Osteon interfacial strength and histomorphometry of equine cortical bone

Bigley, R. F.; Griffin, Lanny; Christensen, Lisa M.; Vandenbosch, Ryan

doi:10.1016/j.jbiomech.2005.05.006

Cited by 53 publications

(57 citation statements)

References 40 publications

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“…Variables such as collagen fiber orientation, osteon shape, and intra‐cortical porosity (i.e. resorption spaces and Haversian canals) have all been linked to the mechanical competency of bone tissue (Sevostianov and Kachanov, 2000; Goldman et al, 2003, 2014; Bigley et al, 2006; Skedros et al, 2013, 2007). Counts and measurements along with regionally‐specific concentrations of microstructural features may reflect different adaptations to bone strain (Rose et al, 2012).…”

mentioning

confidence: 99%

Cortical bone histomorphology of known‐age skeletons from the Kirsten collection, Stellenbosch university, South Africa

Pfeiffer

Heinrich

Beresheim

et al. 2016

American J Phys Anthropol

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ObjectivesNormal human bone tissue changes predictably as adults get older, but substantial variability in pattern and pace remains unexplained. Information is needed regarding the characteristics of histological variables across diverse human populations.MethodsUndecalcified thin sections from mid‐thoracic ribs of 213 skeletons (138 M, 75 F, 17–82 years, mean age 48 years), are used to explore the efficacy of an established age‐at‐death estimation method and methodological approach (Cho et al.: J Forensic Sci 47 (2002) 12‐18) and expand on it. The ribs are an age‐balanced sample taken from skeletonized cadavers collected from 1967 to 1999 in South Africa, each with recorded sex, age, cause of death and government‐defined population group (129 “Colored,” 49 “Black,” 35 “White”).ResultsThe Ethnicity Unknown equation performs better than those developed for European‐Americans and African‐Americans, in terms of accuracy and bias. A new equation based solely on the study sample does not improve accuracy. Osteon population densities (OPD) show predicted values, yet secondary osteon areas (On.Ar) are smaller than expected for non‐Black subgroups. Relative cortical area (Ct.Ar/Tt.Ar) is low among non‐Whites.ConclusionsResults from this highly diverse sample show that population‐specific equations do not increase estimate precision. While within the published range of error for the method (±24.44 years), results demonstrate a systematic under‐aging of young adults and over‐aging of older adults. The regression approach is inappropriate. The field needs fresh approaches to statistical treatment and to factors behind cortical bone remodeling. Am J Phys Anthropol 160:137–147, 2016. © 2016 The Authors American Journal of Physical Anthropology Published by Wiley Periodicals, Inc.

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confidence: 99%

Cortical bone histomorphology of known‐age skeletons from the Kirsten collection, Stellenbosch university, South Africa

Pfeiffer

Heinrich

Beresheim

et al. 2016

American J Phys Anthropol

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“…The cortical bone can be properly modelled as a rate dependent transversely isotropic material (Reilly and Burstein, 1975;Yoon and Katz, 1976) thus this tissue can be considered analogous to a fiber reinforced composite material as has been demonstrated in different contributions in the literature; see for instance Guo et al (1998), Hogan (1992), Katz et al (1984), and Bigley et al (2006).…”

Section: Fe Assuming Anisotropic Behaviourmentioning

confidence: 99%

A review on recent advances in numerical modelling of bone cutting

Marco

Rodríguez-Millán

Santiuste

et al. 2015

Journal of the Mechanical Behavior of Biomedical Materials

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“…This means that the assumption of mechanically isotropic bone tissue is a strong simplification of the problem. The cortical bone can be properly modelled as a rate dependent transversely isotropic material [33,34], thus the cortical bone tissue can be considered analogous to a fibre reinforced composite material [35][36][37][38]. Based on this analogy, the osteon acts as the fibre with the matrix being interstitial bone consisting of old osteon fragments.…”

Section: Anisotropic Materialsmentioning

confidence: 99%

The influence of anisotropy in numerical modeling of orthogonal cutting of cortical bone

Santiuste

Rodríguez-Millán

Giner

et al. 2014

Composite Structures

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Cutting operations in bone are involved in surgical treatments in orthopaedics and traumatology.The importance of guaranteeing the absence of damage in the living workpiece is equivalent in this case to ensuring surface quality. The knowledge in this field is really far from the expertise in industrial cutting of mechanical components. Modeling of bone cutting is a challenge strongly dependent on the accurate modeling of mechanical behaviour of the bone. This paper focuses on modeling of orthogonal cutting of cortical bone. The intrinsic anisotropic nature of the cortical bone that makes it comparable to a compos-ite material is taken into account. The influence of anisotropy is analysed comparing this behaviour with an isotropic approach. It is shown that both chip morphology and temperature are affected by the anisot-ropy of the cortical bone that acts as a workpiece.

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Osteon interfacial strength and histomorphometry of equine cortical bone

Cited by 53 publications

References 40 publications

Cortical bone histomorphology of known‐age skeletons from the Kirsten collection, Stellenbosch university, South Africa

Cortical bone histomorphology of known‐age skeletons from the Kirsten collection, Stellenbosch university, South Africa

A review on recent advances in numerical modelling of bone cutting

The influence of anisotropy in numerical modeling of orthogonal cutting of cortical bone

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