Pressure and shear stress in trabecular bone marrow during whole bone loading

Abstract Skeletal adaptation to mechanical loading is controlled by mechanobiological signaling. Osteocytes are highly responsive to applied strains, and are the key mechanosensory cells in bone. However, many cells residing in the marrow also respond to mechanical cues such as hydrostatic pressure...

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Bibliographic Details
Published in:Journal of biomechanics 2015-09, Vol.48 (12), p.3035-3043
Main Authors: Metzger, Thomas A, Schwaner, Stephen A, LaNeve, Anthony J, Kreipke, Tyler C, Niebur, Glen L
Format: Article
Language:English
Subjects:
Activities of Daily Living
Adaptation
Animals
Bone marrow
Bone Marrow - physiology
Bones
Computational modeling
Cyclic loads
Experimental measurements
Fatigue (materials)
Femur - cytology
Femur - physiology
Fluid-structure interaction
Gene expression
Hydrodynamics
Hydrostatic Pressure
Load
Mathematical models
Mesenchymal Stromal Cells - cytology
Models, Biological
Osteocytes - cytology
Permeability
Physical Medicine and Rehabilitation
Pressure
Pressure gradients
Pressure transducers
Scale models
Shear Strength
Shear stress
Stem cells
Strain gauges
Stress, Mechanical
Studies
Swine
Tomography
Trabecular bone
Transplants & implants
Weight-Bearing
Whole bone loading
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Summary:Abstract Skeletal adaptation to mechanical loading is controlled by mechanobiological signaling. Osteocytes are highly responsive to applied strains, and are the key mechanosensory cells in bone. However, many cells residing in the marrow also respond to mechanical cues such as hydrostatic pressure and shear stress, and hence could play a role in skeletal adaptation. Trabecular bone encapsulates marrow, forming a poroelastic solid. According to the mechanical theory, deformation of the pores induces motion in the fluid-like marrow, resulting in pressure and velocity gradients. The latter results in shear stress acting between the components of the marrow. To characterize the mechanical environment of trabecular bone marrow in situ , pore pressure within the trabecular compartment of whole porcine femurs was measured with miniature pressure transducers during stress-relaxation and cyclic loading. Pressure gradients ranging from 0.013 to 0.46 kPa/mm were measured during loading. This range was consistent with calculated pressure gradients from continuum scale poroelastic models with the same permeability. Micro-scale computational fluid dynamics models created from computed tomography images were used to calculate the micromechanical stress in the marrow using the measured pressure differentials as boundary conditions. The volume averaged shear stress in the marrow ranged from 1.67 to 24.55 Pa during cyclic loading, which exceeds the mechanostimulatory threshold for mesenchymal lineage cells. Thus, the loading of bone through activities of daily living may be an essential component of bone marrow health and mechanobiology. Additional studies of cell-level interactions during loading in healthy and disease conditions will provide further incite into marrow mechanobiology.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2015.07.028