An Experimental and Computational Investigation of Bone Formation in Mechanically Loaded Trabecular Bone Explants

Birmingham, Evelyn; Niebur, Glen L.; McNamara, Laoise M.; McHugh, Peter E.

doi:10.1007/s10439-015-1378-4

Cited by 27 publications

(13 citation statements)

References 39 publications

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“…Bioreactor experiments have been conducted in the past to study the effects of combination systems that have both fluid flow and mechanical stimulation components to induce cellular proliferation and/or differentiation of 3D premature tissue grafts (Birmingham, Niebur, McNamara, & McHugh, ; Engelmayr et al, ; Haasper et al, ; Hoffmann, Feliciano, Martin, de Wild, & Wendt, ; Jagodzinski et al, ; S. T. Li et al, ; C. Liu et al, ; Orr & Burg, ; Witt, Duda, Bergmann, & Petersen, ). Few studies have compared the independent and combined effects of the perfusion flow and mechanical stimuli on cellular proliferation and osteogenic differentiation (Engelmayr et al, ; Jagodzinski et al, ; C. Liu et al, ).…”

Section: Discussionmentioning

confidence: 99%

Biomimetic fetal rotation bioreactor for engineering bone tissues—Effect of cyclic strains on upregulation of osteogenic gene expression

Ravichandran

Wen

Lim

et al. 2018

J Tissue Eng Regen Med

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Cells respond to physiological mechanical stresses especially during early fetal development. Adopting a biomimetic approach, it is necessary to develop bioreactor systems to explore the effects of physiologically relevant mechanical strains and shear stresses for functional tissue growth and development. This study introduces a multimodal bioreactor system that allows application of cyclic compressive strains on premature bone grafts that are cultured under biaxial rotation (chamber rotation about 2 axes) conditions for bone tissue engineering. The bioreactor is integrated with sensors for dissolved oxygen levels and pH that allow real-time, non-invasive monitoring of the culture parameters. Mesenchymal stem cells-seeded polycaprolactone-β-tricalcium phosphate scaffolds were cultured in this bioreactor over 2 weeks in 4 different modes-static, cyclic compression, biaxial rotation, and multimodal (combination of cyclic compression and biaxial rotation). The multimodal culture resulted in 1.8-fold higher cellular proliferation in comparison with the static controls within the first week. Two weeks of culture in the multimodal bioreactor utilizing the combined effects of optimal fluid flow conditions and cyclic compression led to the upregulation of osteogenic genes alkaline phosphatase (3.2-fold), osteonectin (2.4-fold), osteocalcin (10-fold), and collagen type 1 α1 (2-fold) in comparison with static cultures. We report for the first time, the independent and combined effects of mechanical stimulation and biaxial rotation for bone tissue engineering using a bioreactor platform with non-invasive sensing modalities. The demonstrated results show leaning towards the futuristic vision of using a physiologically relevant bioreactor system for generation of autologous bone grafts for clinical implantation.

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Section: Discussionmentioning

confidence: 99%

Biomimetic fetal rotation bioreactor for engineering bone tissues—Effect of cyclic strains on upregulation of osteogenic gene expression

Ravichandran

Wen

Lim

et al. 2018

J Tissue Eng Regen Med

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“…The boundary condition of the FEA used in this simulation is shown in Figure 5. It defines the prescribed boundary condition of displacement on the top surface to simulate the uniaxial load because of the bone's mechanical loading [14]. Besides, a zero-displacement boundary condition is assigned to the opposite surface in its normal.…”

Section: Boundary Condition and Materials Inputmentioning

confidence: 99%

“…Nodes included in this boundary condition are confined only in the y-direction but can move freely inside the x-z plane. The model is fixed in the ydirection at the bottom, and a load-based strain 1000-3500 µε is applied to the upper surface according to the variation in the mechanical load of the bone [14] [15]. The magnesium's nonlinear-elastic/plastic material behaviour was modelled with: 3500 MPa as the elastic modulus, a Poisson's ratio of 0.35, and kinematic tangent modulus of 0.05 E.…”

Section: Boundary Condition and Materials Inputmentioning

confidence: 99%

Fatigue Prediction of Porous Magnesium Bone Scaffold Using Finite Element Method

Putra¹,

Prakoso²,

Nugrasyah³

et al. 2021

Atlantis Highlights in Engineering

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The purpose of this study was to determine fatigue in a porous magnesium bone scaffold. It applies finite element simulation in assessing bone scaffolding's fatigue behaviour with variations in axial loading based on physiological activities in humans. By applying the boundary conditions to the solid mechanics model and fatigue simulation, it subjects each specimen to a different loading of 1000 -3500 με, which gives the bone scaffold displacement variations. The simulation results of fatigue life for the porosity of 30%, 41%, and 55% show that the greater the loading, the lower the number of failure cycles on the porous magnesium bone scaffold. For a porosity of 30% with a load of 1000 -3500 με, it produces the number of failure cycles from 3.99x10 22 -3.61 x10 16 .

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“…To this date, experimental and simulation study have been performing in order to capture the value of these biomechanical stimuli that encourage the remodelling process. [6][7][8] Bone marrow is a prime component in trabecular bone, in which it accommodates bone predecessors' cells for bone remodelling. Thus, it is important to consider it presence to better represent the actual conditions of trabecular bone.…”

Section: Introductionmentioning

confidence: 99%

Influence of bone marrow characteristic and trabecular bone morphology on bone remodelling process with FSI approach

Rabiatul

Rianti

Januddi

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part L:

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While doing daily physiological activities, the trabecular bone will experience a certain amount of deformation which leads to the bone marrow movement. The movement can affect the bone remodelling process and the properties of the bone itself. The bone marrow plays a role as a hydraulic stiffening of the trabecular structure. However, previous studies analysed on trabecular bone and bone marrow separately, which is not considered as the actual condition. Thus, it is crucial to consider combine analyses of the bone marrow with the trabecular structure simultaneous. The aim of this study is to investigate the effect of bone marrow on the mechanical environment and the structure of trabecular bone during normal walking loading. Hence, this study used the Fluid-Structure Interaction (FSI) approach as a finite element method to discover the effect of bone marrow to the trabecular structure and vice versa. The findings show the shear stress value along normal walking phase was found in a range of 0.01–0.27 Pa which is sufficient to regulated cell response minimally. This study provides insight into understanding the related mechanobiological responds towards supply of nutrients onto bone cells.

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An Experimental and Computational Investigation of Bone Formation in Mechanically Loaded Trabecular Bone Explants

Cited by 27 publications

References 39 publications

Biomimetic fetal rotation bioreactor for engineering bone tissues—Effect of cyclic strains on upregulation of osteogenic gene expression

Biomimetic fetal rotation bioreactor for engineering bone tissues—Effect of cyclic strains on upregulation of osteogenic gene expression

Fatigue Prediction of Porous Magnesium Bone Scaffold Using Finite Element Method

Influence of bone marrow characteristic and trabecular bone morphology on bone remodelling process with FSI approach

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