomech. 1975;8(1):81-86.
1970	Currey JD. The mechanical properties of bone. Clin Orthop Relat Res. November–December 1970;73:210-231.

Cited By (16)

Year	Entry
2019	Zhai X, Guo Z, Gao J, Kedir N, Nie Y, Claus B, Sun T, Xiao X, Fezzaa K, Chen WW. High-speed X-ray visualization of dynamic crack initiation and propagation in bone. Acta Biomater. May 2019;90:278-286.
1993	Riggs CM, Vaughan LC, Evans GP, Lanyon LE, Boyde A. Mechanical implications of collagen fibre orientation in cortical bone of the equine radius. Anat Embryol. March 1993;187(3):239-248.
2014	Zimmermann EA, Gludovatz B, Schaible E, Busse B, Ritchie RO. Fracture resistance of human cortical bone across multiple length-scales at physiological strain rates. Biomaterials. July 2014;35(21):5472-5481.
2020	Zioupos P, Kirchner HOK, Peterlik H. Ageing bone fractures: the case of a ductile to brittle transition that shifts with age. Bone. February 2020;131:115176.
2000	Batson EL, Reilly GC, Currey JD, Balderson DS. Postexercise and positional variation in mechanical properties of the radius in young horses. Equine Vet J. March 2000;32(2):95-100.
2008	Zioupos P, Hansen U, Currey JD. Microcracking damage and the fracture process in relation to strain rate in human cortical bone tensile failure. J Biomech. October 20, 2008;41(14):2932-2939.
2008	Hansen U, Zioupos P, Simpson R, Currey JD, Hynd D. The effect of strain rate on the mechanical properties of human cortical bone. J Biomech Eng. February 2008;130(1):011011.
2011	Kulin RM, Jiang F, Vecchio KS. Effects of age and loading rate on equine cortical bone failure. J Mech Behav Biomed Mater. January 2011;4(1):57-75.
2011	Ural A, Zioupos P, Buchanan D, Vashishth D. The effect of strain rate on fracture toughness of human cortical bone: a finite element study. J Mech Behav Biomed Mater. October 2011;4(7):1021-1032.
2019	Zhai X, Gao J, Nie Y, Guo Z, Kedir N, Claus B, Sun T, Fezzaa K, Xiao X, Chen WW. Real-time visualization of dynamic fractures in porcine bones and the loading-rate effect on their fracture toughness. J Mech Phys Solids. October 2019;(131):358-371.
2020	Zhai X, Nie Y, Gao J, Kedir N, Claus B, Sun T, Fezzaa K, Chen WW. The effect of loading direction on the fracture behaviors of cortical bone at a dynamic loading rate. J Mech Phys Solids. September 2020;142:104015.
2002	Les CM, Stover SM, Keyak JH, Taylor KT, Kaneps AJ. Stiff and strong compressive properties are associated with brittle post‐yield behavior in equine compact bone material. J Orthop Res. May 2002;20(2):607-614.
1998	Kawcak CE. Effects of Loading on Subchondral Bone of the Equine Carpal and Metacarpophalangeal Joints [PhD thesis]. Colorado State University; 1998.
2014	Gilchrist SM. Comparison of Proximal Femur Deformations, Failures and Fractures in Quasi-Static and Inertially-Driven Simulations of a Sideways Fall from Standing: An Experimental Study Utilizing Novel Fall Simulation, Digital Image Correlation, and Development of Digital Volume Correlation Techniques [PhD thesis]. Vancouver, BC: University of British Columbia; January 2014.
1998	Vajda EG. Age-Related Changes in the Microstructure and Mineralization of the Female Proximal Femur [PhD thesis]. University of Utah; March 1998.
2022	Snow TJ. An Investigation of the Role of Collagen Network on the Dynamic Fracture Initiation Toughness of Bovine Cortical Bone [Master's thesis]. University of Utah; December 2022.