Modelling the mechanics of partially mineralized collagen fibrils, fibres and tissue

Progressive stiffening of collagen tissue by bioapatite mineral is important physiologically, but the details of this stiffening are uncertain. Unresolved questions about the details of the accommodation of bioapatite within and upon collagen's hierarchical structure have posed a central hurdle, but recent microscopy data resolve several major questions. These data suggest how collagen accommodates bioapatite at the lowest relevant hierarchical level (collagen fibrils), and suggest several possibilities for the progressive accommodation of bioapatite at higher hierarchical length scales (fibres and tissue). We developed approximations for the stiffening of collagen across spatial hierarchies based upon these data, and connected models across hierarchies levels to estimate mineralization-dependent tissue-level mechanics. In the five possible sequences of mineralization studied, percolation of the bioapatite phase proved to be an important determinant of the degree of stiffening by bioapatite. The models were applied to study one important instance of partially mineralized tissue, which occurs at the attachment of tendon to bone. All sequences of mineralization considered reproduced experimental observations of a region of tissue between tendon and bone that is more compliant than either tendon or bone, but the size and nature of this region depended strongly upon the sequence of mineralization. These models and observations have implications for engineered tissue scaffolds at the attachment of tendon to bone, bone development and graded biomimetic attachment of dissimilar hierarchical materials in general.

[1]  Guy M. Genin,et al.  Mineral Distributions at the Developing Tendon Enthesis , 2012, PloS one.

[2]  G. Genin,et al.  The nanometre-scale physiology of bone: steric modelling and scanning transmission electron microscopy of collagen–mineral structure , 2012, Journal of The Royal Society Interface.

[3]  Iwona M Jasiuk,et al.  Elastic modeling of bone at nanostructural level , 2012 .

[4]  Lester J. Smith,et al.  Tissue-Engineering Strategies for the Tendon/Ligament-to-Bone Insertion , 2012, Connective Tissue Research.

[5]  Roberto Ballarini,et al.  Viscoelastic properties of isolated collagen fibrils. , 2011, Biophysical journal.

[6]  J. McKittrick,et al.  Minerals Form a Continuum Phase in Mature Cancellous Bone , 2011, Calcified Tissue International.

[7]  Victor Birman,et al.  Fibrocartilage tissue engineering: the role of the stress environment on cell morphology and matrix expression. , 2011, Tissue engineering. Part A.

[8]  Alberto Redaelli,et al.  Hierarchical structure and nanomechanics of collagen microfibrils from the atomistic scale up. , 2011, Nano letters.

[9]  Sandra J Shefelbine,et al.  BoneJ: Free and extensible bone image analysis in ImageJ. , 2010, Bone.

[10]  P. Hilbers,et al.  The role of collagen in bone apatite formation in the presence of hydroxyapatite nucleation inhibitors. , 2010, Nature materials.

[11]  M. R. Dodge,et al.  In vitro fracture testing of submicron diameter collagen fibril specimens. , 2010, Biophysical journal.

[12]  Younan Xia,et al.  "Aligned-to-random" nanofiber scaffolds for mimicking the structure of the tendon-to-bone insertion site. , 2010, Nanoscale.

[13]  G. Genin,et al.  The development and morphogenesis of the tendon-to-bone insertion - what development can teach us about healing -. , 2010, Journal of musculoskeletal & neuronal interactions.

[14]  Yuye Tang,et al.  Deformation micromechanisms of collagen fibrils under uniaxial tension , 2009, Journal of The Royal Society Interface.

[15]  Y. Lanir,et al.  Recruitment viscoelasticity of the tendon. , 2009, Journal of biomechanical engineering.

[16]  David Saloner,et al.  A computationally efficient formal optimization of regional myocardial contractility in a sheep with left ventricular aneurysm. , 2009, Journal of biomechanical engineering.

[17]  Christian Hellmich,et al.  Ductile sliding between mineral crystals followed by rupture of collagen crosslinks: experimentally supported micromechanical explanation of bone strength. , 2009, Journal of theoretical biology.

[18]  T. Irving,et al.  On the packing structure of collagen: response to Okuyama et al.'s comment on Microfibrillar structure of type I collagen in situ , 2009 .

[19]  Victor Birman,et al.  Functional grading of mineral and collagen in the attachment of tendon to bone. , 2009, Biophysical journal.

[20]  Markus J. Buehler,et al.  Alpha-Helical Protein Networks Are Self-Protective and Flaw-Tolerant , 2009, PloS one.

[21]  Younan Xia,et al.  Nanofiber scaffolds with gradations in mineral content for mimicking the tendon-to-bone insertion site. , 2009, Nano letters.

[22]  Victor Birman,et al.  Micromechanics and Structural Response of Functionally Graded, Particulate-Matrix, Fiber-Reinforced Composites. , 2009, International journal of solids and structures.

[23]  Markus J Buehler,et al.  Deformation and failure of protein materials in physiologically extreme conditions and disease. , 2009, Nature materials.

[24]  Markus J Buehler,et al.  Nanomechanical strength mechanisms of hierarchical biological materials and tissues , 2008, Computer methods in biomechanics and biomedical engineering.

[25]  M. R. Dodge,et al.  Stress-strain experiments on individual collagen fibrils. , 2008, Biophysical journal.

[26]  A. Boyde,et al.  Composite bounds on the elastic modulus of bone. , 2008, Journal of biomechanics.

[27]  C. Hellmich,et al.  Micromechanics-Based Conversion of CT Data into Anisotropic Elasticity Tensors, Applied to FE Simulations of a Mandible , 2008, Annals of Biomedical Engineering.

[28]  P. Purslow,et al.  Ageing changes in the tensile properties of tendons: influence of collagen fibril volume fraction. , 2008, Journal of biomechanical engineering.

[29]  J. Pasteris,et al.  Bone and Tooth Mineralization: Why Apatite? , 2008 .

[30]  Elliot P. Douglas,et al.  Bone structure and formation: A new perspective , 2007 .

[31]  Richard Weinkamer,et al.  Nature’s hierarchical materials , 2007 .

[32]  Markus J. Buehler,et al.  Fracture mechanics of protein materials , 2007 .

[33]  Ralph Müller,et al.  Effects of thresholding techniques on microCT-based finite element models of trabecular bone. , 2007, Journal of biomechanical engineering.

[34]  Markus J. Buehler,et al.  Molecular nanomechanics of nascent bone: fibrillar toughening by mineralization , 2007 .

[35]  A. Palazoglu,et al.  Nanoscale heterogeneity promotes energy dissipation in bone. , 2007, Nature materials.

[36]  R. Okamoto,et al.  Modeling Cell and Matrix Anisotropy in Fibroblast Populated Collagen Vessels , 2007, Biomechanics and modeling in mechanobiology.

[37]  Christian Hellmich,et al.  'Universal' microstructural patterns in cortical and trabecular, extracellular and extravascular bone materials: micromechanics-based prediction of anisotropic elasticity. , 2007, Journal of theoretical biology.

[38]  Baohua Ji,et al.  Elastic properties of nanocomposite structure of bone , 2006 .

[39]  H. Kahn,et al.  Nano measurements with micro-devices: mechanical properties of hydrated collagen fibrils , 2006, Journal of The Royal Society Interface.

[40]  Jacqueline A. Cutroni,et al.  Sacrificial bonds and hidden length dissipate energy as mineralized fibrils separate during bone fracture , 2005, Nature materials.

[41]  Elliot L Elson,et al.  The relationship between cell and tissue strain in three-dimensional bio-artificial tissues. , 2005, Biophysical journal.

[42]  Elliot L Elson,et al.  Thin bio-artificial tissues in plane stress: the relationship between cell and tissue strain, and an improved constitutive model. , 2005, Biophysical journal.

[43]  Christian Hellmich,et al.  Mineral–collagen interactions in elasticity of bone ultrastructure – a continuum micromechanics approach , 2004 .

[44]  Matthew M Tomaino,et al.  Bi‐directional mechanical properties of the human forearm interosseous ligament , 2004, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[45]  Christian Hellmich,et al.  Can the diverse elastic properties of trabecular and cortical bone be attributed to only a few tissue-independent phase properties and their interactions? , 2004, Biomechanics and modeling in mechanobiology.

[46]  William D Middleton,et al.  The outcome and repair integrity of completely arthroscopically repaired large and massive rotator cuff tears. , 2004, The Journal of bone and joint surgery. American volume.

[47]  Stavros Thomopoulos,et al.  Variation of biomechanical, structural, and compositional properties along the tendon to bone insertion site. , 2003, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[48]  Christian Hellmich,et al.  Micromechanical Model for Ultrastructural Stiffness of Mineralized Tissues , 2002 .

[49]  M. Spector,et al.  The ultrastructure of anorganic bovine bone and selected synthetic hyroxyapatites used as bone graft substitute materials. , 2002, Biomaterials.

[50]  K A Derwin,et al.  A quantitative investigation of structure-function relationships in a tendon fascicle model. , 1999, Journal of biomechanical engineering.

[51]  S. Weiner,et al.  Lamellar bone: structure-function relations. , 1999, Journal of structural biology.

[52]  M Oyama,et al.  Identification of types II, IX and X collagens at the insertion site of the bovine achilles tendon. , 1998, Matrix biology : journal of the International Society for Matrix Biology.

[53]  J. Ralphs,et al.  Characterization of collagens and proteoglycans at the insertion of the human Achilles tendon. , 1998, Matrix biology : journal of the International Society for Matrix Biology.

[54]  R. Pidaparti,et al.  Bone mineral lies mainly outside collagen fibrils: predictions of a composite model for osteonal bone. , 1996, Journal of biomechanics.

[55]  J Kumagai,et al.  Immunohistochemical distribution of type I, II and III collagens in the rabbit supraspinatus tendon insertion. , 1994, Journal of anatomy.

[56]  V. Ingle,et al.  The loci of mineral in turkey leg tendon as seen by atomic force microscope and electron microscopy , 1994, Calcified Tissue International.

[57]  M. Glimcher,et al.  Three-dimensional spatial relationship between the collagen fibrils and the inorganic calcium phosphate crystals of pickerel (Americanus americanus) and herring (Clupea harengus) bone. , 1991, Journal of molecular biology.

[58]  S. Weiner,et al.  Three-dimensional ordered distribution of crystals in turkey tendon collagen fibers. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[59]  S. Safran,et al.  Continuum percolation of rods. , 1985, Physical review letters.

[60]  A. Miller Collagen: the organic matrix of bone. , 1984, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[61]  R. F. Ker Dynamic tensile properties of the plantaris tendon of sheep (Ovis aries). , 1981, The Journal of experimental biology.

[62]  V. Podrazký,et al.  Densities of collagen dehydrated by some organic solvents , 1966, Experientia.

[63]  G. Genin,et al.  Bi-material attachment through a compliant interfacial system at the tendon-to-bone insertion site. , 2012, Mechanics of materials : an international journal.

[64]  Victor Birman,et al.  Collagen fiber orientation at the tendon to bone insertion and its influence on stress concentrations. , 2006, Journal of biomechanics.

[65]  A Leith,et al.  Mineral and organic matrix interaction in normally calcifying tendon visualized in three dimensions by high-voltage electron microscopic tomography and graphic image reconstruction. , 1993, Journal of structural biology.

[66]  W. Landis,et al.  Topographic imaging of mineral and collagen in the calcifying turkey tendon. , 1991, Connective tissue research.

[67]  M. Glimcher The nature of the mineral component of bone and the mechanism of calcification. , 1987, Instructional course lectures.

[68]  N. E. Dorsey Properties of ordinary water-substance in all its phases : water-vapor, water, and all the ices , 1940 .