Review: bone tissue engineering: the role of interstitial fluid flow

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Hillsley, M. V.¹; Frangos, J. A.¹

Review: bone tissue engineering: the role of interstitial fluid flow

Biotechnol Bioeng. March 25, 1994;43(7):573-581

©1994 John Wiley & Sons, Inc.

Affiliations

¹Department of Chemical Engineering, The Pennsylvania State University, University Park, Pennsylvania 16802
Abstract and keywords

It is well established that vascularization is required for effective bone healing. This implies that blood flow and interstitial fluid (ISF) flow are required for healing and maintenance of bone. The fact that changes in bone blood flow and ISF flow are associated with changes in bone remodeling and formation support this theory. ISF flow in bone results from transcortical pressure gradients produced by vascular and hydrostatic pressure, and mechanical loading. Conditions observed to alter flow rates include increases in venous pressure in hypertension, fluid shifts occurring in bedrest and microgravity, increases in vascularization during the injury-healing response, and mechanical compression and bending of bone during exercise. These conditions also induce changes in bone remodeling. Previously, we hypothesized that interstitial fluid flow in bone, and in particular fluid shear stress, serves to mediate signal transduction in mechanical loading- and injury-induced remodeling. In addition, we proposed that a lack or decrease of ISF flow results in the bone loss observed in disuse and microgravity. The purpose of this article is to review ISF flow in bone and its role in osteogenesis.

Keywords: bone; bone remodeling; bone interstitial fluid flow; fluid shear stress; osteoblasts
Links

DOI: 10.1002/bit.260430706

PubMed: 11540959

WoS: A1994MY10200005
History

Received: 1993-06-09

Accepted: 1993-08-16

Cited Works (22)

Year	Entry
1990	Kufahl RH, Saha S. A theoretical model for stress-generated fluid flow in the canaliculi-lacunae network in bone tissue. J Biomech. 1990;23(2):171-180.
1988	Montgomery RJ, Sutker BD, Bronk JT, Smith SR, Kelly PJ. Interstitial fluid flow in cortical bone. Microvasc Res. May 1988;35(3):295-307.
1992	Buschmann MD, Gluzband YA, Grodzinsky AJ, Kimura JH, Hunziker EB. Chondrocytes in agarose culture synthesize a mechanically functional extracellular matrix. J Orthop Res. November 1992;10(6):745-758.
1970	Donaldson CL, Hulley SB, Vogel JM, Hattner RS, Bayers JH, McMillan DE. Effect of prolonged bed rest on bone mineral. Metabolism. December 1970;19(12):1071-1084.
1991	Reich KM, Frangos JA. Effect of flow on prostaglandin E₂ and inositol trisphosphate levels in osteoblasts. Am J Physiol. September 1991;261(3):C428-C432.
1990	Reich KM, Gay CV, Frangos JA. Fluid shear stress as a mediator of osteoblast cyclic adenosine monophosphate production. J Cell Physiol. April 1990;143(1):100-103.
1993	Reich KM, Frangos JA. Protein kinase C mediates flow-induced prostaglandin E₂ production in osteoblasts. Calcif Tiss Int. January 1993;52(1):62-66.
1991	Cowin SC, Moss-Salentijn L, Moss ML. Candidates for the mechanosensory system in bone. J Biomech Eng. May 1991;113(2):191-197.
1977	Piekarski K, Munro M. Transport mechanism operating between blood supply and osteocytes in long bones. Nature. September 1, 1977;270(5623):80-82.
1988	Frost HM. Vital biomechanics: proposed general concepts for skeletal adaptations to mechanical usage. Calcif Tiss Int. May 1988;42(3):145-156.
1981	Doty SB. Morphological evidence of gap junctions between bone cells. Calcif Tiss Int. 1981;33(5):509-512.
1968	Anderson JC, Eriksson C. Electrical properties of wet collagen. Nature. April 13, 1968;218(5137):166-168.
1990	Murray DW, Rushton N. The effect of strain on bone cell prostaglandin E₂ release: a new experimental method. Calcif Tiss Int. July 1990;47(1):35-39.
1991	Dillaman RM, Roer RD, Gay DM. Fluid movement in bone: theoretical and empirical. J Biomech. 1991;24(suppl 1):163-177.
1985	Frangos JA, Eskin SG, McIntire LV, Ives CL. Flow effects on prostacyclin production by cultured human endothelial cells. Science. March 22, 1985;227(4693):1477-1479.
1984	Binderman I, Shimshoni Z, Somjen D. Biochemical pathways involved in the translation of physical stimulus into biological message. Calcif Tiss Int. March 1984;36(1):S82-S85.
1985	Rubin CT, Lanyon LE. Regulation of bone mass by mechanical strain magnitude. Calcif Tiss Int. 1985;37(4):411-417.
1984	Rubin CT, Lanyon LE. Regulation of bone formation by applied dynamic loads. J Bone Joint Surg. March 1984;66A(3):397-402.
1993	Langer R, Vacanti JP. Tissue engineering. Science. May 14, 1993;260(5110):920-926.
1982	Gross D, Williams WS. Streaming potential and the electromechanical response of physiologically-moist bone. J Biomech. 1982;15(4):277-295.
1987	Salzstein RA, Pollack SR, Mak AFT, Petrov N. Electromechanical potentials in cortical bone, I: a continuum approach. J Biomech. 1987;20(3):261-270.
1892	Wolff J. Das Gesetz der Transformation der Knochen. Berlin: Hirschwald; 1892.

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2013	Hum JM. Signaling Mechanisms That Suppress the Anabolic Response of Osteoblasts and Osteocytes to Fluid Shear Stress [PhD thesis]. Bloomington, IN: Indiana University; September 2013.
1996	Johnson DL, McAllister TN, Frangos JA. Fluid flow stimulates rapid and continuous release of nitric oxide in osteoblasts. Am J Physiol Endocrinol Metab. July 1996;271(1):E205-E208.
1997	Smalt R, Mitchell FT, Howard RL, Chambers TJ. Induction of NO and prostaglandin E₂ in osteoblasts by wall-shear stress but not mechanical strain. Am J Physiol Endocrinol Metab. October 1997;273(4):E751-E758.
2002	Qin Y-X, Lin W, Rubin C. The pathway of bone fluid flow as defined by in vivo intramedullary pressure and streaming potential measurements. Ann Biomed Eng. May 2002;30(5):693-702.
2009	Fritton SP, Weinbaum S. Fluid and solute transport in bone: flow-induced mechanotransduction. Annu Rev Fluid Mech. 2009;41:347-374.
2000	Hutmacher DW. Scaffolds in tissue engineering bone and cartilage. Biomaterials. December 15, 2000;21(24):2529-2543.
2001	Sikavitsas VI, Temenoff JS, Mikos AG. Biomaterials and bone mechanotransduction. Biomaterials. October 2001;22(19):2581-2593.
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.
2003	Kapur S, Baylink DJ, William Lau K-H. Fluid flow shear stress stimulates human osteoblast proliferation and differentiation through multiple interacting and competing signal transduction pathways. Bone. March 2003;32(3):241-251.
2004	Wang L, Ciani C, Doty SB, Fritton SP. Delineating bone's interstitial fluid pathway in vivo. Bone. March 2004;34(3):499-509.
2003	Qin Y-X, Kaplan T, Saldanha A, Rubin C. Fluid pressure gradients, arising from oscillations in intramedullary pressure, is correlated with the formation of bone and inhibition of intracortical porosity. J Biomech. October 2003;36(10):1427-1437.
2006	Beno T, Yoon Y-J, Cowin SC, Fritton SP. Estimation of bone permeability using accurate microstructural measurements. J Biomech. 2006;39(13):2378-2387.
2000	Noble BS, Reeve J. Osteocyte function, osteocyte death and bone fracture resistance. Mol Cell Endocrinol. January 25, 2000;159(1-2):7-13.
2002	Wang L. Investigating the Role of Interstitial Fluid Flow in Bone Adaptation and Metabolism [PhD thesis]. New York, NY: The City University of New York; 2002.
2004	Mi LY. Analysis of Avian Bone Response to Mechanical Loading Using a Computational Connected Network [PhD thesis]. New York, NY: The City College of New York; 2004.
2004	Thi MM. Cellular Communication and Mechanotransduction in Response to Fluid Shear Stress [PhD thesis]. New York, NY: The City University of New York; 2004.
2008	Ciani C. Characterization of Microporosities and Load-Induced Interstitial Fluid Movement in Normal and Osteopenic Bone [PhD thesis]. New York, NY: The City University of New York; 2008.
2017	Shah AD. Elucidating the Effects of Interstitial Fluid Flow on Hepatocellular Carcinoma Invasion [PhD thesis]. Drexel University; June 2017.
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2004	McMullen RA. An in Vitro Investigation of MC3T3-E1 Osteoblast Proliferation and Differentiation on Hydroxyapatite Based Tissue-Engineered Scaffolds [Master's thesis]. East Lansing, MI: Michigan State University; 2004.
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2005	McGarry JG. Computational and Experimental Investigation of Bone Cell Response to Mechanical Stimuli [PhD thesis]. Trinity College Dublin; September 2005.
2006	Dupree MA. Induction of Osteoblastic Proliferation and Phenotype Development With Fibroblast Growth Factor 2: A Kinetic and Tissue Culture Evaluation of in Vitro Response in Two and Three Dimensions [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2006.
2001	Parsamian GP. Damage Mechanics of Human Cortical Bone [PhD thesis]. Morgantown, WV: West Virginia University; 2001.