Manipulating load-induced fluid flow in vivo to promote bone adaptation

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Meslier, Quentin A.¹; DiMauro, Nicole¹; Somanchi, Priya¹; Nano, Sarah¹; Shefelbine, Sandra J.^1,2

Manipulating load-induced fluid flow in vivo to promote bone adaptation

Bone. December 2022;165:116547

©2022 Elsevier Inc. All rights reserved.

Affiliations

¹Department of Bioengineering, Northeastern University, Boston, MA, USA

²Department of Mechanical and Industrial Engineering, Northeastern University, Boston, MA, USA
Abstract and keywords

Mechanical stimulation is critical to maintaining bone mass and strength. Strain has been commonly thought of as the mechanical stimulus driving bone adaptation. However, numerous studies have hypothesized that fluid flow in the lacunar-canalicular system plays a role in mechanoadaptation. The role of fluid flow compared to strain magnitude on bone remodeling has yet to be characterized. This study aimed to determine the contribution of fluid flow velocity compared to strain on bone adaptation. We used finite element modeling to design in vivo experiments, manipulating strain and fluid flow contributions. Using a uniaxial compression tibia model in mice, we demonstrated that high fluid flow velocity results in significant bone adaptation even under low strain magnitude. In contrast, high strain magnitude paired with low fluid velocity does not trigger a bone response. These findings support previous hypotheses stating that fluid flow is the principal mechanical stimulus driving bone adaptation. Moreover, they give new insights regarding bone adaptative response and provide new pathways toward treatment against age-related mechanosensitivity loss in bone.

Keywords: Bone adaptation; Axial tibia loading; Fluid flow velocity; Finite element modeling
Links

DOI: 10.1016/j.bone.2022.116547

PubMed: 36113842

WoS: 000864791800004
History

Received: 2022-07-20

Revised: 2022-09-01

Accepted: 2022-09-12

Online: 2022-09-14

Cited Works (32)

Year	Entry
2011	Lynch ME, Main RP, Xu Q, Schmicker TL, Schaffler MB, Wright TM, van der Meulen MCH. Tibial compression is anabolic in the adult mouse skeleton despite reduced responsiveness with aging. Bone. September 2011;49(3):439-446.
2011	Lambers FM, Schulte FA, Kuhn G, Webster DJ, Müller R. Mouse tail vertebrae adapt to cyclic mechanical loading by increasing bone formation rate and decreasing bone resorption rate as shown by time-lapsed in vivo imaging of dynamic bone morphometry. Bone. December 2011;49(6):1340-1350.
2003	Steck R, Niederer P, Knothe Tate ML. A finite element analysis for the prediction of load-induced fluid flow and mechanochemical transduction in bone. J Theo Biol. January 21, 2003;220(2):249-259.
2014	Birkhold AI, Razi H, Duda GN, Weinkamer R, Checa S, Willie BM. The influence of age on adaptive bone formation and bone resorption. Biomaterials. November 2014;35(34):9290-9301.
2000	Knothe Tate ML, Steck R, Forwood MR, Niederer P. In vivo demonstration of load-induced fluid flow in the rat tibia and its potential implications for processes associated with functional adaptation. J Exp Biol. September 2000;203(18):2737-2745.
1999	Cowin SC. Bone poroelasticity. J Biomech. March 1999;32(3):217-238.
2010	Doube M, Kłosowski MM, Arganda-Carreras I, Cordelières FP, Dougherty RP, Jackson JS, Schmid B, Hutchinson JR, Shefelbine SJ. BoneJ: free and extensible bone image analysis in ImageJ. Bone. December 2010;47(6):1076-1079.
1995	Turner CH, Owan I, Takano Y. Mechanotransduction in bone: role of strain rate. Am J Physiol Endocrinol Metab. September 1995;269(3):E438-E442.
1997	Gross TS, Edwards JL, Mcleod KJ, Rubin CT. Strain gradients correlate with sites of periosteal bone formation. J Bone Miner Res. June 1997;12(6):982-988.
2005	De Souza RL, Matsuura M, Eckstein F, Rawlinson SCF, Lanyon LE, Pitsillides AA. Non-invasive axial loading of mouse tibiae increases cortical bone formation and modifies trabecular organization: a new model to study cortical and cancellous compartments in a single loaded element. Bone. December 2005;37(6):810-818.
2013	Willie BM, Birkhold AI, Razi H, Thiele T, Aido M, Kruck B, Schill A, Checa S, Main RP, Duda GN. Diminished response to in vivo mechanical loading in trabecular and not cortical bone in adulthood of female C57Bl/6 mice coincides with a reduction in deformation to load. Bone. August 2013;55(2):335-346.
2005	Batra NN, Li YJ, Yellowley CE, You L, Malone AM, Kim CH, Jacobs CR. Effects of short-term recovery periods on fluid-induced signaling in osteoblastic cells. J Biomech. September 2005;38(9):1909-1917.
1982	O'Connor JA, Lanyon LE, MacFie H. The influence of strain rate on adaptive bone remodelling. J Biomech. 1982;15(10):767-781.
2012	Sugiyama T, Meakin LB, Browne WJ, Galea GL, Price JS, Lanyon LE. Bones' adaptive response to mechanical loading is essentially linear between the low strains associated with disuse and the high strains associated with the lamellar/woven bone transition. J Bone Miner Res. August 2012;27(8):1784-1793.
1987	Frost HM. Bone "mass" and the "mechanostat": a proposal. Anat Rec. September 1987;219(1):1-9.
1975	Reilly DT, Burstein AH. The elastic and ultimate properties of compact bone tissue. J Biomech. 1975;8(6):393-405.
2001	Hsieh Y, Robling AG, Ambrosius WT, Burr DB, Turner CH. Mechanical loading of diaphyseal bone in vivo: the strain threshold for an osteogenic response varies with location. J Bone Miner Res. December 2001;16(10):2291-2297.
1997	Mosley JR, March BM, Lynch J, Lanyon LE. Strain magnitude related changes in whole bone architecture in growing rats. Bone. March 1997;20(3):191-198.
2018	Gatti V, Azoulay EM, Fritton SP. Microstructural changes associated with osteoporosis negatively affect loading-induced fluid flow around osteocytes in cortical bone. J Biomech. January 3, 2018;66:127-136.
2014	Patel TK, Brodt MD, Silva MJ. Experimental and finite element analysis of strains induced by axial tibial compression in young-adult and old female C57Bl/6 mice. J Biomech. January 22, 2014;47(2):451-457.
2011	Price C, Zhou X, Li W, Wang L. 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. February 2011;26(2):277-285.
1994	Turner CH, Forwood MR, Otter MW. Mechanotransduction in bone: do bone cells act as sensors of fluid flow? FASEB J. August 1994;8(11):875-878.
1994	Weinbaum S, Cowin SC, Zeng Y. A model for the excitation of osteocytes by mechanical loading-induced bone fluid shear stresses. J Biomech. March 1994;27(3):339-360.
2014	Holguin N, Brodt MD, Sanchez ME, Silva MJ. Aging diminishes lamellar and woven bone formation induced by tibial compression in adult C57BL/6. Bone. August 2014;65:83-91.
2003	Srinivasan S, Agans SC, King KA, Moy NY, Poliachik SL, Gross TS. Enabling bone formation in the aged skeleton via rest-inserted mechanical loading. Bone. December 2003;33(6):946-955.
2001	Hsieh Y, Turner CH. Effects of loading frequency on mechanically induced bone formation. J Bone Miner Res. May 2001;16(5):918-924.
2000	You J, Yellowley CE, Donahue HJ, Zhang Y, Chen Q, Jacobs CR. Substrate deformation levels associated with routine physical activity are less stimulatory to bone cells relative to loading-induced oscillatory fluid flow. J Biomech Eng. August 2000;122(4):387-393.
2001	You L, Cowin SC, Schaffler MB, Weinbaum S. A model for strain amplification in the actin cytoskeleton of osteocytes due to fluid drag on pericellular matrix. J Biomech. November 2001;34(11):1375-1386.
2004	Warden SJ, Turner CH. Mechanotransduction in the cortical bone is most efficient at loading frequencies of 5–10 hz. Bone. February 2004;34(2):261-270.
1998	Mosley JR, Lanyon LE. Strain rate as a controlling influence on adaptive modeling in response to dynamic loading of the ulna in growing male rats. Bone. October 1998;23(4):313-318.
2001	Robling AG, Burr DB, Turner CH. Recovery periods restore mechanosensitivity to dynamically loaded bone. J Exp Biol. 2001;204(19):3389-3399.
2012	Moustafa A, Sugiyama T, Prasad J, Zaman G, Gross TS, Lanyon LE, Price JS. Mechanical loading-related changes in osteocyte sclerostin expression in mice are more closely associated with the subsequent osteogenic response than the peak strains engendered. Osteoporos Int. April 2012;23(4):1225-1234.