Compressive mechanical properties of dry antler cortical bone cylinders from different cervidae species

[en] Antlers are bony structures composed predominantly of primary osteons with unique mechanical properties due to their specific use by deer as weapon and shield. Antler bone fracture resistance has attracted prior scrutiny through experimental tests and theoretical models. To characterize antler mechanical properties, compression of cubes, or bending or tensioning of rectangular bars have been performed in the literature with variations in the protocols precluding comparisons of the data. Compression testing is a widely used experimental technique for determining the mechanical properties of specimens excised from cortical or cancellous regions of bone. However, the recommended geometry for compression tests is the cylinder, being more representative of the real performances of the material. The purpose of research was to report data for compressive strength and stiffness of antler cortical bone following current guidelines. Cylinders (n = 296) of dry antler cortical bone from either the main beam or the tines of Cervus elaphus, Rangifer tarandus, Cervus nippon and Damadama were tested. This study highlights the fact that compression of antler cortical bone cylinders following current guidelines is feasible but not applicable in all species. Standardization of the testing protocols could help to compare data from the literature. This study also confirms that sample localization has no effect on the mechanical properties, that sample density has a significant impact and allows enriching the knowledge of the mechanical properties of dry antler cortical bone.

Disciplines :

Veterinary medicine & animal health

Author, co-author :

Picavet, Pierre ; Université de Liège - ULiège > Département d'Enseignement et de Clinique des animaux de Compagnie (DCC) > Chirurgie des animaux de compagnie

Claeys, Stéphanie ; Université de Liège - ULiège > Département d'Enseignement et de Clinique des animaux de Compagnie (DCC) > Chirurgie des animaux de compagnie

Rondia, Etienne ; Université de Liège - ULiège > Département d'Enseignement et de Clinique des animaux de Compagnie (DCC) > Chirurgie des animaux de compagnie ; Université de Liège - ULiège > Département de mécanique des matériaux et structures

Balligand, Marc ; Université de Liège - ULiège > Département d'Enseignement et de Clinique des animaux de Compagnie (DCC) > Chirurgie des animaux de compagnie

Language :

English

Title :

Compressive mechanical properties of dry antler cortical bone cylinders from different cervidae species

Publication date :

04 February 2024

Journal title :

Journal of the Mechanical Behavior of Biomedical Materials

ISSN :

1751-6161

eISSN :

1878-0180

Publisher :

Elsevier, Oxford, Gb

Volume :

152

Pages :

106442

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 09 February 2024

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Bibliography

An, Y.H., Draughn, R.A., Mechanical properties and testing methods of bone. An, Y.H., Friedman, R.J., (eds.) Animal Models in Orthopaedic Research, 1999, CRC Press, 139–163.
Attia, T., Willett, T.L., Tension and compression testing of cortical bone. Zdero, R., (eds.) Experimental Methods in Orthopaedic Biomechanics, 2017, Academic Press, 167–183.
Bayraktar, H.H., Morgan, E.F., Niebur, G.L., Grayson, E.M., Wong, E.K., Keaveny, T.M., Comparison of the elastic and yield properties of human femoral trabecular and cortical bone tissue. J. Biomech. 37 (2004), 27–35.
Blob, R.W., LaBarbera, M., Correlates of variation in deer antler stiffness: age, mineral content, intra-antler location, habitat, and phylogeny. Biol. J. Linn. Soc. 74 (2001), 113–120.
Blob, R.W., Snelgrove, J.M., Antler stiffness in moose (Alces alces): correlated evolution of bone function and material properties?. J. Morphol. 267 (2006), 1075–1086.
Cappelli, J., Atzori, A.S., Ceacero, F., Landete-Castillejos, T., Cannas, A., Gallego, L., García, A.J., Morphology, chemical composition, mechanical properties and structure in antler of Sardinian red deer (Cervus elaphus corsicanus). Hystrix 28:1 (2017), 110–112.
Chen, P.Y., Stokes, A.G., McKittrick, J., Comparison of the structure and mechanical properties of bovine femur bone and antler of the North American elk (Cervus elaphus canadensis). Acta Biomater. 5:2 (2009), 693–706.
Clutton-Brock, T.H., The function of antlers. Behaviour 79 (1982), 108–125.
Currey, J.D., The design of mineralised hard tissues for their mechanical functions. J. Exp. Biol. 202 (1999), 3285–3294.
Currey, J.D., Bones: Structure and Mechanics. 2002, Princeton University Press, Princeton.
Currey, J.D., Strain rate dependence of the mechanical properties of reindeer antler and the cumulative damage model of bone fracture. J. Biomech. 22:5 (1989), 469–475.
Currey, J.D., Landete-Castillejos, T., Estevez, J., Ceacero, F., Olguin, A., Garcia, A., Gallego, L., The mechanical properties of red deer antler bone when used in fighting. J. Exp. Biol. 212:24 (2009), 3985–3993 (a).
Currey, J.D., Landete-Castillejos, T., Estevez, J., Olguín, A., García, A., Gallego, L., The Young's modulus and impact energy absorption of wet and dry deer cortical bone. Open Bone J. 1 (2009), 38–45, 10.2174/1876525400901010038 (b).
Davison, K.S., Siminoski, K., Adachi, J.D., Hanley, D.A., Goltzman, D., Hodsman, A.B., Josse, R., Kaiser, S., Olszynski, W.P., Papaioannou, A., Ste-Marie, L.G., Kendler, D.L., Tenenhouse, A., Brown, J.P., Bone strength: the whole is greater than the sum of its parts. Semin. Arthritis Rheum. 36 (2006), 22–31.
Donnelly, E., Methods for assessing bone quality: a review. Clin. Orthop. Relat. Res. 469 (2011), 2128–2138.
El Masri, F., Sapin de Brosses, E., Rhissassi, K., Skalli, W., Mitton, D., Apparent Young's modulus of vertebral cortico-cancellous bone specimens. Comput. Methods Biomech. Biomed. Eng. 15 (2012), 23–28.
Geist, V., The evolution of horn-like organs. Behaviour 27 (1966), 175–214.
Keaveny, T.M., Borchers, R.E., Gibson, L.J., Hayes, W.C., Trabecular bone modulus and strength can depend on specimen geometry. J. Biomech. 26 (1993), 991–1000.
Kitchener, A.C., The evolution and mechanical design of horns and antlers. Rayner, J.M.W.K.J., (eds.) Biomechanics in Evolution, 1991, Cambridge University Presse, Cambridge UK, 229–253.
Kitchener, A.C., Fighting and the mechanical design of horns and antlers. Domenici, P., Blake, R.W., (eds.) Biomechanics in Animal Behaviour, 2000, BIOS Scientific Publishers, Oxford.
Landete-Castillejos, T., Currey, J.D., Estevez, J.A., Gaspar-López, E., Garcia, A., Gallego, L., Influence of physiological effort of growth and chemical composition on antler bone mechanical properties. Bone 41:5 (2007), 794–803.
Landete-Castillejos, T., Currey, J.D., Estevez, J.A., Fierro, Y., Calatayud, A., Ceacero, F., Garcia, A., Gallego, L., Do drastic weather effects on diet influence changes in chemical composition, mechanical properties and structure in deer antlers?. Bone 47 (2010), 815–825.
Landete-Castillejos, T., Kierdorf, H., Gomez, S., Luna, S., García, A., Cappelli, J., Pérez-Serrano, M., Pérez-Barberia, J., Gallego, L., Kierdorf, U., Antlers-evolution, development, structure, composition, and biomechanics of an outstanding type of bone. Bone, 128, 2019, 115046.
Launey, M.E., Chen, P.Y., McKittrick, J., Ritchie, R.O., Mechanistic aspects of the fracture toughness of elk antler bone. Acta Biomater. 6 (2010), 1505–1514.
Leslie, D.M. Jr., Jenkins, K., Rutting mortality among male Roosevelt elk. J. Mammal. 66 (1985), 163–164.
Linde, F., Goosthgen, C.B., Hvid, I., Pongsoipetch, B., Bentzen, S., Mechanical properties of trabecular bone by a non-destructive compression testing approach. Eng. Med. 17 (1988), 23–29.
Linde, F., Hvid, I., Madsen, F., The effect of specimen geometry on the mechanical behaviour of trabecular bone specimens. J. Biomech. 25:4 (1992), 359–368.
Lincoln, G., The biology of antlers. J. Zool. (Lond.) 226 (1992), 517–528.
Ma, S., Goh, E.L., Jin, A., et al. Long-term effects of bisphosphonate therapy: perforations, microcracks and mechanical properties. Sci. Rep., 7, 2017, 43399.
McCalden, R.W., McGeough, J.A., Barker, M.B., Court-Brown, C.M., Age-related changes in the tensile properties of cortical bone. The relative importance of changes in porosity, mineralization, and microstructure. J Bone Joint Surg Am 8 (1993), 1193–1205.
Mosekilde, L., Normal age-related changes in bone mass, structure, and strength-consequences of the remodelling process. Dan. Med. Bull. 1 (1993), 65–83.
Pal, S., Mechanical properties of biological materials. Pal, S., (eds.) Design of Artificial Human Joints & Organs, 2017, Springer, 23–40.
Picavet, P.P., Balligand, M., Organic and mechanical properties of Cervidae antlers: a review. Vet. Res. Commun. 40:3–4 (2016), 141–147.
Rajaram, A., Ramanathan, N., Tensile properties of antler bone. Calcif. Tissue Int. 34 (1982), 301–305.
Reilly, D.T., Burstein, A.H., Frankel, V.H., The elastic modulus for bone. J. Biomech., 7, 1974, 271.
Rho, J.Y., Kuhn-Spearing, L., Zioupos, P., Mechanical properties and the hierarchical structure of bone. Med. Eng. Phys. 20 (1998), 92–102.
R∅hl, L., Larsen, E., Linde, F., Odgaard, A., J∅rgensen, J., Tensile and compressive properties of cancellous bone. J. Biomech. 24 (1991), 1143–1149.
Schaffler, M.B., Burr, D.B., Stiffness of compact hone: effects of porosity and density. J. Biomech. 1 (1988), 13–16.
Shah, S.R., DesJardins, J.D., Blob, R.W., Antler stiffness in caribou (Rangifer tarandus): testing variation in bone material properties between males and females. Zoology (Jena) 111 (2008), 476–482.
Skedros, J.G., Keenan, K.E., Cooper, D.M., Bloebaum, R.D., Histocompositional organization and toughening mechanisms in antler. J. Struct. Biol. 187 (2014), 129–148.
Vashishth, D., Behiri, J.C., Bonfield, W., Crack growth resistance in cortical bone: concept of microcrack toughening. J. Biomech. 30:8 (1997), 763–769.
Wall, J.C., Chatterij, S., Jeffery, J.W., On the origin of scater in results of human bone strength test. Med. Biol. Eng., 8, 1970, 171.
Wang, X., Nyman, J.S., Dong, X., Leng, H., Reyes, M., Fundamental Biomechanics in Bone Tissue Engineering: Synthesis Lectures on Tissue Engineering. 2010, Morgan & Claypool Publishers, San Rafael, California.
Zhao, S., Arnold, M., Ma, S., Abel, R.L., Cobb, J.P., Hansen, U., Boughton, O., Standardizing compression testing for measuring the stiffness of human bone. Bone Joint Res 7:8 (2018), 524–538.
Zhu, M., Keller, T.S., Spengler, D.M., Effects of specimen load-bearing and free surface layers on the compressive mechanical properties of cellular materials. J. Biomech. 27 (1994), 57–66.
Zioupos, P., Currey, J.D., Sedman, A.J., An examination of the micromechanics of failure of bone and antler by acoustic emission tests and Laser Scanning Confocal Microscopy. Med. Eng. Phys. 16:3 (1994), 203–212.
Zioupos, P., Currey, J.D., Changes in the stiffness, strength, and toughness of human cortical bone with age. Bone 22:1 (1998), 57–66.