Numerical simulation of the influence of rough bone-callus interface on the healing of fractured bone.

V. Beilin; G.N. Pande; K. Ito

doi:10.1023/A:1026643016461

Numerical simulation of the influence of rough bone-callus interface on the healing of fractured bone.

V. Beilin, G.N. Pande, K. Ito

Orthopaedic Biomechanics

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The process of healing of fractured bone is known to be influenced by the mechanical environment and the loads exerted by physical activity of the patient or otherwise. We compute mechanical fields in the soft connective tissue of the healing fracture using Biot's poroelasticity model and a finite element (FE) method for low-frequency loading. A two-scale FE framework is used to model effects of the rough bone-callus contact surface. We look at the difference the interface roughness makes with respect to different possible mechanostimulating agents.

Original language	English
Pages (from-to)	373-378
Journal	Mechanics of Composite Materials
Volume	36
Issue number	5
DOIs	https://doi.org/10.1023/A:1026643016461
Publication status	Published - 2000

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title = "Numerical simulation of the influence of rough bone-callus interface on the healing of fractured bone.",

abstract = "The process of healing of fractured bone is known to be influenced by the mechanical environment and the loads exerted by physical activity of the patient or otherwise. We compute mechanical fields in the soft connective tissue of the healing fracture using Biot's poroelasticity model and a finite element (FE) method for low-frequency loading. A two-scale FE framework is used to model effects of the rough bone-callus contact surface. We look at the difference the interface roughness makes with respect to different possible mechanostimulating agents.",

author = "V. Beilin and G.N. Pande and K. Ito",

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AU - Pande, G.N.

AU - Ito, K.

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N2 - The process of healing of fractured bone is known to be influenced by the mechanical environment and the loads exerted by physical activity of the patient or otherwise. We compute mechanical fields in the soft connective tissue of the healing fracture using Biot's poroelasticity model and a finite element (FE) method for low-frequency loading. A two-scale FE framework is used to model effects of the rough bone-callus contact surface. We look at the difference the interface roughness makes with respect to different possible mechanostimulating agents.

AB - The process of healing of fractured bone is known to be influenced by the mechanical environment and the loads exerted by physical activity of the patient or otherwise. We compute mechanical fields in the soft connective tissue of the healing fracture using Biot's poroelasticity model and a finite element (FE) method for low-frequency loading. A two-scale FE framework is used to model effects of the rough bone-callus contact surface. We look at the difference the interface roughness makes with respect to different possible mechanostimulating agents.

U2 - 10.1023/A:1026643016461

DO - 10.1023/A:1026643016461

M3 - Article

SN - 0191-5665

VL - 36

SP - 373

EP - 378

JO - Mechanics of Composite Materials

JF - Mechanics of Composite Materials

IS - 5

ER -

Numerical simulation of the influence of rough bone-callus interface on the healing of fractured bone.

Abstract

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