Compressive Fatigue Life and Micromorphology of Equine Metacarpal Subchondral Bone

Bone fatigue injuries are an important cause of lameness in racehorses and as such are an animal welfare issue and a cause of losses to the industry. The metacarpal condyles are commonly affected by stress fractures and palmar osteochondral disease, a fatigue injury of subchondral bone. Bone fatigue injuries should be preventable through training adjustments. Knowledge about the behaviour of equine bone, and particularly subchondral bone, under cyclic loading is important to inform training recommendations. Computational models have been developed to investigate the effects of training changes on stress fracture development but require equine subchondral bone material properties as an input to meaningfully model metacarpal condylar fatigue injuries.

A method for compressive fatigue testing of subchondral bone was developed and the fatigue life of equine subchondral bone determined. The fatigue life curve followed a power law, similar to cortical and cancellous bone. Subchondral bone stiffness increased during fatigue testing over hundreds to thousands of cycles, which was initially attributed to a method artefact. Initial specimen stiffness was positively associated with actual density but not with horse and training related factors.

Micro-CT was used to investigate the micromorphology of the palmar metacarpal subchondral bone. Micromorphology parameters were analysed with principal component analysis and mixed-effects linear regression models. The largest differences in micromorphology were observed in untrained horses between the age of 16 and 20 months. In racehorses in training, age and duration of a training period had no influence on micromorphology. Horses with palmar osteochondral disease had more pores in crosssection than those without. Tissue mineral density increased, and bone volume fraction decreased with increasing distance from the articular surface.

Several alterations to the fatigue testing method were explored to accommodate the curved articular surface and eliminate the stiffness increase during compressioncompression cyclic loading. The stiffness increase during the first 50 cycles was demonstrated to be reversible and no microdamage or trabecular compaction was detected in specimens loaded up to 200 cycles. Stiffness increase during compression-compression fatigue testing at a physiological frequency is thus likely the result of normal viscous material properties of subchondral bone.

Finally, compressive fatigue life was positively associated with bone volume fraction in the deeper layers of subchondral bone. Initial stiffness was positively associated with tissue mineral density in the deeper layers and bone volume fraction in the superficial layer. Both maximum stiffness and cycles to maximum stiffness were positively associated with fatigue life. Cycles to 10% reduction of maximal stiffness correlated strongly with cycles to gross fracture.

The results showed that subchondral bone’s viscous material properties led to a prolonged stiffness increase during cyclic compressive loading at physiological frequencies. Further research is required to investigate the physiological implications of this finding. Subchondral bone sclerosis measured as bone volume fraction is positively associated with compressive fatigue life and thus has a protective effect on subchondral bone. Further research is required to reconcile this finding with the common colocation of fatigue damage in sclerotic subchondral bone of racehorses.

Year	Entry
1989	Schaffler MB, Radin EL, Burr DB. Mechanical and morphological effects of strain rate on fatigue of compact bone. Bone. 1989;10(3):207-214.
1988	Schaffler MB, Burr DB. Stiffness of compact bone: effects of porosity and density. J Biomech. 1988;21(1):13-16.
1998	Taylor D. Fatigue of bone and bones: an analysis based on stressed volume. J Orthop Res. March 1998;16(2):163-169.
1995	Kannus P, Haapasalo H, Sankelo M, Sievanen H, Pasanen M, Heinonen A, Oja P, Vuori I. Effect of starting age of physical activity on bone mass in the dominant arm of tennis and squash players. Ann Intern Med. July 1995;123(1):27-31.
2001	Turner CH, Hsieh Y, Müller R, Bouxsein ML, Rosen CJ, McCrann ME, Donahue LR, Beamer WG. Variation in bone biomechanical properties, microstructure, and density in BXH recombinant inbred mice. J Bone Miner Res. February 2001;16(2):206-213.
1997	Keaveny TM, Pinilla TP, Crawford RP, Kopperdahl DL, Lou A. Systematic and random errors in compression testing of trabecular bone [published correction appears in J Orthop Res. 1995;17(1):151]. J Orthop Res. 1997;15(1):101-110.
1977	Carter DR, Hayes WC. Compact bone fatigue damage: a microscopic examination. Clin Orthop Relat Res. September 1977;127:265-274.
1981	Carter DR, Caler WE, Spengler DM, Frankel VH. Uniaxial fatigue of human cortical bone: the influence of tissue physical characteristics. J Biomech. 1981;14(7):461-470.
2006	Hernandez CJ, Gupta A, Keaveny TM. A biomechanical analysis of the effects of resorption cavities on cancellous bone strength. J Bone Miner Res. August 2006;21(8):1248-1255.
1996	Gustafson MB, Martin RB, Gibson V, Storms DH, Stover SM, Gibeling J, Griffin L. Calcium buffering is required to maintain bone stiffness in saline solution. J Biomech. September 1996;29(9):1191-1194.
1996	Zioupos P, Wang XT, Currey JD. Experimental and theoretical quantification of the development of damage in fatigue tests of bone and antler. J Biomech. August 1996;29(8):989-1002.
1995	Gibson VA, Stover SM, Martin RB, Gibeling JC, Willits NH, Gustafson MB, Griffin LV. Fatigue behavior of the equine third metacarpus: mechanical property analysis. J Orthop Res. November 1995;13(6):861-868.
2010	Bouxsein ML, Boyd SK, Christiansen BA, Guldberg RE, Jepsen KJ, Müller R. Guidelines for assessment of bone microstructure in rodents using micro-computed tomography. J Bone Miner Res. July 2010;25(7):1468-1486.
2003	Boyde A. The real response of bone to exercise. J Anat. August 2003;203(2):173-189.
1990	Schaffler MB, Radin EL, Burr DB. Long-term fatigue behavior of compact bone at low strain magnitude and rate. Bone. 1990;11(5):321-326.
1976	Carter DR, Hayes WC. Fatigue life of compact bone, I: effects of stress amplitude, temperature and density. J Biomech. 1976;9(1):27-34.
1988	Harrigan TP, Jasty M, Mann RW, Harris WH. Limitations of the continuum assumption in cancellous bone. J Biomech. 1988;21(4):269-275.
2002	Arthur Moore TL, Gibson LJ. Microdamage accumulation in bovine trabecular bone in uniaxial compression. J Biomech Eng. February 2002;124(1):63-71.
1999	Reilly GC, Currey JD. The development of microcracking and failure in bone depends on the loading mode to which it is adapted. J Exp Biol. 1999;202(5):543-552.
1998	Bentolila V, Boyce TM, Fyhrie DP, Drumb R, Skerry TM, Schaffler MB. Intracortical remodeling in adult rat long bones after fatigue loading. Bone. September 1998;23(3):275-281.
1991	Odgaard A, Linde F. The underestimation of Young's modulus in compressive testing of cancellous bone specimens. J Biomech. 1991;24(8):691-698.
2005	Warden SJ, Hurst JA, Sanders MS, Turner CH, Burr DB, Li J. Bone adaptation to a mechanical loading program significantly increases skeletal fatigue resistance. J Bone Miner Res. May 2005;20(5):809-816.
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.
2010	Harrison SM, Whitton RC, Kawcak CE, Stover SM, Pandy MG. Relationship between muscle forces, joint loading and utilization of elastic strain energy in equine locomotion. J Exp Biol. December 1, 2010;213(23):3998-4009.
2010	Harrison NM, McHugh PE. Comparison of trabecular bone behavior in core and whole bone samples using high-resolution modeling of a vertebral body. Biomech Model Mechanobiol. 2010;9(4):469-480.
2008	Dendorfer S, Maier HJ, Taylor D, Hammer J. Anisotropy of the fatigue behaviour of cancellous bone. J Biomech. 2008;41(3):636-641.
2002	Wachter NJ, Krischak GD, Mentzel M, Sarkar MR, Ebinger T, Kinz L, Claes L, Augat P. Correlation of bone mineral density with strength and microstructural parameters of cortical bone in vitro. Bone. July 2002;31(1):90-95.
1995	Martin B. Mathematical model for repair of fatigue damage and stress fracture in osteonal bone. J Orthop Res. May 1995;13(3):309-316.
1977	Carter DR, Hayes WC. Compact bone fatigue damage, I: residual strength and stiffness. J Biomech. 1977;10(5-6):325-337.
1993	Mori S, Burr DB. Increased intracortical remodeling following fatigue damage. Bone. March–April 1993;14(2):103-109.
2006	Nyman JS, Roy A, Shen X, Acuna RL, Tyler JH, Wang X. The influence of water removal on the strength and toughness of cortical bone. J Biomech. 2006;39(5):931-938.
1998	Müller R, Van Campenhout H, Van Damme B, Van der Perre G, Dequeker J, Hildebrand T, Rüegsegger P. Morphometric analysis of human bone biopsies: a quantitative structural comparison of histological sections and micro-computed tomography. Bone. July 1998;23(1):59-66.
1998	Kopperdahl DL, Keaveny TM. Yield strain behavior of trabecular bone. J Biomech. July 1998;31(7):601-608.
2006	Ün K, Bevill G, Keaveny TM. The effects of side-artifacts on the elastic modulus of trabecular bone. J Biomech. 2006;39(11):1955-1963.
1987	Linde F, Hvid I. Stiffness behaviour of trabecular bone specimens. J Biomech. 1987;20(1):83-89.
2006	Wang X, Niebur GL. Microdamage propagation in trabecular bone due to changes in loading mode. J Biomech. 2006;39(5):781-790.
1985	Linde F, Hvid I, Jensen NC. Material properties of cancellous bone in repetitive axial loading. Eng Med. October 1985;14(4):173-177.
1989	Linde F, Hvid I. The effect of constraint on the mechanical behaviour of trabecular bone specimens. J Biomech. 1989;22(5):485-490.
1988	Rice JC, Cowin SC, Bowman JA. On the dependence of the elasticity and strength of cancellous bone on apparent density. J Biomech. 1988;21(2):155-168.
1983	Goldstein SA, Wilson DL, Sonstegard DA, Matthews LS. The mechanical properties of human tibial trabecular bone as a function of metaphyseal location. J Biomech. 1983;16(12):965-969.
2006	McNamara LM, Van der Linden JC, Weinans H, Prendergast PJ. Stress-concentrating effect of resorption lacunae in trabecular bone. J Biomech. 2006;39(4):734-741.
1999	Taylor D, O'Brien F, Prina-Mello A, Ryan C, O'Reilly P, Lee TC. Compression data on bovine bone confirms that a “stressed volume” principle explains the variability of fatigue strength results. J Biomech. November 1999;32(11):1199-1203.
1970	Galante J, Rostoker W, Ray RD. Physical properties of trabecular bone. Calcif Tiss Res. 1970;5(1):236-246.
2008	Helgason B, Perilli E, Schileo E, Taddei F, Brynjólfsson S, Viceconti M. Mathematical relationships between bone density and mechanical properties: a literature review. Clin Biomech (Bristol, Avon). 2008;23(2):135-146.
1990	Nunamaker DM, Butterweck DM, Provost MT. Fatigue fractures in thoroughbred racehorses: relationships with age, peak bone strain, and training. J Orthop Res. July 1990;8(4):604-611.
1995	McCubbrey DA, Cody DD, Peterson EL, Kuhn JL, Flynn MJ, Goldstein SA. Static and fatigue failure properties of thoracic and lumbar vertebral bodies and their relation to regional density. J Biomech. August 1995;28(8):891-899.
2002	Hsieh Y-F, Silva MJ. In vivo fatigue loading of the rat ulna induces both bone formation and resorption and leads to time-related changes in bone mechanical properties and density. J Orthop Res. July 2002;20(4):764-771.
1997	McCalden RW, McGeough JA, Court-Brown CM. Age-related changes in the compressive strength of cancellous bone: the relative importance of changes in density and trabecular architecture. J Bone Joint Surg. March 1997;79A(3):421-427.
2003	Moore TLA, Gibson LJ. Fatigue of bovine trabecular bone. J Biomech Eng. December 2003;125(6):761-768.
1992	Linde F, Hvid I, Madsen F. The effect of specimen geometry on the mechanical behaviour of trabecular bone specimens. J Biomech. 1992;25(4):359-368.
1993	Linde F, Sørensen HCF. The effect of different storage methods on the mechanical properties of trabecular bone. J Biomech. 1993;26(10):1249-1252.
1997	Martin RB, Gibson VA, Stover SM, Gibeling JC, Griffin LV. Residual strength of equine bone is not reduced by intense fatigue loading: implications for stress fracture. J Biomech. February 1997;30(2):109-114.
1995	Borchers RE, Gibson LJ, Burchardt H, Hayes WC. Effects of selected thermal variables on the mechanical properties of trabecular bone. Biomaterials. May 1995;16(7):545-551.
2011	Lynch ME, Main RP, Xu Q, Schmicker TL, Schaffler MB, Wright TM, van der Meulen MCH. Tibial compression is anabolic in the adult mouse skeleton despite reduced responsiveness with aging. Bone. September 2011;49(3):439-446.
2006	Gibson VA, Stover SM, Gibeling JC, Hazelwood SJ, Martin RB. Osteonal effects on elastic modulus and fatigue life in equine bone. J Biomech. 2006;39(2):217-225.
2006	Rapillard L, Charlebois M, Zysset PK. Compressive fatigue behavior of human vertebral trabecular bone. J Biomech. 2006;39(11):2133-2139.
2008	Nazarian A, Snyder BD, Zurakowski D, Müller R. Quantitative micro-computed tomography: a non-invasive method to assess equivalent bone mineral density. Bone. August 2008;43(2):302-311.
1996	Bennell KL, Malcolm SA, Thomas SA, Wark JD, Brukner PD. The incidence and distribution of stress fractures in competitive track and field athletes: a twelve-month prospective study. Am J Sports Med. March–April 1996;24(2):211-217.
1976	Carter DR, Hayes WC. Bone compressive strength: the influence of density and strain rate. Science. September 10, 1976;194(4270):1174-1176.
1977	Carter DR, Hayes WC. The compressive behavior of bone as a two-phase porous structure. J Bone Joint Surg. 1977;59A(7):954-962.
1993	Michel MC, Guo X-DE, Gibson LJ, McMahon TA, Hayes WC. Compressive fatigue behavior of bovine trabecular bone. J Biomech. April–May 1993;26(4-5):453-463.
2006	Teo JCM, Si-Hoe KM, Keh JEL, Teoh SH. Relationship between CT intensity, micro-architecture and mechanical properties of porcine vertebral cancellous bone. Clin Biomech (Bristol, Avon). March 2006;21(3):235-244.
1984	Radin EL, Martin RB, Burr DB, Caterson B, Boyd RD, Goodwin C. Effects of mechanical loading on the tissues of the rabbit knee. J Orthop Res. 1984;2(3):221-234.
1990	Choi K, Kuhn JL, Ciarelli MJ, Goldstein SA. The elastic moduli of human subchondral, trabecular, and cortical bone tissue and the size-dependency of cortical bone modulus. J Biomech. 1990;23(11):1103-1113.
1992	Choi K, Goldstein SA. A comparison of the fatigue behavior of human trabecular and cortical bone tissue. J Biomech. 1992;25(12):1371-1381.
2002	Ding M, Odgaard A, Danielsen CC, Hvid I. Mutual associations among microstructural, physical and mechanical properties of human cancellous bone. J Bone Joint Surg. August 2002;84B(6):900-907.
1998	Bowman SM, Guo XE, Cheng DW, Keaveny TM, Gibson LJ, Hayes WC, McMahon TA. Creep contributes to the fatigue behavior of bovine trabecular bone. J Biomech Eng. October 1998;120(5):647-654.
1993	Turner CH, Burr DB. Basic biomechanical measurements of bone: a tutorial. Bone. 1993;14(4):595-608.
1974	Gray RJ, Korbacher GK. Compressive fatigue behaviour of bovine compact bone. J Biomech. May 1974;7(3):287-292.
1997	Burr DB, Forwood MR, Fyhrie DP, Martin RB, Schaffler MB, Turner CH. Bone microdamage and skeletal fragility in osteoporotic and stress fractures. J Bone Miner Res. January 1997;12(1):6-15.
1995	Burr DB, Hooser M. Alterations to the en bloc basic fuchsin staining protocol for the demonstration of microdamage produced in vivo. Bone. October 1995;17(4):431-433.
1990	Burr DB, Stafford T. Validity of the bulk-staining technique to separate artifactual from in vivo bone microdamage. Clin Orthop Relat Res. November 1990;260:305-308.
2000	Lee TC, O'Brien FJ, Taylor D. The nature of fatigue damage in bone. Int J Fract. November 2000;22(10):847-853.
1998	Burr DB, Turner CH, Naick P, Forwood MR, Ambrosius W, Hasan MS, Pidaparti R. Does microdamage accumulation affect the mechanical properties of bone? J Biomech. April 1998;31(4):337-345.
1993	Keaveny TM, Borchers RE, Gibson L, Hayes WC. Trabecular bone modulus and strength can depend on specimen geometry. J Biomech. August 1993;26(8):991-995.
1998	Zioupos P, Casinos A. Cumulative damage and the response of human bone in two-step loading fatigue. J Biomech. September 1998;31(9):825-833.
2012	Goff MG, Slyfield CR, Kummari SR, Tkachenko EV, Fischer SE, Yi YH, Jekir MG, Keaveny TM, Hernandez CJ. Three-dimensional characterization of resorption cavity size and location in human vertebral trabecular bone. Bone. July 2012;51(1):28-37.
2014	Harrison SM, Chris Whitton R, Kawcak CE, Stover SM, Pandy MG. Evaluation of a subject-specific finite-element model of the equine metacarpophalangeal joint under physiological load. J Biomech. January 3, 2014;47(1):65-73.
2015	Goff MG, Lambers FM, Nguyen TM, Sung J, Rimnac CM, Hernandez CJ. Fatigue-induced microdamage in cancellous bone occurs distant from resorption cavities and trabecular surfaces. Bone. October 2015;79:8-14.
1996	Rüegsegger P, Koller B, Müller R. A microtomographic system for the nondestructive evaluation of bone architecture. Calcif Tiss Int. 1996;58(1):24-29.
1984	Parfitt AM. The cellular basis of bone remodeling: the quantum concept reexamined in light of recent advances in the cell biology of bone. Calcif Tiss Int. March 1984;36(suppl 1):S37-S45.
1989	Burr DB, Schaffler MB, Yang KH, Lukoschek M, Sivaneri N, Blaha JD, Radin EL. Skeletal change in response to altered strain environments: is woven bone a response to elevated strain? Bone. 1989;10(3):223-233.
1988	Burr DB, Schaffler MB, Frederickson RG. Composition of the cement line and its possible mechanical role as a local interface in human compact bone. J Biomech. 1988;21(11):939-945.
1993	Broz JJ, Simske SJ, Greenberg AR, Luttges MW. Effects of rehydration state on the flexural properties of whole mouse long bones. J Biomech Eng. November 1993;115(4A):447-449.
1985	Burr DB, Martin RB, Schaffler MB, Radin EL. Bone remodeling in response to in vivo fatigue microdamage. J Biomech. 1985;18(3):189-200.
2013	Kanis JA, McCloskey EV, Johansson H, Cooper C, Rizzoli R, Reginster J-Y; Scientific Advisory Board of the European Society for Clinical and Economic Aspects of Osteoporosis and Osteoarthritis (ESCEO); Committee of Scientific Advisors of the International Osteoporosis Foundation (IOF). European guidance for the diagnosis and management of osteoporosis in postmenopausal women. Osteoporos Int. January 2013;24(1):23-57.
1989	Frost HM. Transient-steady state phenomena in microdamage physiology: a proposed algorithm for lamellar bone. Calcif Tiss Int. June 1989;44(6):367-381.
1990	Sharp DJ, Tanner KE, Bonfield W. Measurement of the density of trabecular bone. J Biomech. 1990;23(8):853-857.
1985	Frost HM. The pathomechanics of osteoporoses. Clin Orthop Relat Res. November 1985;200:198-225.
1998	Boyce TM, Fyhrie DP, Glotkowski MC, Radin EL, Schaffler MB. Damage type and strain mode associations in human compact bone bending fatigue. J Orthop Res. May 1998;16(3):322-329.
2004	Follet H, Boivin G, Rumelhart C, Meunier PJ. The degree of mineralization is a determinant of bone strength: a study on human calcanei. Bone. May 2004;34(5):783-789.
1966	McElhaney JH. Dynamic response of bone and muscle tissue. J Appl Physiol. 1966;21(4):1231-1236.
1989	Caler WE, Carter DR. Bone creep-fatigue damage accumulation. J Biomech. 1989;22(6-7):625-635.
1993	McCalden RW, McGeough JA, Barker MB, Court-Brown CM. Age-related changes in the tensile properties of cortical bone: the relative importance of changes in porosity, mineralization, and microstructure. J Bone Joint Surg. 1993;75A(8):1193-1205.
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.
1985	Milgrom C, Giladi M, Stein M, Kashtan H, Margulies JY, Chisin R, Steinberg R, Aharonson Z. Stress fractures in military recruits: a prospective study showing an unusually high incidence. J Bone Joint Surg. November 1985;67B(5):732-735.
2007	Bevill G, Easley SK, Keaveny TM. Side-artifact errors in yield strength and elastic modulus for human trabecular bone and their dependence on bone volume fraction and anatomic site. J Biomech. 2007;40(15):3381-3388.
2004	Haddock SM, Yeh OC, Mummaneni PV, Rosenberg WS, Keaveny TM. Similarity in the fatigue behavior of trabecular bone across site and species. J Biomech. February 2004;37(2):181-187.
1973	Radin EL, Parker HG, Pugh JW, Steinberg RS, Paul IL, Rose RM. Response of joints to impact loading, III: relationship between trabecular microfractures and cartilage degeneration. J Biomech. January 1973;6(1):51-57.
1988	Currey JD. The effects of drying and re-wetting on some mechanical properties of cortical bone. J Biomech. 1988;21(5):439-441.
1988	Currey JD. Strain rate and mineral content in fracture models of bone. J Orthop Res. January 1988;6(1):32-38.

Year

Entry

1989

Schaffler MB, Radin EL, Burr DB. Mechanical and morphological effects of strain rate on fatigue of compact bone. Bone. 1989;10(3):207-214.

1988

Schaffler MB, Burr DB. Stiffness of compact bone: effects of porosity and density. J Biomech. 1988;21(1):13-16.

1998

Taylor D. Fatigue of bone and bones: an analysis based on stressed volume. J Orthop Res. March 1998;16(2):163-169.

1995

Kannus P, Haapasalo H, Sankelo M, Sievanen H, Pasanen M, Heinonen A, Oja P, Vuori I. Effect of starting age of physical activity on bone mass in the dominant arm of tennis and squash players. Ann Intern Med. July 1995;123(1):27-31.

2001

Turner CH, Hsieh Y, Müller R, Bouxsein ML, Rosen CJ, McCrann ME, Donahue LR, Beamer WG. Variation in bone biomechanical properties, microstructure, and density in BXH recombinant inbred mice. J Bone Miner Res. February 2001;16(2):206-213.