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Abstract
The transport of fluid, nutrients, and signaling molecules in the bone lacunar–canalicular system (LCS) is critical for osteocyte survival and function. We have applied the fluorescence recovery after photobleaching (FRAP) approach to quantify load-induced fluid and solute transport in the LCS in situ, but the measurements were limited to cortical regions 30–50 μm underneath the periosteum due to the constrains of laser penetration. With this work, we aimed to expand our understanding of load-induced fluid and solute transport in both trabecular and cortical bone using a multiscaled image-based finite element analysis (FEA) approach. An intact murine tibia was first re-constructed from microCT images into a three-dimensional (3D) linear elastic FEA model, and the matrix deformations at various locations were calculated under axial loading. A segment of the above 3D model was then imported to the biphasic poroelasticity analysis platform (FEBio) to predict load-induced fluid pressure fields, and interstitial solute/fluid flows through LCS in both cortical and trabecular regions. Further, secondary flow effects such as the shear stress and/or drag force acting on osteocytes, the presumed mechano-sensors in bone, were derived using the previously developed ultrastructural model of Brinkman flow in the canaliculi. The material properties assumed in the FEA models were validated against previously obtained strain and FRAP transport data measured on the cortical cortex. Our results demonstrated the feasibility of this computational approach in estimating the fluid flux in the LCS and the cellular stimulation forces (shear and drag forces) for osteocytes in any cortical and trabecular bone locations, allowing further studies of how the activation of osteocytes correlates with in vivo functional bone formation. The study provides a promising platform to reveal potential cellular mechanisms underlying the anabolic power of exercises and physical activities in treating patients with skeletal deficiencies.
Solute transport: Model reveals flow of fluid and nutrients in bone
A computational model of molecular movement within bone has revealed how mechanical forces impact bone formation. The findings help identify chemical and mechanical responses to physical activities in healthy individuals and point to ways that exercise could help people with skeletal deficiencies. Liyun Wang and colleagues from the University of Delaware, USA, created a three-dimensional model of a mouse leg bone to study how mechanical forces associated with exercise affect fluid flux and mechanical stimuli around osteocytes, which are embedded in bone and critical for bone health. The researchers validated their model using a previously developed imaging technique that can quantify load-induced transport of fluid, nutrients and signaling molecules, but only in the outer shell of bone. The new computational approach can be used to estimate fluid flows in any bone region, especially for the inside of bone which has been difficult to study.
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Lixia Fan, Shaopeng Pei, X Lucas Lu, Liyun Wang.
A multiscale 3D finite element analysis of fluid/solute transport in mechanically loaded bone.
Bone Research, 2016, 4(1): 16032 DOI:10.1038/boneres.2016.32
| [1] |
Duncan RL, Turner CH. Mechanotransduction and the functional response of bone to mechanical strain. Calcif Tissue Int, 1995, 57: 344-358
|
| [2] |
Klein-Nulend J, Bacabac RG, Mullender MG. Mechanobiology of bone tissue. Pathol Biol (Paris), 2005, 53: 576-580
|
| [3] |
Lanyon LE, Hampson WG, Goodship AE et al Bone deformation recorded in vivo from strain gauges attached to the human tibial shaft. Acta Orthop Scand, 1975, 46: 256-268
|
| [4] |
Burr DB, Milgrom C, Fyhrie D et al In vivo measurement of human tibial strains during vigorous activity. Bone, 1996, 18: 405-410
|
| [5] |
Nicolella DP, Moravits DE, Gale AM et al Osteocyte lacunae tissue strain in cortical bone. J Biomech, 2006, 39: 1735-1743
|
| [6] |
Owan I, Burr DB, Turner CH et al Mechanotransduction in bone: osteoblasts are more responsive to fluid forces than mechanical strain. Am J Physiol, 1997, 273: C810-C815
|
| [7] |
You J, Yellowley CE, Donahue HJ et al Substrate deformation levels associated with routine physical activity are less stimulatory to bone cells relative to loading-induced oscillatory fluid flow. J Biomech Eng, 2000, 122: 387-393
|
| [8] |
Weinbaum S, Cowin SC, Zeng Y. A model for the excitation of osteocytes by mechanical loading-induced bone fluid shear stresses. J Biomech, 1994, 27: 339-360
|
| [9] |
Fritton SP, Weinbaum S. Fluid and solute transport in bone: flow-induced mechanotransduction. Annu Rev Fluid Mech, 2009, 41: 347-374
|
| [10] |
Bonewald LF. The amazing osteocyte. J Bone Miner Res, 2011, 26: 229-238
|
| [11] |
Robling AG, Niziolek PJ, Baldridge LA et al Mechanical stimulation of bone in vivo reduces osteocyte expression of Sost/sclerostin. J Biol Chem, 2008, 283: 5866-5875
|
| [12] |
You L, Temiyasathit S, Lee P et al Osteocytes as mechanosensors in the inhibition of bone resorption due to mechanical loading. Bone, 2008, 42: 172-179
|
| [13] |
Dallas SL, Prideaux M, Bonewald LF. The osteocyte: an endocrine cell and more. Endocr Rev, 2013, 34: 658-690
|
| [14] |
Piekarski K, Munro M. Transport mechanism operating between blood supply and osteocytes in long bones. Nature, 1977, 269: 80-82
|
| [15] |
Lai X, Price C, Modla S et al The dependences of osteocyte network on bone compartment, age, and disease. Bone Res, 2015, 3: 15009
|
| [16] |
Wang L, Wang Y, Han Y et al In situ measurement of solute transport in the bone lacunar-canalicular system. Proc Natl Acad Sci USA, 2005, 102: 11911-11916
|
| [17] |
You L, Cowin SC, Schaffler MB et al A model for strain amplification in the actin cytoskeleton of osteocytes due to fluid drag on pericellular matrix. J Biomech, 2001, 34: 1375-1386
|
| [18] |
You LD, Weinbaum S, Cowin SC et al Ultrastructure of the osteocyte process and its pericellular matrix. Anat Rec A Discov Mol Cell Evol Biol, 2004, 278: 505-513
|
| [19] |
Goulet GC, Coombe D, Martinuzzi RJ et al Poroelastic evaluation of fluid movement through the lacunocanalicular system. Ann Biomed Eng, 2009, 37: 1390-1402
|
| [20] |
Goulet GC, Hamilton N, Cooper D et al Influence of vascular porosity on fluid flow and nutrient transport in loaded cortical bone. J Biomech, 2008, 41: 2169-2175
|
| [21] |
Gururaja S, Kim HJ, Swan CC et al Modeling deformation-induced fluid flow in cortical bone's canalicular-lacunar system. Ann Biomed Eng, 2005, 33: 7-25
|
| [22] |
Kufahl RH, Saha S. A theoretical model for stress-generated fluid flow in the canaliculi-lacunae network in bone tissue. J Biomech, 1990, 23: 171-180
|
| [23] |
McCarthy ID, Yang L. A distributed model of exchange processes within the osteon. J Biomech, 1992, 25: 441-450
|
| [24] |
Srinivasan S, Gross TS. Canalicular fluid flow induced by bending of a long bone. Med Eng Phys, 2000, 22: 127-133
|
| [25] |
Wang L, Cowin SC, Weinbaum S et al Modeling tracer transport in an osteon under cyclic loading. Ann Biomed Eng, 2000, 28: 1200-1209
|
| [26] |
Zhou X, Novotny JE, Wang L. Modeling fluorescence recovery after photobleaching in loaded boneotential applications in measuring fluid and solute transport in the osteocytic lacunar-canalicular system. Ann Biomed Eng, 2008, 36: 1961-1977
|
| [27] |
Price C, Zhou X, Li W et al Real-time measurement of solute transport within the lacunar-canalicular system of mechanically loaded bone: direct evidence for load-induced fluid flow. J Bone Miner Res, 2011, 26: 277-285
|
| [28] |
Wang B, Zhou X, Price C et al Quantifying load-induced solute transport and solute-matrix interaction within the osteocyte lacunar-canalicular system. J Bone Miner Res, 2013, 28: 1075-1086
|
| [29] |
Wang B, Lai X, Price C et al Perlecan-containing pericellular matrix regulates solute transport and mechanosensing within the osteocyte lacunar-canalicular system. J Bone Miner Res, 2014, 29: 878-891
|
| [30] |
Oxlund H, Ejersted C, Andreassen TT et al Parathyroid hormone (1-34) and (1-84) stimulate cortical bone formation both from periosteum and endosteum. Calcif Tissue Int, 1993, 53: 394-399
|
| [31] |
Parfitt AM, Mathews CH, Villanueva AR et al Relationships between surface, volume, and thickness of iliac trabecular bone in aging and in osteoporosis. Implications for the microanatomic and cellular mechanisms of bone loss. J Clin Invest, 1983, 72: 1396-1409
|
| [32] |
Deligianni DD, Apostolopoulos CA. Multilevel finite element modeling for the prediction of local cellular deformation in bone. Biomech Model Mechanobiol, 2008, 7: 151-159
|
| [33] |
Steck R, Niederer P, Knothe Tate ML. A finite difference model of load-induced fluid displacements within bone under mechanical loading. Med Eng Phys, 2000, 22: 117-125
|
| [34] |
Li W, You L, Schaffler MB et al The dependency of solute diffusion on molecular weight and shape in intact bone. Bone, 2009, 45: 1017-1023
|
| [35] |
Price C, Li W, Novotny JE et al An in-situ fluorescence-based optical extensometry system for imaging mechanically loaded bone. J Orthop Res, 2010, 28: 805-811
|
| [36] |
Maas SA, Ellis BJ, Ateshian GA et al FEBio: finite elements for biomechanics. J Biomech Eng, 2012, 134: 011005
|
| [37] |
Mauck RL, Hung CT, Ateshian GA. Modeling of neutral solute transport in a dynamically loaded porous permeable gel: implications for articular cartilage biosynthesis and tissue engineering. J Biomech Eng, 2003, 125: 602-614
|
| [38] |
Gardinier JD, Townend CW, Jen KP et al In situ permeability measurement of the mammalian lacunar-canalicular system. Bone, 2010, 46: 1075-1081
|
| [39] |
Cardoso L, Fritton SP, Gailani G et al Advances in assessment of bone porosity, permeability and interstitial fluid flow. J Biomech, 2013, 46: 253-265
|
| [40] |
Ciani C, Doty SB, Fritton SP. An effective histological staining process to visualize bone interstitial fluid space using confocal microscopy. Bone, 2009, 44: 1015-1017
|
| [41] |
Sharma D, Ciani C, Marin PA et al Alterations in the osteocyte lacunar-canalicular microenvironment due to estrogen deficiency. Bone, 2012, 51: 488-497
|
| [42] |
Wijeratne SS, Martinez JR, Grindel BJ et al Single molecule force measurements of perlecan/HSPG2: A key component of the osteocyte pericellular matrix. Matrix Biol, 2016, 50: 27-38
|
| [43] |
Jing D, Baik AD, Lu XL et al In situ intracellular calcium oscillations in osteocytes in intact mouse long bones under dynamic mechanical loading. FASEB J, 2014, 28: 1582-1592
|
| [44] |
Evans SF, Parent JB, Lasko CE et al Periosteum, bone's "smart" bounding membrane, exhibits direction-dependent permeability. J Bone Miner Res, 2013, 28: 608-617
|
| [45] |
Lai X, Price C, Lu XL et al Imaging and quantifying solute transport across periosteum: implications for muscle-bone crosstalk. Bone, 2014, 66: 82-89
|
