Relationships between degradability of silk scaffolds and osteogenesis.

Bone repairs represent a major focus in orthopedic medicine with biomaterials as a critical aspect of the regenerative process. However, only a limited set of biomaterials are utilized today and few studies relate biomaterial scaffold design to degradation rate and new bone formation. Matching biomaterial remodeling rate towards new bone formation is important in terms of the overall rate and quality of bone regeneration outcomes. We report on the osteogenesis and metabolism of human bone marrow derived mesenchymal stem cells (hMSCs) in 3D silk scaffolds. The scaffolds were prepared with two different degradation rates in order to study relationships between matrix degradation, cell metabolism and bone tissue formation in vitro. SEM, histology, chemical assays, real-time PCR and metabolic analyses were assessed to investigate these relationships. More extensively mineralized ECM formed in the scaffolds designed to degrade more rapidly, based on SEM, von Kossa and type I collagen staining and calcium content. Measures of osteogenic ECM were significantly higher in the more rapidly degrading scaffolds than in the more slowly degrading scaffolds over 56 days of study in vitro. Metabolic analysis, including glucose and lactate levels, confirmed the degradation rate differences with the two types of scaffolds, with the more rapidly degrading scaffolds supporting higher levels of glucose consumption and lactate synthesis by the hMSCs upon osteogenesis, in comparison to the more slowly degrading scaffolds. The results demonstrate that scaffold degradation rates directly impact the metabolism of hMSCs, and in turn the rate of osteogenesis. An understanding of the interplay between cellular metabolism and scaffold degradability should aid in the more rational design of scaffolds for bone regeneration needs both in vitro and in vivo.

[1]  K. Olbrich,et al.  Metabolic and Functional Characterization of Human Adipose-Derived Stem Cells in Tissue Engineering   , 2008, Plastic and reconstructive surgery.

[2]  David L Kaplan,et al.  Silk-based biomaterials. , 2003, Biomaterials.

[3]  A. Reddi,et al.  Changes in intracellular enzymes of collagen biosynthesis during matrix-induced cartilage and bone development. , 1981, Biochimica et biophysica acta.

[4]  J M García-Aznar,et al.  On scaffold designing for bone regeneration: A computational multiscale approach. , 2009, Acta biomaterialia.

[5]  Wee Keong Nah,et al.  The osteogenic differentiation of adipose tissue-derived precursor cells in a 3D scaffold/matrix environment. , 2008, Current drug discovery technologies.

[6]  D. Kaplan,et al.  Impact of collagen structure on matrix trafficking by human fibroblasts. , 2004, Journal of biomedical materials research. Part A.

[7]  Loomis Me,et al.  An enzymatic fluorometric method for the determination of lactic acid in serum. , 1961 .

[8]  M. Young Bone Matrix Proteins: More Than Markers , 2002, Calcified Tissue International.

[9]  J. Jansen,et al.  Ectopic bone formation in rat marrow stromal cell/titanium fiber mesh scaffold constructs: effect of initial cell phenotype. , 2005, Biomaterials.

[10]  Peter Dubruel,et al.  Quantitative screening of engineered implants in a long bone defect model in rabbits. , 2008, Tissue engineering. Part C, Methods.

[11]  David L Kaplan,et al.  Porous 3-D scaffolds from regenerated silk fibroin. , 2004, Biomacromolecules.

[12]  K. Anseth,et al.  Small functional groups for controlled differentiation of hydrogel-encapsulated human mesenchymal stem cells. , 2008, Nature materials.

[13]  A. Boccaccini,et al.  Biodegradable and bioactive porous polymer/inorganic composite scaffolds for bone tissue engineering. , 2006, Biomaterials.

[14]  Ung-Jin Kim,et al.  Three-dimensional aqueous-derived biomaterial scaffolds from silk fibroin. , 2005, Biomaterials.

[15]  D. Kaplan,et al.  In vivo degradation of three-dimensional silk fibroin scaffolds. , 2008, Biomaterials.

[16]  K. Olbrich,et al.  Effects of glutamine, glucose, and oxygen concentration on the metabolism and proliferation of rabbit adipose-derived stem cells. , 2006, Tissue engineering.

[17]  D J Mooney,et al.  Regulating Bone Formation via Controlled Scaffold Degradation , 2003, Journal of dental research.

[18]  W. Mutschler,et al.  Tissue engineering for bone defect healing: an update on a multi-component approach. , 2008, Injury.

[19]  V. Paralkar,et al.  Proline-rich tyrosine kinase 2 regulates osteoprogenitor cells and bone formation, and offers an anabolic treatment approach for osteoporosis , 2007, Proceedings of the National Academy of Sciences.

[20]  G. Stein,et al.  Development of the osteoblast phenotype: molecular mechanisms mediating osteoblast growth and differentiation. , 1995, The Iowa orthopaedic journal.

[21]  Filippo Causa,et al.  Bioactive scaffolds for bone and ligament tissue , 2007, Expert review of medical devices.

[22]  D. Burrin,et al.  Comparative aspects of tissue glutamine and proline metabolism. , 2008, The Journal of nutrition.

[23]  M. Hediger,et al.  Introduction: glutamate transport, metabolism, and physiological responses. , 1999, The American journal of physiology.

[24]  H. Yoshikawa,et al.  Oxygen tension is an important mediator of the transformation of osteoblasts to osteocytes , 2007, Journal of Bone and Mineral Metabolism.

[25]  Jochen Ringe,et al.  Stem cells for regenerative medicine: advances in the engineering of tissues and organs , 2002, Naturwissenschaften.

[26]  R. Smith Collagen and disorders of bone. , 1980, Clinical science.

[27]  F. Ismail-Beigi,et al.  Glucose uptake and lactate production in cells exposed to CoCl(2) and in cells overexpressing the Glut-1 glucose transporter. , 2002, Archives of biochemistry and biophysics.

[28]  D. Kaplan,et al.  Processing methods to control silk fibroin film biomaterial features , 2008 .

[29]  P. Prendergast,et al.  Gene expression by marrow stromal cells in a porous collagen–glycosaminoglycan scaffold is affected by pore size and mechanical stimulation , 2008, Journal of materials science. Materials in medicine.

[30]  S. Bryant,et al.  Hydrogel properties influence ECM production by chondrocytes photoencapsulated in poly(ethylene glycol) hydrogels. , 2002, Journal of biomedical materials research.

[31]  J. Mazumdar,et al.  Dynamics of the cell and its extracellular matrix - a simple mathematical approach , 2003, IEEE Transactions on NanoBioscience.

[32]  Wangdo Kim,et al.  An inverse method for predicting tissue-level mechanics from cellular mechanical input. , 2009, Journal of biomechanics.

[33]  M Navarro,et al.  Biomaterials in orthopaedics , 2008, Journal of The Royal Society Interface.

[34]  C. R. Howlett,et al.  The functional expression of human bone-derived cells grown on rapidly resorbable calcium phosphate ceramics. , 2004, Biomaterials.

[35]  C. R. Howlett,et al.  Effect of rapidly resorbable calcium phosphates and a calcium phosphate bone cement on the expression of bone-related genes and proteins in vitro. , 2004, Journal of biomedical materials research. Part A.

[36]  P. Trinder,et al.  Determination of blood glucose using an oxidase-peroxidase system with a non-carcinogenic chromogen , 1969, Journal of clinical pathology.

[37]  A. Jubel,et al.  Reduced collagen degradation in polytraumas with traumatic brain injury causes enhanced osteogenesis. , 2006, Journal of neurotrauma.

[38]  P. Steinberg,et al.  Alterations in the glycolytic and glutaminolytic pathways after malignant transformation of rat liver oval cells , 1999, Journal of cellular physiology.

[39]  M. Sefton,et al.  Tissue engineering. , 1998, Journal of cutaneous medicine and surgery.

[40]  Ung-Jin Kim,et al.  Bone tissue engineering with premineralized silk scaffolds. , 2008, Bone.

[41]  Kyongbum Lee,et al.  Extracellular matrix remodeling--methods to quantify cell-matrix interactions. , 2007, Biomaterials.

[42]  R. Reis,et al.  Materials in particulate form for tissue engineering. 2. Applications in bone , 2007, Journal of tissue engineering and regenerative medicine.

[43]  S. Einav,et al.  Adhesion molecule expression by osteogenic cells cultured on various biodegradable scaffolds. , 2005, Journal of biomedical materials research. Part A.

[44]  D. Mason Glutamate signalling and its potential application to tissue engineering of bone. , 2004, European cells & materials.

[45]  S. Kasugai,et al.  Temporal studies on the tissue compartmentalization of bone sialoprotein (BSP), osteopontin (OPN), and SPARC protein during bone formation In Vitro , 1992, Journal of cellular physiology.

[46]  Chengtie Wu,et al.  Improvement of mechanical and biological properties of porous CaSiO3 scaffolds by poly(D,L-lactic acid) modification. , 2008, Acta biomaterialia.

[47]  S. Cartmell Controlled release scaffolds for bone tissue engineering. , 2009, Journal of pharmaceutical sciences.

[48]  Antonios G Mikos,et al.  The influence of an in vitro generated bone-like extracellular matrix on osteoblastic gene expression of marrow stromal cells. , 2008, Biomaterials.

[49]  J. Phang,et al.  The metabolism of proline as microenvironmental stress substrate. , 2008, The Journal of nutrition.

[50]  Osteogenic Influence of Lysine in Porous Hydroxyapatite Scaffold , 2007 .

[51]  Irene Georgakoudi,et al.  Bone regeneration on macroporous aqueous-derived silk 3-D scaffolds. , 2007, Macromolecular bioscience.

[52]  W C Hayes,et al.  Evolution of bone transplantation: molecular, cellular and tissue strategies to engineer human bone. , 1996, Biomaterials.

[53]  J. Vacanti,et al.  Tissue engineering. , 1996, Seminars in pediatric surgery.

[54]  C. Giachelli,et al.  Osteopontin: a versatile regulator of inflammation and biomineralization. , 2000, Matrix biology : journal of the International Society for Matrix Biology.

[55]  Ralph Müller,et al.  Effect of scaffold design on bone morphology in vitro. , 2006, Tissue engineering.

[56]  M. Miloso,et al.  Mesenchymal stem cells cultured on a collagen scaffold: In vitro osteogenic differentiation. , 2007, Archives of oral biology.

[57]  J. Urban,et al.  Evidence for a negative Pasteur effect in articular cartilage. , 1997, The Biochemical journal.

[58]  Mingzhong Li,et al.  Enzymatic degradation behavior of porous silk fibroin sheets. , 2003, Biomaterials.

[59]  G. Semenza,et al.  Transcriptional regulation of genes encoding glycolytic enzymes by hypoxia-inducible factor 1. , 1994, The Journal of biological chemistry.

[60]  Ung-Jin Kim,et al.  Influence of macroporous protein scaffolds on bone tissue engineering from bone marrow stem cells. , 2005, Biomaterials.

[61]  Yuuki Imai,et al.  [The state and perspective in bone regeneration]. , 2008, Clinical calcium.

[62]  A. Giatromanolaki,et al.  Oxygen and glucose consumption in gastrointestinal adenocarcinomas: Correlation with markers of hypoxia, acidity and anaerobic glycolysis , 2006, Cancer science.

[63]  J. A. Sanz-Herrera,et al.  A mathematical approach to bone tissue engineering , 2009, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[64]  E. Pişkin,et al.  Biodegradable polymers as biomaterials. , 1995, Journal of biomaterials science. Polymer edition.

[65]  T. Skerry The role of glutamate in the regulation of bone mass and architecture. , 2008, Journal of musculoskeletal & neuronal interactions.

[66]  R. Diegelmann Analysis of collagen synthesis. , 2003, Methods in molecular medicine.

[67]  S A Cohen,et al.  Applications of amino acid derivatization with 6-aminoquinolyl-N-hydroxysuccinimidyl carbamate. Analysis of feed grains, intravenous solutions and glycoproteins. , 1994, Journal of chromatography. A.

[68]  D. Mooney,et al.  Hydrogels for tissue engineering: scaffold design variables and applications. , 2003, Biomaterials.

[69]  Sang-Hyug Park,et al.  Tissue-engineered cartilage using fibrin/hyaluronan composite gel and its in vivo implantation. , 2005, Artificial organs.

[70]  D. Bader,et al.  Rate of oxygen consumption by isolated articular chondrocytes is sensitive to medium glucose concentration , 2006, Journal of cellular physiology.

[71]  N. Lang,et al.  Temporal and local appearance of alkaline phosphatase activity in early stages of guided bone regeneration. A descriptive histochemical study in humans. , 2001, Clinical oral implants research.

[72]  Boon Chin Heng,et al.  Histological evaluation of osteogenesis of 3D-printed poly-lactic-co-glycolic acid (PLGA) scaffolds in a rabbit model , 2009, Biomedical materials.

[73]  T. Clemens,et al.  Activation of the hypoxia-inducible factor-1α pathway accelerates bone regeneration , 2008, Proceedings of the National Academy of Sciences.

[74]  A. Nerlich,et al.  Lysyl hydroxylation in collagens from hyperplastic callus and embryonic bones. , 1992, The Biochemical journal.

[75]  G. Semenza,et al.  Hypoxia-inducible factor 1: oxygen homeostasis and disease pathophysiology. , 2001, Trends in molecular medicine.

[76]  G. Stephanopoulos,et al.  Profiling of dynamic changes in hypermetabolic livers , 2003, Biotechnology and bioengineering.

[77]  A. Alford,et al.  Matricellular proteins: Extracellular modulators of bone development, remodeling, and regeneration. , 2006, Bone.

[78]  G. Stein,et al.  The developmental stages of osteoblast growth and differentiation exhibit selective responses of genes to growth factors (TGF beta 1) and hormones (vitamin D and glucocorticoids). , 1993, The Journal of oral implantology.