Ashwij Mayya scite author profile

Cortical bone, found in the central part of long bones like femur, is known to adapt to local mechanical stresses. This adaptation has been linked exclusively with Haversian remodelling involving bone resorption and formation of secondary osteons. Compared to primary/plexiform bone, the Haversian bone has lower stiffness, fatigue strength and fracture toughness, raising the question why nature prefers an adaptation that is detrimental to bone's primary function of bearing mechanical stresses. Here, we show that in the goat femur, Haversian remodelling occurs only at locations of high compressive stresses. At locations corresponding to high tensile stresses, we observe a microstructure that is non-Haversian. Compared with primary/plexiform bone, this microstructure's mineralisation is significantly higher with a distinctly different spatial pattern. Thus, the Haversian structure is an adaptation only to high compressive stresses rendering its inferior tensile properties irrelevant as the regions with high tensile stresses have a non-Haversian, apparently primary microstructure.

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Haversian microstructure in bovine femoral cortices: An adaptation for improved compressive strength

Mayya

Banerjee

Rajesh

2016

Materials Science and Engineering: C

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Splitting fracture in bovine bone using a porosity-based spring network model

Mayya

Praveen

Banerjee

et al. 2016

J. R. Soc. Interface.

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We examine the specific role of the structure of the network of pores in plexiform bone in its fracture behaviour under compression. Computed tomography scan images of the sample pre-and post-compressive failure show the existence of weak planes formed by aligned thin long pores extending through the length. We show that the physics of the fracture process is captured by a two-dimensional random spring network model that reproduces well the macroscopic response and qualitative features of fracture paths obtained experimentally, as well as avalanche statistics seen in recent experiments on porcine bone.

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Damage spreading in quasi-brittle disordered solids: II. What the statistics of precursors teach us about compressive failure

Berthier¹,

Mayya²,

Ponson³

2022

Journal of the Mechanics and Physics of Solids

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Role of porosity and matrix behavior on compressive fracture of Haversian bone using random spring network model

Mayya

Banerjee

Rajesh

2018

Journal of the Mechanical Behavior of Biomedical Materials

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Ashwij Mayya

Mammalian cortical bone in tension is non-Haversian

Haversian microstructure in bovine femoral cortices: An adaptation for improved compressive strength

Splitting fracture in bovine bone using a porosity-based spring network model

Damage spreading in quasi-brittle disordered solids: II. What the statistics of precursors teach us about compressive failure

Role of porosity and matrix behavior on compressive fracture of Haversian bone using random spring network model

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