The mineral–collagen interface in bone

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The mineral–collagen interface in bone

Calcif Tiss Int. September 2015;97(3):262-280

©2015 Springer Science+Business Media New York

Affiliations

¹Department of Cell and Molecular Biology, Feinberg School of Medicine, Northwestern University, 303 E. Chicago Ave., Chicago, IL 60611-3008, USA
Abstract and keywords

The interface between collagen and the mineral reinforcement phase, carbonated hydroxyapatite (cAp), is essential for bone’s remarkable functionality as a biological composite material. The very small dimensions of the cAp phase and the disparate natures of the reinforcement and matrix are essential to the material’s performance but also complicate study of this interface. This article summarizes what is known about the cAp-collagen interface in bone and begins with descriptions of the matrix and reinforcement roles in composites, of the phases bounding the interface, of growth of cAp growing within the collagen matrix, and of the effect of intra- and extrafibrilar mineral on determinations of interfacial properties. Different observed interfacial interactions with cAp (collagen, water, non-collagenous proteins) are reviewed; experimental results on interface interactions during loading are reported as are their influence on macroscopic mechanical properties; conclusions of numerical modeling of interfacial interactions are also presented. The data suggest interfacial interlocking (bending of collagen molecules around cAp nanoplatelets) and water-mediated bonding between collagen and cAp are essential to load transfer. The review concludes with descriptions of areas where new research is needed to improve understanding of how the interface functions.

Keywords: Bone; Mineral–collagen interface; Apatite; Collagen; Non-collagenous proteins
Links

DOI: 10.1007/s00223-015-9984-6

PubMed: 25824581

WoS: 000359018600007
History

Received: 2015-01-06

Accepted: 2015-03-04

Online: 2015-04-01

Cited Works (63)

Year	Entry
1987	Lees S. Considerations regarding the structure of the mammalian mineralized osteoid from viewpoint of the generalized packing model. Connect Tissue Res. 1987;16(4):281-303.
1986	Weiner S, Price PA. Disaggregation of bone into crystals. Calcif Tiss Int. November 1986;39(6):365-375.
2006	Buehler MJ. Nature designs tough collagen: explaining the nanostructure of collagen fibrils. Proc Natl Acad Sci USA. August 15, 2006;103(33):12285-12290.
1985	Bonar LC, Lees S, Mook HA. Neutron diffraction studies of collagen in fully mineralized bone. J Mol Biol. 1985;181(2):265-270.
2002	Currey JD. Bones: Structure and Mechanics. Princeton, NJ: Princeton University Press; 2002.
1993	Landis WJ, Song MJ, Leith A, McEwen L, McEwen BF. Mineral and organic matrix interaction in normally calcifying tendon visualized in three dimensions by high-voltage electron microscopic tomography and graphic image reconstruction. J Struct Biol. January 1993;110(1):39-54.
2012	McNally EA, Schwarcz HP, Botton GA, Arsenault AL. A model for the ultrastructure of bone based on electron microscopy of ion-milled sections. PLoS One. January 17, 2012;7(1):e29258.
1999	Nanci A. Content and distribution of noncollagenous matrix proteins in bone and cementum: relationship to speed of formation and collagen packing density. J Struct Biol. June 30, 1999;126(3):256-269.
2011	Chen P-Y, Toroian D, Price PA, McKittrick J. Minerals form a continuum phase in mature cancellous bone. Calcif Tiss Int. May 2011;88(5):351-361.
2003	Roschger P, Gupta HS, Berzlanovich A, Ittner G, Dempster DW, Fratzl P, Cosman F, Parisien M, Lindsay R, Nieves JW, Klaushofer K. Constant mineralization density distribution in cancellous human bone. Bone. March 2003;32(3):316-323.
1995	Hulmes DJS, Wess TJ, Prockop DJ, Fratzl P. Radial packing, order, and disorder in collagen fibrils. Biophys J. May 1995;68(5):1661-1670.
2001	Thompson JB, Kindt JH, Drake B, Hansma HG, Morse DE, Hansma PK. Bone indentation recovery time correlates with bond reforming time. Nature. December 13, 2001;414(6865):773-776.
1994	Walsh WR, Guzelsu N. Compressive properties of cortical bone: mineral-organic interfacial bonding. Biomaterials. January 1994;15(2):137-145.
1998	Weiner S, Wagner HD. The material bone: structure-mechanical function relations. Ann Rev Mater Sci. August 1998;28:271-298.
2014	Gallant MA, Brown DM, Hammond M, Wallace JM, Du J, Deymier-Black AC, Almer JD, Stock SR, Allen MR, Burr DB. Bone cell-independent benefits of raloxifene on the skeleton: a novel mechanism for improving bone material properties. Bone. April 2014;61:191-200.
2003	Ascenzi M-G, Ascenzi A, Benvenuti A, Burghammer M, Panzavolta S, Bigid A. Structural differences between “dark” and “bright” isolated human osteonic lamellae. J Struct Biol. January 2003;141(1):22-33.
2015	Tang T, Ebacher V, Cripton P, Guy P, McKay H, Wang R. Shear deformation and fracture of human cortical bone. Bone. February 2015;71:25-35.
1991	Weiner S, Arad T, Traub W. Crystal organization in rat bone lamellae. FEBS Lett. July 1991;285(1):49-54.
1997	Weiner S, Arad T, Sabanay I, Traub. W. Rotated plywood structure of primary lamellar bone in the rat: orientations of the collagen fibril arrays. Bone. June 1997;20(6):509-514.
2013	Zysset PK, Dall'Ara E, Varga P, Pahr DH. Finite element analysis for prediction of bone strength. BoneKEy Rep. August 2013;2:386.
2011	Stock SR, Yuan F, Brinson LC, Almer JD. Internal strain gradients quantified in bone under load using high-energy x-ray scattering. J Biomech. January 11, 2011;44(2):291-296.
1997	Misof K, Landis WJ, Klaushofer K, Fratzl P. Collagen from the osteogenesis imperfecta mouse model (oim) shows reduced resistance against tensile stress. J Clin Invest. July 1997;100(1):40-45.
2001	Wang X, Bank RA, Tekoppele JM, Agrawal CM. The role of collagen in determining bone mechanical properties. J Orthop Res. 2001;19(6):1021-1026.
2007	Ruffoni D, Fratzl P, Roschger P, Klaushofer K, Weinkamer R. The bone mineralization density distribution as a fingerprint of the mineralization process. Bone. May 2007;40(5):1308-1319.
1992	Fratzl P, Groschner M, Vogl G, Plenk H Jr, Eschberger J, Fratzl-Zelman N, Koller K, Klaushofer K. Mineral crystals in calcified tissues: a comparative study by SAXS. J Bone Miner Res. March 1992;7(3):329-334.
2001	Lucchinetti E. Dense bone tissue as a molecular composite. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:chap 13.
1973	Evans FG. Mechanical Properties of Bone. Springfield, IL: Charles C. Thomas; 1973.
2005	Wilson EE, Awonusi A, Morris MD, Kohn DH, Tecklenburg MM, Beck LW. Highly ordered interstitial water observed in bone by nuclear magnetic resonance. J Bone Miner Res. 2005;20(4):625-634.
2014	Reznikov N, Shahar R, Weiner S. Bone hierarchical structure in three dimensions. Acta Biomater. September 2014;10(8):3815-3826.
1999	Baig AA, Fox JL, Young RA, Wang Z, Hsu J, Higuchi WI, Chhettry A, Zhuang H, Otsuka M. Relationships among carbonated apatite solubility, crystallite size, and microstrain parameters. Calcif Tiss Int. May 1999;64(5):437-449.
2010	Nudelman F, Pieterse K, George A, Bomans PHH, Friedrich H, Brylka LJ, Hilbers PAJ, de With G, Sommerdijk NAJM. The role of collagen in bone apatite formation in the presence of hydroxyapatite nucleation inhibitors. Nat Mater. December 2010;9(12):1004-1009.
1996	Mullender MG, van der Meer DD, Huiskes R, Lips P. Osteocyte density changes in aging and osteoporosis. Bone. February 1996;18(2):109-113.
1957	Eshelby JD. The determination of the elastic field of an ellipsoidal inclusion, and related problems. Proc R Soc Lon Ser-A. 1957;241(1226):376-396.
2006	Orgel JPRO, Irving TC, Miller A, Wess TJ. Microfibrillar structure of type I collagen in situ. Proc Natl Acad Sci USA. June 13, 2006;103(24):9001-9005.
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.
2005	Gupta HS, Wagermaier W, Zickler GA, Aroush DR-B, Funari SS, Roschger P, Wagner HD, Fratzl P. Nanoscale deformation mechanisms in bone. Nano Lett. October 2005;5(10):2108-2111.
1994	Ziv V, Weiner S. Bone crystal sizes: a comparison of transmission electron microscopic and x-ray diffraction line width broadening techniques. Connect Tissue Res. 1994;30(3):165-175.
2015	Reznikov N, Chase H, Brumfeld V, Shahar R, Weiner S. The 3D structure of the collagen fibril network in human trabecular bone: relation to trabecular organization. Bone. February 2015;71:189-195.
2000	Jäger I, Fratzl P. Mineralized collagen fibrils: a mechanical model with a staggered arrangement of mineral particles. Biophys J. October 2000;79(4):1737-1746.
2012	Bar-On B, Wagner HD. Elastic modulus of hard tissues. J Biomech. February 23, 2012;45(4):672-678.
2012	Poundarik AA, Diab T, Sroga GE, Ural A, Boskey AL, Gundberg CM, Vashishth D. Dilatational band formation in bone. Proc Natl Acad Sci USA. November 20, 2012;109(47):19178-19183.
2007	Fantner GE, Adams J, Turner P, Thurner PJ, Fisher LW, Hansma PK. Nanoscale ion mediated networks in bone: osteopontin can repeatedly dissipate large amounts of energy. Nano Lett. August 2007;7(8):2491-2498.
2008	Siegmund T, Allen MR, Burr DB. Failure of mineralized collagen fibrils: modeling the role of collagen cross-linking. J Biomech. 2008;41(7):1427-1435.
1999	Reilly GC, Currey JD. The development of microcracking and failure in bone depends on the loading mode to which it is adapted. J Exp Biol. 1999;202(5):543-552.
1996	Landis WJ, Hodgens KJ, Song MJ, Arena J, Kiyonaga S, Marko M, Owen C, McEwen BF. Mineralization of collagen may occur on fibril surfaces: evidence from conventional and high-voltage electron microscopy and three-dimensional imaging. J Struct Biol. July 1996;117(1):24-35.
2014	Reznikov N, Shahar R, Weiner S. Three-dimensional structure of human lamellar bone: the presence of two different materials and new insights into the hierarchical organization. Bone. February 2014;59:93-104.
1982	Gilmore RS, Katz JL. Elastic properties of apatites. J Mater Sci. 1982;17:1131-1141.
1926	de Jong WF. La substance minérale dans les os. Recueil des Travaux Chimiques des Pays-Bas. 1926;45(6):445-448.
2003	Jaschouz D, Paris O, Roschger P, Hwang H-S, Fratzl P. Pole figure analysis of mineral nanoparticle orientation in individual trabecula of human vertebral bone. J Appl Crystallogr. June 2003;36(1, pt 3):494-498.
1973	Katz EP, Li S-T. Structure and function of bone collagen fibrils. J Mol Biol. October 15, 1973;80(1):1-15.
2004	Akkus O, Adar F, Schaffler MB. Age-related changes in physicochemical properties of mineral crystals are related to impaired mechanical function of cortical bone. Bone. March 2004;34(4):443-453.
2006	Gupta HS, Seto J, Wagermaier W, Zaslansky P, Boesecke P, Fratzl P. Cooperative deformation of mineral and collagen in bone at the nanoscale. Proc Natl Acad Sci USA. November 21, 2006;103(47):17741-17746.
2002	Burr DB. The contribution of the organic matrix to bone's material properties. Bone. July 2002;31(1):8-11.
2005	Fantner GE, Hassenkam T, Kindt JH, Weaver JC, Birkedal H, Pechenik L, Cutroni JA, Cidade GAG, Stucky GD, Morse DE, Hansma PK. Sacrificial bonds and hidden length dissipate energy as mineralized fibrils separate during bone fracture. Nat Mater. August 2005;4(8):612-616.
1994	Currey JD, Brear K, Zioupos P. Dependence of mechanical properties on fibre angle in narwhal tusk, a highly oriented biological composite. J Biomech. July 1994;27(7):885-897.
2011	Dong XN, Almer JD, Wang X. Post-yield nanomechanics of human cortical bone in compression using synchrotron X-ray scattering techniques. J Biomech. February 24, 2011;44(4):676-682.
2007	Gupta HS, Fratzl P, Kerschnitzki M, Benecke G, Wagermaier W, Kirchner HOK. Evidence for an elementary process in bone plasticity with an activation enthalpy of 1 eV. J R Soc Interface. April 22, 2007;4(3):277-282.
2012	Vaughan TJ, McCarthy CT, McNamara LM. A three-scale finite element investigation into the effects of tissue mineralisation and lamellar organisation in human cortical and trabecular bone. J Mech Behav Biomed Mater. August 2012;12:50-62.
2007	Almer JD, Stock SR. Micromechanical response of mineral and collagen phases in bone. J Struct Biol. February 2007;157(2):365-370.
2005	Almer JD, Stock SR. Internal strains and stresses measured in cortical bone via high-energy X-ray diffraction. J Struct Biol. October 2005;152(1):14-27.
2004	Hassenkam T, Fantner G, Cutroni J, Weaver J, Morse D, Hansma P. High-resolution AFM imaging of intact and fractured trabecular bone. Bone. July 2004;35(1):4-10.
2003	Rubin MA, Jasiuk I, Taylor J, Rubin J, Ganey T, Apkarian RP. TEM analysis of the nanostructure of normal and osteoporotic human trabecular bone. Bone. March 2003;32(3):270-282.
2001	Lucchinetti E. Composite models of bone properties. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:chap 12.

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2019	Wittig NK, Palle J, Østergaard M, Frølich S, Birkbak ME, Spiers KM, Garrevoet J, Birkedal H. Bone biomineral properties vary across human osteonal bone. ACS Nano. 2019;13(11):12949-12956.
2020	Zioupos P, Kirchner HOK, Peterlik H. Ageing bone fractures: the case of a ductile to brittle transition that shifts with age. Bone. February 2020;131:115176.
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2020	Maghsoudi-Ganjeh M, Wang X, Zeng X. Nanomechanics and ultrastructure of bone: a review. Comput Model Eng Sci. 2020;125(1):1-32.
2018	Unal M, Creecy A, Nyman JS. The role of matrix composition in the mechanical behavior of bone. Curr Osteoporos Rep. June 2018;16(3):205-215.
2020	Törnquist E, Isaksson H, Turunen MJ. Mineralization of cortical bone during maturation and growth in rabbits. J Bone Min Metab. May 2020;38(3):289-298.
2016	Paschalis EP, Gamsjaeger S, Fratzl-Zelman N, Roschger P, Masic A, Brozek W, Hassler N, Glorieux FH, Rauch F, Klaushofer K, Fratzl P. Evidence for a role for nanoporosity and pyridinoline content in human mild osteogenesis imperfecta. J Bone Miner Res. May 2016;31(5):1050-1059.
2019	Hunt HB, Torres AM, Palomino PM, Marty E, Saiyed R, Cohn M, Jo J, Warner S, Sroga GE, King KB, Lane JM, Vashishth D, Hernandez CJ, Donnelly E. Altered tissue composition, microarchitecture, and mechanical performance in cancellous bone from men with type 2 diabetes mellitus. J Bone Miner Res. July 2019;34(7):1191-1206.
2021	Hunt HB, Miller NA, Hemmerling KJ, Koga M, Lopez KA, Taylor EA, Sellmeyer DE, Moseley KF, Donnelly E. Bone tissue composition in postmenopausal women varies with glycemic control from normal glucose tolerance to type 2 diabetes mellitus. J Bone Miner Res. February 2021;36(2):334-346.
2020	Maghsoudi-Ganjeh M, Wang X, Zeng X. Computational investigation of the effect of water on the nanomechanical behavior of bone. J Mech Behav Biomed Mater. January 2020;101:103454.
2016	Georgiadis M, Müller R, Schneider P. Techniques to assess bone ultrastructure organization: orientation and arrangement of mineralized collagen fibrils. J R Soc Interface. June 1, 2016;13(119):20160088.
2020	Törnquist E, Gentile L, Prévost S, Diaz A, Olsson U, Isaksson H. Comparison of small-angle neutron and X-ray scattering for studying cortical bone nanostructure. Sci Rep. 2020;10:14552.
2017	Unal M. Classification of Bound Water and Collagen Denaturation Status of Cortical Bone by Raman Spectroscopy [PhD thesis]. Cleveland, OH: Case Western Reserve University; January 2017.
2018	Guss JD. The Role of the Gut Microbiome in Bone and Joint [PhD thesis]. Ithaca, NY: Cornell University; December 2018.
2018	Hunt HB. Characterization of Material Properties, Microarchitecture, and Mechanics of Bone from Subjects With Type 2 Diabetes Mellitus [PhD thesis]. Ithaca, NY: Cornell University; December 2018.
2019	Groetsch A. Micro- and Nanomechanics of Mineralised Collagen Fibre Elasto-Plasticity [PhD thesis]. Ebinburgh, Scotland: Heriot-Watt University; November 2019.
2021	Törnquist E. Bone Structure Characterisation Using Neutron Scattering Techniques [PhD thesis]. Lund, Sweden: Lund University; 2021.
2019	Nobakhti S. Multiscale Characteristics of Bone Toughness [PhD thesis]. Northeastern University; July 2019.
2019	Heney AP. Effect of Fatigue-Induced Microdamage on the Compressive Properties of Bovine Trabecular Bone [Master's thesis]. Queen's University; September 2019.
2017	Ahsan AS. Effect of Intrafibrillar Mineralization on the Mechanical Properties of Osteogenesis Imperfecta Bone Using a Cohesive Finite Element Approach [Master's thesis]. San Antionio, TX: University of Texas at San Antonio; May 2017.
2017	Tilak K. Finite Element Simulation of Nanoindentation in Lamellar Bone Composites [Master's thesis]. San Antionio, TX: University of Texas at San Antonio; May 2017.
2020	Maghsoudi-Ganjeh M. Computational Investigation of Ultrastructural Behavior of Bone and Bone-Inspired Materials [PhD thesis]. San Antionio, TX: University of Texas at San Antonio; May 2020.
2022	Martel DR. Contributors to Proximal Femur Fracture Force: Multiscale Considerations of Rate, Toughness, and Bone Composition [PhD thesis]. University of Waterloo; 2022.
2018	Creecy A. Age- and Diabetes-Related Changes in the Matrix and Fracture Resistance of Bone [PhD thesis]. Nashville, TN: Vanderbilt University; August 10, 2018.