The In Situ Mechanics of Trabecular Bone Marrow: The Potential for Mechanobiological Response

Metzger, Thomas A.; Kreipke, Tyler C.; Vaughan, Ted J.; McNamara, Laoise M.; Niebur, Glen L.

doi:10.1115/1.4028985

Cited by 61 publications

(35 citation statements)

References 62 publications

(67 reference statements)

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“…This is in agreement with previous studies, 3,13 although a different trend has been observed elsewhere. 30 The aim of this study was to assess whether physiological compression of trabecular bone generates shear stress within the bone marrow which stimulates new bone growth. It was found within the computational models of the sample specific geometries that shear stress of sufficient magnitude to produce an osteogenic response in MSCs was indeed generated during physiological compression.…”

Section: Discussionmentioning

confidence: 99%

“…Recent studies have demonstrated that the shear stress generated in marrow can be of significant magnitude to stimulate an osteogenic response in the bone marrow cells. 3,4,13,16,30,42 The magnitude of shear stress required to generate an osteogenic responses in MSCs and pre-osteoblastic cells in vitro is commonly reported to range between 0.1 and 1 Pa. 1,2,11 Other studies have suggested a lower threshold <0.05 Pa 10,39 and have demonstrated no significant difference in the osteogenic response between osteoblastic cells exposed to either 0.06 or 0.6 Pa. 33 However, the response of marrow cells to this shear stress generated during physiological loading has yet to be determined.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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Understanding how bone marrow multipotent stromal cells (MSCs) contribute to new bone formation and remodeling in vivo is of principal importance for informing the development of effective bone tissue engineering strategies in vitro. However, the precise in situ stimuli that MSCs experience have not been fully established. The shear stress generated within the bone marrow of physiologically loaded samples has never been determined, but could be playing an important role in the generation of sufficient stimulus for MSCs to undergo osteogenic differentiation. In this study fluid structure interaction (FSI) computational models were used in conjunction with a bioreactor which physiologically compresses explanted trabecular bone samples to determine whether MSCs can be directly stimulated by mechanical cues within the bone marrow. Experimentally loaded samples were found to have greater osteogenic activity, as verified by bone histomorphometry, compared to control static samples. FSI models demonstrated a linear relationship between increasing shear stress and decreasing bone volume. The FSI models demonstrated that bone strain, not marrow shear stress, was likely the overall driving mechanical signal for new bone formation during compression. However, the shear stress generated in the models is within the range of values which has been shown previously to generate an osteogenic response in MSCs.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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“…Second, these data indicate that MSCs in the humerus were less responsive to mechanical signals, either because of reduced cellular mechanosensitivity per se (Volk et al, 2012), or perhaps due to aspects of the marrow niche (e.g. adjacency to hematopoietic stem cells, higher concentration of adipocytes, marrow viscosity) that confounded the ability of MSCs to commit to an osteoblast lineage (Adler et al, 2014;Metzger et al, 2015). These interpretations must be considered with caution, because changes in MSC numbers alone are not a direct indication of differentiation activity toward osteoblast production, and we did not directly show here that osteoblast numbers increased with exercise treatment.…”

Section: Discussionmentioning

confidence: 99%

Focal enhancement of the skeleton to exercise correlates to mesenchymal stem cell responsivity rather than peak external forces

Wallace

Pagnotti

Rubin-Sigler

et al. 2015

Journal of Experimental Biology

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Force magnitudes have been suggested to drive the structural response of bone to exercise. As importantly, the degree to which any given bone can adapt to functional challenges may be enabled, or constrained, by regional variation in the capacity of marrow progenitors to differentiate into bone-forming cells. Here, we investigate the relationship between bone adaptation and mesenchymal stem cell (MSC) responsivity in growing mice subject to exercise. First, using a force plate, we show that peak external forces generated by forelimbs during quadrupedal locomotion are significantly higher than hindlimb forces. Second, by subjecting mice to treadmill running and then measuring bone structure with μCT, we show that skeletal effects of exercise are site-specific but not defined by load magnitudes. Specifically, in the forelimb, where external forces generated by running were highest, exercise failed to augment diaphyseal structure in either the humerus or radius, nor did it affect humeral trabecular structure. In contrast, in the ulna, femur and tibia, exercise led to significant enhancements of diaphyseal bone areas and moments of area. Trabecular structure was also enhanced by running in the femur and tibia. Finally, using flow cytometry, we show that marrow-derived MSCs in the femur are more responsive to exercise-induced loads than humeral cells, such that running significantly lowered MSC populations only in the femur. Together, these data suggest that the ability of the progenitor population to differentiate toward osteoblastogenesis may correlate better with bone structural adaptation than peak external forces caused by exercise.

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“…Similarly, estimated shear stress in the marrow near individual trabeculae is 0.5 to 2 Pa [33,37]. In some cases, shear stress may reach up to 5 Pa when the marrow is modeled as a highly viscous material [38]. Using bone explants, Verbruggen et al [39, 40••] recently showed that application of uniaxial compressive strains of up to 3000 με resulted in membrane strains in osteocytes and osteoblasts of up to 30,000 and 25,000 με, respectively, a 10× amplification.…”

Section: Mechanical Signals Generated During Daily Activitiesmentioning

confidence: 99%

Bone Homeostasis and Repair: Forced Into Shape

Castillo

Leucht

2015

Curr Rheumatol Rep

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Mechanical loading is a potent anabolic regulator of bone mass, and the first line of defense for bone loss is weight-bearing exercise. Likewise, protected weight bearing is the first prescribed physical therapy following orthopedic reconstructive surgery. In both cases, enhancement of new bone formation is the goal. Our understanding of the physical cues, mechanisms of force sensation, and the subsequent cellular response will help identify novel physical and therapeutic treatments for age- and disuse-related bone loss, delayed- and nonunion fractures, and significant bony defects. This review highlights important new insights into the principles and mechanisms governing mechanical adaptation of the skeleton during homeostasis and repair and ends with a summary of clinical implications stemming from our current understanding of how bone adapts to biophysical force.

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The In Situ Mechanics of Trabecular Bone Marrow: The Potential for Mechanobiological Response

Cited by 61 publications

References 62 publications

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

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

Focal enhancement of the skeleton to exercise correlates to mesenchymal stem cell responsivity rather than peak external forces

Bone Homeostasis and Repair: Forced Into Shape

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