Osteonal structure in the equine third metacarpus

Martin, R. B.; Gibson, V. A.; Stover, S. M.; Gibeling, J. C.; Griffins, L. V.

Affiliations

¹Orthopedic Research Laboratory, School of Medicine, University of California at Davis, Davis, CA, USA

²Veterinary Orthopedic Research Laboratory, School of Veterinary Medicine, University of California at Davis, Davis, CA, USA

³Department of Chemical Engineering and Materials Science, College of Engineering, University of California at Davis, Davis, CA, USA

Abstract and keywords

In studying the flexural fatigue properties of the equine third metacarpal (cannon) bone, we previously found that the dorsal region was weaker monotonically, but more fatigue resistant, than the lateral region. Fatigue resistance was associated with fracture surfaces which demonstrated that secondary osteons had “pulled out” of the surrounding matrix; this never happened in lateral specimens. We therefore became interested in the osteonal structure of this bone, and began to study its birefringence patterns in circularly polarized light. We found that the predominant type of secondary osteon was one in which only the outermost few lamellae were circumferential, with the inner lamellae being longitudinally oriented. This “hoop” pattern had not been described in Ascenzi's classic papers. Using basic fuchsin-stained, undecalcified cross-sections from the dorsal, medial, and lateral midshaft regions of 12 pairs of cannon bones, we classified 360 secondary osteons according to their birefringence patterns, and measured their inner and outer diameters. We found that variants of the hoop category comprised 60% of all osteons, but were significantly less common in the dorsal region, where the predominant types were Ascenzi's “longitudinal” or “alternating” patterns. The dorsal region also had smaller osteons (OD = 156 ± 19 pm) than the medial (179 ± 13 pm, p = 0.0004) and lateral (182 ± 13 μm, p = 0.0001) regions. We postulate that these regional variations in osteonal size and structure, which are obviously produced by regional variations in remodeling, have important mechanical implications.

Keywords: Secondary osteon; Birefringence; Lamellar structure; Horse

Links

DOI: 10.1016/8756-3282(96)00167-6

PubMed: 8853861

WoS: A1996VB74000013

History

Received: 1996-01-18

Revised: 1996-04-02

Accepted: 1996-04-29

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Cited By (22)

Year	Entry
2005	Skedros JG, Holmes JL, Vajda EG, Bloebaum AD. Cement lines of secondary osteons in human bone are not mineral‐deficient: new data in a historical perspective. Anat Rec. September 2005;286A(1):781-803.
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2006	Hoc T, Henry L, Verdier M, Aubry D, Sedel L, Meunier A. Effect of microstructure on the mechanical properties of Haversian cortical bone. Bone. April 2006;38(4):466-474.
2003	Malik CL, Stover SM, Martin RB, Gibeling JC. Equine cortical bone exhibits rising R-curve fracture mechanics. J Biomech. February 2003;36(2):191-198.
2003	Götzen N, Cross AR, Ifju PG, Rapoff AJ. Understanding stress concentration about a nutrient foramen. J Biomech. October 2003;36(10):1511-1521.
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	Bigley RF, Griffin LV, Christensen L, Vandenbosch R. Osteon interfacial strength and histomorphometry of equine cortical bone. J Biomech. 2006;39(9):1629-1640.
2007	Ural A, Vashishth D. Anisotropy of age-related toughness loss in human cortical bone: a finite element study. J Biomech. 2007;40(7):1606-1614.
2012	Feng L, Chittenden M, Schirer J, Dickinson M, Jasiuk I. Mechanical properties of porcine femoral cortical bone measured by nanoindentation. J Biomech. June 26, 2012;45(10):1775-1782.
2020	Ascenzi M-G, Zonca A, Keyak JH. Effect of cortical bone micro-structure in fragility fracture patients on lamellar stress. J Biomech. February 13, 2020;100:109596.
2003	Hiller LP, Stover SM, Gibson VA, Gibeling JC, Prater CS, Hazelwood SJ, Yeh OC, Martin RB. Osteon pullout in the equine third metacarpal bone: effects of ex vivo fatigue. J Orthop Res. May 2003;21(3):481-488.
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