Dynamic loading stimulates chondrocyte biosynthesis when encapsulated in charged hydrogels prepared from poly(ethylene glycol) and chondroitin sulfate.

This study aimed to elucidate the role of charge in mediating chondrocyte response to loading by employing synthetic 3D hydrogels. Specifically, neutral poly(ethylene glycol) (PEG) hydrogels were employed where negatively charged chondroitin sulfate (ChS), one of the main extracellular matrix components of cartilage, was systematically incorporated into the PEG network at 0%, 20% or 40% to control the fixed charge density. PEG hydrogels were employed as a control environment for extracellular events which occur as a result of loading, but which are not associated with a charged matrix (e.g., cell deformation and fluid flow). Freshly isolated bovine articular chondrocytes were embedded in the hydrogels and subject to dynamic mechanical stimulation (0.3Hz, 15% amplitude strains, 6h) and assayed for nitric oxide production, cell proliferation, proteoglycan synthesis, and collagen deposition. In the absence of loading, incorporation of charge inhibited cell proliferation by approximately 75%, proteoglycan synthesis by approximately 22-50% depending on ChS content, but had no affect on collagen deposition. Dynamic loading had no effect on cellular responses in PEG hydrogels. However, dynamically loading 20% ChS gels inhibited nitrite production by 50%, cell proliferation by 40%, but stimulated proteoglycan and collagen deposition by 162% and 565%, respectively. Dynamic loading of 40% ChS hydrogels stimulated nitrite production by 62% and proteoglycan synthesis by 123%, but inhibited cell proliferation by 54% and collagen deposition by 52%. Upon removing the load and culturing under free-swelling conditions for 36h, the enhanced matrix synthesis observed in the 20% ChS gels was not maintained suggesting that loading is necessary to stimulate matrix production. In conclusion, extracellular events associated with a charged matrix have a dramatic affect on how chondrocytes respond to mechanical stimulation within these artificial 3D matrices suggesting that streaming potentials and/or dynamic changes in osmolarity may be important regulators of chondrocytes while cell deformation and fluid flow appear to have less of an effect.

[1]  S. Bryant,et al.  Crosslinking Density Influences Chondrocyte Metabolism in Dynamically Loaded Photocrosslinked Poly(ethylene glycol) Hydrogels , 2004, Annals of Biomedical Engineering.

[2]  V C Mow,et al.  The extracellular matrix, interstitial fluid and ions as a mechanical signal transducer in articular cartilage. , 1999, Osteoarthritis and cartilage.

[3]  A. Maroudas,et al.  The correlation of fixed negative charge with glycosaminoglycan content of human articular cartilage. , 1969, Biochimica et biophysica acta.

[4]  Kristi S. Anseth,et al.  Synthesis and Characterization of Photopolymerized Multifunctional Hydrogels: Water-Soluble Poly(Vinyl Alcohol) and Chondroitin Sulfate Macromers for Chondrocyte Encapsulation , 2004 .

[5]  F. Guilak,et al.  Hyper-osmotic stress induces volume change and calcium transients in chondrocytes by transmembrane, phospholipid, and G-protein pathways. , 2001, Journal of biomechanics.

[6]  Clark T Hung,et al.  Chondrocyte intracellular calcium, cytoskeletal organization, and gene expression responses to dynamic osmotic loading. , 2006, American journal of physiology. Cell physiology.

[7]  S. Bryant,et al.  Cell encapsulation in biodegradable hydrogels for tissue engineering applications. , 2008, Tissue engineering. Part B, Reviews.

[8]  M. Grinstaff,et al.  Photocrosslinkable polysaccharides for in situ hydrogel formation. , 2001, Journal of biomedical materials research.

[9]  F. Lang,et al.  Cell Volume in the Regulation of Cell Proliferation and Apoptotic Cell Death , 2001, Cellular Physiology and Biochemistry.

[10]  Christine Ortiz,et al.  Compressive nanomechanics of opposing aggrecan macromolecules. , 2006, Journal of biomechanics.

[11]  J. Urban,et al.  Regulation of matrix synthesis rates by the ionic and osmotic environment of articular chondrocytes , 1993, Journal of cellular physiology.

[12]  D. Bader,et al.  Dynamic compression inhibits the synthesis of nitric oxide and PGE(2) by IL-1beta-stimulated chondrocytes cultured in agarose constructs. , 2001, Biochemical and biophysical research communications.

[13]  A. Grodzinsky,et al.  Molecular-Level Theoretical Model for Electrostatic Interactions within Polyelectrolyte Brushes: Applications to Charged Glycosaminoglycans , 2003 .

[14]  Petro Julkunen,et al.  Collagen Network of Articular Cartilage Modulates Fluid Flow and Mechanical Stresses in Chondrocyte , 2006, Biomechanics and modeling in mechanobiology.

[15]  L. Bonassar,et al.  The role of cartilage streaming potential, fluid flow and pressure in the stimulation of chondrocyte biosynthesis during dynamic compression. , 1995, Journal of biomechanics.

[16]  Jun Wang,et al.  Photocrosslinkable polysaccharides based on chondroitin sulfate. , 2004, Journal of biomedical materials research. Part A.

[17]  S J Bryant,et al.  Static and dynamic compressive strains influence nitric oxide production and chondrocyte bioactivity when encapsulated in PEG hydrogels of different crosslinking densities. , 2008, Osteoarthritis and cartilage.

[18]  E. Thonar,et al.  Quantification of 35S-labeled proteoglycans complexed to alcian blue by rapid filtration in multiwell plates. , 1994, Analytical biochemistry.

[19]  E. Hay,et al.  Cell Biology of Extracellular Matrix , 1988, Springer US.

[20]  P. Savard,et al.  Detection and analysis of cartilage degeneration by spatially resolved streaming potentials , 2002, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[21]  A. Grodzinsky,et al.  Proteoglycan deposition around chondrocytes in agarose culture: construction of a physical and biological interface for mechanotransduction in cartilage. , 2002, Biorheology.

[22]  S. Moncada,et al.  Endogenous nitric oxide: physiology, pathology and clinical relevance , 1991, European journal of clinical investigation.

[23]  W M Lai,et al.  Transport of fluid and ions through a porous-permeable charged-hydrated tissue, and streaming potential data on normal bovine articular cartilage. , 1993, Journal of biomechanics.

[24]  V. Mow,et al.  The functional environment of chondrocytes within cartilage subjected to compressive loading: a theoretical and experimental approach. , 2002, Biorheology.

[25]  S. Bryant,et al.  Medium osmolarity and pericellular matrix development improves chondrocyte survival when photoencapsulated in poly(ethylene glycol) hydrogels at low densities. , 2009, Tissue engineering. Part A.

[26]  A. Grodzinsky,et al.  Biosynthetic response of cartilage explants to dynamic compression , 1989, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[27]  J. Caron,et al.  Glucosamine and chondroitin sulfate regulate gene expression and synthesis of nitric oxide and prostaglandin E(2) in articular cartilage explants. , 2005, Osteoarthritis and cartilage.

[28]  V. Mow,et al.  Chondrocyte deformation and local tissue strain in articular cartilage: A confocal microscopy study , 1995, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[29]  Mutsumi Takagi,et al.  Effect of chondroitin sulfate and hyaluronic acid on gene expression in a three-dimensional culture of chondrocytes. , 2005, Journal of bioscience and bioengineering.

[30]  J. Hassenpflug,et al.  Combination of reduced oxygen tension and intermittent hydrostatic pressure: a useful tool in articular cartilage tissue engineering. , 2001, Journal of biomechanics.

[31]  F. Legendre,et al.  Chondroitin sulfate modulation of matrix and inflammatory gene expression in IL-1beta-stimulated chondrocytes--study in hypoxic alginate bead cultures. , 2008, Osteoarthritis and cartilage.

[32]  Kristi S. Anseth,et al.  Predicting Controlled-Release Behavior of Degradable PLA-b-PEG-b-PLA Hydrogels , 2001 .

[33]  D. Lee,et al.  The effects of direct current stimulation on isolated chondrocytes seeded in 3D agarose constructs. , 2008, Biorheology.

[34]  R M Pilliar,et al.  A single application of cyclic loading can accelerate matrix deposition and enhance the properties of tissue-engineered cartilage. , 2006, Osteoarthritis and cartilage.

[35]  F. Guilak,et al.  The Pericellular Matrix as a Transducer of Biomechanical and Biochemical Signals in Articular Cartilage , 2006, Annals of the New York Academy of Sciences.

[36]  S E Carver,et al.  Increasing extracellular matrix production in regenerating cartilage with intermittent physiological pressure. , 1999, Biotechnology and bioengineering.

[37]  R W Farndale,et al.  A direct spectrophotometric microassay for sulfated glycosaminoglycans in cartilage cultures. , 1982, Connective tissue research.

[38]  G A Ateshian,et al.  Functional tissue engineering of articular cartilage through dynamic loading of chondrocyte-seeded agarose gels. , 2000, Journal of biomechanical engineering.

[39]  Thomas Aigner,et al.  Articular cartilage and changes in Arthritis: Cell biology of osteoarthritis , 2001, Arthritis Research & Therapy.

[40]  D. A. Lee,et al.  Integrin-mediated mechanotransduction in IL-1β stimulated chondrocytes , 2006 .

[41]  W M Lai,et al.  The influence of the fixed negative charges on mechanical and electrical behaviors of articular cartilage under unconfined compression. , 2004, Journal of Biomechanical Engineering.

[42]  Wenjing Hu,et al.  Surface chemistry influences implant biocompatibility. , 2008, Current topics in medicinal chemistry.

[43]  H. Baba,et al.  Effect of osmolarity on glycosaminoglycan production and cell metabolism of articular chondrocyte under three-dimensional culture system. , 2008, Clinical and experimental rheumatology.

[44]  F. X. Hart The mechanical transduction of physiological strength electric fields , 2008, Bioelectromagnetics.

[45]  A. Grodzinsky,et al.  Cartilage electromechanics--I. Electrokinetic transduction and the effects of electrolyte pH and ionic strength. , 1987, Journal of biomechanics.

[46]  P. Franchimont,et al.  Stimulation of proteoglycan production by glucosamine sulfate in chondrocytes isolated from human osteoarthritic articular cartilage in vitro. , 1998, Osteoarthritis and cartilage.

[47]  D. Bader,et al.  Temporal regulation of chondrocyte metabolism in agarose constructs subjected to dynamic compression. , 2003, Archives of biochemistry and biophysics.

[48]  A. Khademhosseini,et al.  Hydrogels in Biology and Medicine: From Molecular Principles to Bionanotechnology , 2006 .

[49]  Shyni Varghese,et al.  Chondroitin sulfate based niches for chondrogenic differentiation of mesenchymal stem cells. , 2008, Matrix biology : journal of the International Society for Matrix Biology.

[50]  D L Bader,et al.  Compressive strains at physiological frequencies influence the metabolism of chondrocytes seeded in agarose , 1997, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[51]  Michel Meunier,et al.  Fabrication and characterization of nonplanar microelectrode array circuits for use in arthroscopic diagnosis of cartilage diseases , 2004, IEEE Transactions on Biomedical Engineering.

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

[53]  Adam C. Canver,et al.  Response of zonal chondrocytes to extracellular matrix‐hydrogels , 2007, FEBS letters.