Porous scaffold architecture guides tissue formation

Critical‐sized bone defect regeneration is a remaining clinical concern. Numerous scaffold‐based strategies are currently being investigated to enable in vivo bone defect healing. However, a deeper understanding of how a scaffold influences the tissue formation process and how this compares to endogenous bone formation or to regular fracture healing is missing. It is hypothesized that the porous scaffold architecture can serve as a guiding substrate to enable the formation of a structured fibrous network as a prerequirement for later bone formation. An ovine, tibial, 30‐mm critical‐sized defect is used as a model system to better understand the effect of the scaffold architecture on cell organization, fibrous tissue, and mineralized tissue formation mechanisms in vivo. Tissue regeneration patterns within two geometrically distinct macroscopic regions of a specific scaffold design, the scaffold wall and the endosteal cavity, are compared with tissue formation in an empty defect (negative control) and with cortical bone (positive control). Histology, backscattered electron imaging, scanning small‐angle X‐ray scattering, and nanoindentation are used to assess the morphology of fibrous and mineralized tissue, to measure the average mineral particle thickness and the degree of alignment, and to map the local elastic indentation modulus. The scaffold proves to function as a guiding substrate to the tissue formation process. It enables the arrangement of a structured fibrous tissue across the entire defect, which acts as a secondary supporting network for cells. Mineralization can then initiate along the fibrous network, resulting in bone ingrowth into a critical‐sized defect, although not in complete bridging of the defect. The fibrous network morphology, which in turn is guided by the scaffold architecture, influences the microstructure of the newly formed bone. These results allow a deeper understanding of the mode of mineral tissue formation and the way this is influenced by the scaffold architecture. © 2012 American Society for Bone and Mineral Research.

[1]  T A Einhorn,et al.  The cell and molecular biology of fracture healing. , 1998, Clinical orthopaedics and related research.

[2]  Klaus Klaushofer,et al.  Nucleation and growth of mineral crystals in bone studied by small-angle X-ray scattering , 1991, Calcified Tissue International.

[3]  Celeste M Nelson,et al.  Geometric control of tissue morphogenesis. , 2009, Biochimica et biophysica acta.

[4]  F. Shapiro,et al.  Cortical bone repair. The relationship of the lacunar-canalicular system and intercellular gap junctions to the repair process. , 1988, The Journal of bone and joint surgery. American volume.

[5]  Dietmar W Hutmacher,et al.  Combined marrow stromal cell-sheet techniques and high-strength biodegradable composite scaffolds for engineered functional bone grafts. , 2007, Biomaterials.

[6]  Dietmar Werner Hutmacher,et al.  State of the art and future directions of scaffold‐based bone engineering from a biomaterials perspective , 2007, Journal of tissue engineering and regenerative medicine.

[7]  Paul Roschger,et al.  Size and habit of mineral particles in bone and mineralized callus during bone healing in sheep , 2010, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[8]  Yilin Cao,et al.  Tissue-engineered bone repair of goat-femur defects with osteogenically induced bone marrow stromal cells. , 2006, Tissue engineering.

[9]  Peter Patka,et al.  Healing of segmental bone defects with granular porous hydroxyapatite augmented with recombinant human osteogenic protein‐I or autologous bone marrow , 2003, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[10]  Scott J Hollister,et al.  The pore size of polycaprolactone scaffolds has limited influence on bone regeneration in an in vivo model. , 2010, Journal of biomedical materials research. Part A.

[11]  L. Claes,et al.  Bone formation in a long bone defect model using a platelet-rich plasma-loaded collagen scaffold. , 2006, Biomaterials.

[12]  David J Mooney,et al.  Quantitative assessment of scaffold and growth factor‐mediated repair of critically sized bone defects , 2007, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[13]  F. Shapiro,et al.  Bone development and its relation to fracture repair. The role of mesenchymal osteoblasts and surface osteoblasts. , 2008, European cells & materials.

[14]  David J Mooney,et al.  An alginate-based hybrid system for growth factor delivery in the functional repair of large bone defects. , 2011, Biomaterials.

[15]  I. Yannas Similarities and differences between induced organ regeneration in adults and early foetal regeneration , 2005, Journal of The Royal Society Interface.

[16]  J O Hollinger,et al.  The critical size defect as an experimental model for craniomandibulofacial nonunions. , 1986, Clinical orthopaedics and related research.

[17]  D. Hutmacher,et al.  Scaffolds in tissue engineering bone and cartilage. , 2000, Biomaterials.

[18]  R. Brentani,et al.  Picrosirius staining plus polarization microscopy, a specific method for collagen detection in tissue sections , 1979, The Histochemical Journal.

[19]  U. Schwarz,et al.  Cell organization in soft media due to active mechanosensing , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[20]  Ralph Müller,et al.  Repair of bone defects using synthetic mimetics of collagenous extracellular matrices , 2003, Nature Biotechnology.

[21]  C Perka,et al.  Segmental bone repair by tissue-engineered periosteal cell transplants with bioresorbable fleece and fibrin scaffolds in rabbits. , 2000, Biomaterials.

[22]  S. Ichinose,et al.  Fresh bone marrow introduction into porous scaffolds using a simple low‐pressure loading method for effective osteogenesis in a rabbit model , 2009, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[23]  Robert E Guldberg,et al.  Differences between in vitro viability and differentiation and in vivo bone-forming efficacy of human mesenchymal stem cells cultured on PCL-TCP scaffolds. , 2010, Biomaterials.

[24]  Yilin Cao,et al.  Repair of goat tibial defects with bone marrow stromal cells and β-tricalcium phosphate , 2008, Journal of materials science. Materials in medicine.

[25]  V. Bousson,et al.  Long‐bone critical‐size defects treated with tissue‐engineered grafts: A study on sheep , 2007, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[26]  Thomas A Einhorn,et al.  Fracture healing as a post‐natal developmental process: Molecular, spatial, and temporal aspects of its regulation , 2003, Journal of cellular biochemistry.

[27]  Aaron Schindeler,et al.  Bone remodeling during fracture repair: The cellular picture. , 2008, Seminars in cell & developmental biology.

[28]  T. Gao,et al.  Morphological and biomechanical difference in healing in segmental tibial defects implanted with Biocoral or tricalcium phosphate cylinders. , 1997, Biomaterials.

[29]  E Bell,et al.  Production of a tissue-like structure by contraction of collagen lattices by human fibroblasts of different proliferative potential in vitro. , 1979, Proceedings of the National Academy of Sciences of the United States of America.

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

[31]  Hee-Kit Wong,et al.  Biological performance of a polycaprolactone-based scaffold used as fusion cage device in a large animal model of spinal reconstructive surgery. , 2009, Biomaterials.

[32]  S. Ramakrishna,et al.  Biomedical applications of polymer-composite materials: a review , 2001 .

[33]  G. Porod Die Röntgenkleinwinkelstreuung von dichtgepackten kolloiden Systemen , 1953 .

[34]  A. Mata,et al.  Hybrid bone implants: self-assembly of peptide amphiphile nanofibers within porous titanium. , 2008, Biomaterials.

[35]  S. Mundlos,et al.  Fetal and postnatal mouse bone tissue contains more calcium than is present in hydroxyapatite. , 2011, Journal of structural biology.

[36]  Andrés J. García,et al.  Human stem cell delivery for treatment of large segmental bone defects , 2010, Proceedings of the National Academy of Sciences.

[37]  P. Fratzl,et al.  Scanning Small Angle X-ray Scattering Analysis of Human Bone Sections , 1999, Calcified Tissue International.

[38]  D. Lickorish,et al.  A three-phase, fully resorbable, polyester/calcium phosphate scaffold for bone tissue engineering: Evolution of scaffold design. , 2007, Biomaterials.

[39]  M. Mastrogiacomo,et al.  Regeneration of large bone defects in sheep using bone marrow stromal cells , 2008, Journal of tissue engineering and regenerative medicine.

[40]  Scott J. Hollister,et al.  Hierarchical bioactive materials for tissue reconstruction: Integrated design and manufacturing challenges , 2011 .

[41]  G. Pharr,et al.  An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments , 1992 .

[42]  D W Hutmacher,et al.  The stimulation of healing within a rat calvarial defect by mPCL-TCP/collagen scaffolds loaded with rhBMP-2. , 2009, Biomaterials.

[43]  M J Glimcher,et al.  Bone biology. II: Formation, form, modeling, remodeling, and regulation of cell function. , 1996, Instructional course lectures.

[44]  P. Fratzl,et al.  Poorly Ordered Bone as an Endogenous Scaffold for the Deposition of Highly Oriented Lamellar Tissue in Rapidly Growing Ovine Bone , 2011, Cells Tissues Organs.

[45]  Huipin Yuan,et al.  BIOMATERIALS : CURRENT KNOWLEDGE OF PROPERTIES , EXPERIMENTAL MODELS AND BIOLOGICAL MECHANISMS , 2011 .

[46]  Takaaki Tanaka,et al.  Repair of segmental bone defects in rabbit tibiae using a complex of beta-tricalcium phosphate, type I collagen, and fibroblast growth factor-2. , 2006, Biomaterials.

[47]  Federica Chiellini,et al.  Polymeric Materials for Bone and Cartilage Repair , 2010 .

[48]  Georg N Duda,et al.  The organization of the osteocyte network mirrors the extracellular matrix orientation in bone. , 2011, Journal of structural biology.

[49]  Michael A K Liebschner,et al.  Biomechanical considerations of animal models used in tissue engineering of bone. , 2004, Biomaterials.

[50]  J. van den Dolder,et al.  Bone regenerative properties of injectable PGLA–CaP composite with TGF‐β1 in a rat augmentation model , 2007, Journal of tissue engineering and regenerative medicine.

[51]  M. Mastrogiacomo,et al.  Reconstruction of extensive long bone defects in sheep using resorbable bioceramics based on silicon stabilized tricalcium phosphate. , 2006, Tissue engineering.

[52]  Donald E Ingber,et al.  Mechanical control of tissue growth: function follows form. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[53]  M. Mochizuki,et al.  Long-term stability of bone tissues induced by an osteoinductive biomaterial, recombinant human bone morphogenetic protein-2 and a biodegradable carrier. , 2004, Biomaterials.

[54]  T. Gerhart,et al.  Healing Bone Using Recombinant Human Bone Morphogenetic Protein 2 and Copolymer , 1998, Clinical orthopaedics and related research.

[55]  F. Bloemers,et al.  Autologous bone versus calcium-phosphate ceramics in treatment of experimental bone defects. , 2003, Journal of biomedical materials research. Part B, Applied biomaterials.

[56]  A. Meunier,et al.  Tissue-engineered bone regeneration , 2000, Nature Biotechnology.

[57]  Sheila J. Jones,et al.  Aspects of Anatomy and Development of Bone: the nm, μm and mm Hierarchy , 1998 .

[58]  T Jämsä,et al.  Enhanced healing of segmental tibial defects in sheep by a composite bone substitute composed of tricalcium phosphate cylinder, bone morphogenetic protein, and type IV collagen. , 1996, Journal of biomedical materials research.

[59]  P. Fratzl,et al.  Spatial and temporal variations of mechanical properties and mineral content of the external callus during bone healing. , 2009, Bone.

[60]  S. Hollister Porous scaffold design for tissue engineering , 2005, Nature materials.

[61]  Ralph Müller,et al.  Nondestructive micro-computed tomography for biological imaging and quantification of scaffold-bone interaction in vivo. , 2007, Biomaterials.

[62]  A L Boskey,et al.  Mineral-matrix interactions in bone and cartilage. , 1992, Clinical orthopaedics and related research.

[63]  Maurilio Marcacci,et al.  Stem cells associated with macroporous bioceramics for long bone repair: 6- to 7-year outcome of a pilot clinical study. , 2007, Tissue engineering.