Photocrosslinking of gelatin macromers to synthesize porous hydrogels that promote valvular interstitial cell function.

The development of novel three-dimensional cell culture platforms for the culture of aortic valvular interstitial cells (VICs) has been fraught with many challenges. Although the most tunable, purely synthetic systems have not been successful at promoting cell survivability or function. On the other hand, entirely natural materials lack mechanical integrity. Here we explore a novel hybrid system consisting of gelatin macromers synthetically modified with methacrylate functionalities allowing for photoencapsulation of cells. Scanning electron microscopy observations show a microporous structure induced during polymerization within the hydrogel. This porous structure was tunable with polymerization rate and did not appear to have interconnected pores. Treatment with collagenase caused bulk erosion indicating enzymatic degradation controls the matrix remodeling. VICs, an important cell line for heart valve tissue engineering, were photoencapsulated and examined for cell-directed migration and differentiation. VICs were able to achieve their native morphology within 2 weeks of culture. The addition of the pro-fibrotic growth factor, transforming growth factor-beta1, accelerated this process and also was capable of inducing enhanced alpha-smooth muscle actin and collagen-1 expression, indicating a differentiation from quiescent fibroblasts to active myofibroblasts as demonstrated by quantitative real-time polymerase chain reaction and immunohistochemistry. Although these studies were limited to VICs, this novel hydrogel system may also be useful for studying other fibroblastic cell types.

[1]  Henry T. Peng,et al.  Hydrogel-elastomer composite biomaterials: 2. Effects of aging methacrylated gelatin solutions on the preparation and physical properties of interpenetrating polymer networks , 2007, Journal of materials science. Materials in medicine.

[2]  Frederick J Schoen,et al.  Heart valve tissue engineering: quo vadis? , 2011, Current opinion in biotechnology.

[3]  B L Bass,et al.  Dual structural and functional phenotypes of the porcine aortic valve interstitial population: characteristics of the leaflet myofibroblast. , 1994, The Journal of surgical research.

[4]  Andrea Barbetta,et al.  Enzymatic cross-linking versus radical polymerization in the preparation of gelatin PolyHIPEs and their performance as scaffolds in the culture of hepatocytes. , 2006, Biomacromolecules.

[5]  Magdi H Yacoub,et al.  Human cardiac valve interstitial cells in collagen sponge: a biological three-dimensional matrix for tissue engineering. , 2002, The Journal of heart valve disease.

[6]  A. Gotlieb,et al.  Advances towards understanding heart valve response to injury. , 2002, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[7]  R. Wyrwa,et al.  Synthesis of Photopolymerizable Hydrophilic Macromers and Evaluation of Their Applicability as Reactive Resin Components for the Fabrication of Three‐Dimensionally Structured Hydrogel Matrices by 2‐Photon‐Polymerization , 2011 .

[8]  Robert M Nerem,et al.  Porcine aortic valve interstitial cells in three-dimensional culture: comparison of phenotype with aortic smooth muscle cells. , 2004, The Journal of heart valve disease.

[9]  A. Pandit,et al.  Enzymatic stabilization of gelatin-based scaffolds. , 2005, Journal of biomedical materials research. Part B, Applied biomaterials.

[10]  S Jockenhoevel,et al.  Fibrin gel as a three dimensional matrix in cardiovascular tissue engineering. , 2000, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[11]  O. Petersen,et al.  Induction of alpha-smooth muscle actin by transforming growth factor-beta 1 in quiescent human breast gland fibroblasts. Implications for myofibroblast generation in breast neoplasia. , 1993, Laboratory investigation; a journal of technical methods and pathology.

[12]  Ali Khademhosseini,et al.  Synthesis and characterization of tunable poly(ethylene glycol): gelatin methacrylate composite hydrogels. , 2011, Tissue engineering. Part A.

[13]  M Cornelissen,et al.  Structural and rheological properties of methacrylamide modified gelatin hydrogels. , 2000, Biomacromolecules.

[14]  M. Pfaffl,et al.  A new mathematical model for relative quantification in real-time RT-PCR. , 2001, Nucleic acids research.

[15]  Henrik Lindberg,et al.  Transforming Growth Factor-β1 Specifically Induce Proteins Involved in the Myofibroblast Contractile Apparatus* , 2004, Molecular & Cellular Proteomics.

[16]  A. Veis,et al.  Reversible Transformation of Gelatin to the Collagen Structure , 1960, Nature.

[17]  Frederick Grinnell,et al.  Fibroblasts, myofibroblasts, and wound contraction , 1994, The Journal of cell biology.

[18]  C. Chu,et al.  Synthesis and characterization of dextran-methacrylate hydrogels and structural study by SEM. , 2000, Journal of biomedical materials research.

[19]  Karthik Nagapudi,et al.  Photo-cross-linking of type I collagen gels in the presence of smooth muscle cells: mechanical properties, cell viability, and function. , 2003, Biomacromolecules.

[20]  J. W. Mwangi,et al.  Crosslinked gelatin matrices: release of a random coil macromolecular solute. , 2004, International journal of pharmaceutics.

[21]  G. Qiao,et al.  Synthetic hydrogels 2. Polymerization induced phase separation in acrylamide systems , 2003 .

[22]  W. Bubnis,et al.  Chemical and Swelling Evaluations of Amino Group Crosslinking in Gelatin and Modified Gelatin Matrices , 1996, Pharmaceutical Research.

[23]  K. Leong,et al.  The design of scaffolds for use in tissue engineering. Part I. Traditional factors. , 2001, Tissue engineering.

[24]  A. Khademhosseini,et al.  Cell-laden microengineered pullulan methacrylate hydrogels promote cell proliferation and 3D cluster formation. , 2011, Soft matter.

[25]  D. Elbert,et al.  Liquid-liquid two-phase systems for the production of porous hydrogels and hydrogel microspheres for biomedical applications: A tutorial review. , 2011, Acta biomaterialia.

[26]  K. Anseth,et al.  Synthetic hydrogel niches that promote hMSC viability. , 2005, Matrix biology : journal of the International Society for Matrix Biology.

[27]  M. Simionescu,et al.  Interstitial Cells of the Heart Valves Possess Characteristics Similar to Smooth Muscle Cells , 1986, Circulation research.

[28]  Kristi S. Anseth,et al.  The effect of bioactive hydrogels on the secretion of extracellular matrix molecules by valvular interstitial cells. , 2008, Biomaterials.

[29]  A. Barbetta,et al.  Tailoring the porosity and morphology of gelatin-methacrylate polyHIPE scaffolds for tissue engineering applications. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[30]  L. Leinwand,et al.  Valvular Myofibroblast Activation by Transforming Growth Factor-&bgr;: Implications for Pathological Extracellular Matrix Remodeling in Heart Valve Disease , 2004, Circulation research.

[31]  T. Kyu,et al.  Morphology Development and Dynamics of Photopolymerization-Induced Phase Separation in Mixtures of a Nematic Liquid Crystal and Photocuratives , 2000 .

[32]  G. Stevens,et al.  The Influence of Extracellular Matrix on the Generation of Vascularized, Engineered, Transplantable Tissue , 2001, Annals of the New York Academy of Sciences.

[33]  C. L. Bell,et al.  Swelling/syneresis phenomena in gel-forming interpolymer complexes. , 1996, Journal of biomaterials science. Polymer edition.

[34]  C M Johnson,et al.  Porcine cardiac valvular subendothelial cells in culture: cell isolation and growth characteristics. , 1987, Journal of molecular and cellular cardiology.

[35]  Jorge Martínez,et al.  Induction of the myofibroblastic phenotype in human gingival fibroblasts by transforming growth factor-beta1: role of RhoA-ROCK and c-Jun N-terminal kinase signaling pathways. , 2006, Journal of periodontal research.

[36]  S. Pedron,et al.  Stimuli Responsive Delivery Vehicles for Cardiac Microtissue Transplantation , 2011 .

[37]  S. Van Vlierberghe,et al.  Biopolymer-based hydrogels as scaffolds for tissue engineering applications: a review. , 2011, Biomacromolecules.

[38]  L G Griffith,et al.  Effect of pore size and void fraction on cellular adhesion, proliferation, and matrix deposition. , 2001, Tissue engineering.

[39]  A. Khademhosseini,et al.  Cell-adhesive and mechanically tunable glucose-based biodegradable hydrogels. , 2011, Acta biomaterialia.

[40]  Ali Khademhosseini,et al.  Synthesis and characterization of photocrosslinkable gelatin and silk fibroin interpenetrating polymer network hydrogels. , 2011, Acta biomaterialia.

[41]  Henry T. Peng,et al.  Hydrogel–elastomer composite biomaterials: 1. Preparation of interpenetrating polymer networks and in vitro characterization of swelling stability and mechanical properties , 2007, Journal of materials science. Materials in medicine.

[42]  C. Chu,et al.  Pore structure analysis of swollen dextran-methacrylate hydrogels by SEM and mercury intrusion porosimetry. , 2000, Journal of biomedical materials research.

[43]  A. Abbott Cell culture: Biology's new dimension , 2003, Nature.

[44]  U. Maschke,et al.  Photopolymerization kinetics and phase behaviour of acrylate based polymer dispersed liquid crystals , 1998 .

[45]  Stephanie J Bryant,et al.  Manipulations in hydrogel chemistry control photoencapsulated chondrocyte behavior and their extracellular matrix production. , 2003, Journal of biomedical materials research. Part A.

[46]  A. Habeeb,et al.  Determination of free amino groups in proteins by trinitrobenzenesulfonic acid. , 1966, Analytical biochemistry.

[47]  Ali Khademhosseini,et al.  SAM-based cell transfer to photopatterned hydrogels for microengineering vascular-like structures. , 2011, Biomaterials.

[48]  Kristi S Anseth,et al.  In vitro osteogenic differentiation of human mesenchymal stem cells photoencapsulated in PEG hydrogels. , 2004, Journal of biomedical materials research. Part A.

[49]  Kristi S Anseth,et al.  The enhancement of chondrogenic differentiation of human mesenchymal stem cells by enzymatically regulated RGD functionalities. , 2008, Biomaterials.

[50]  Lei Tian,et al.  Biomaterials to Prevascularize Engineered Tissues , 2011, Journal of cardiovascular translational research.

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

[52]  Emile R. Mohler,et al.  Bone Formation and Inflammation in Cardiac Valves , 2001, Circulation.

[53]  Ali Khademhosseini,et al.  Interface-directed self-assembly of cell-laden microgels. , 2010, Small.

[54]  Jennifer L West,et al.  Flexural characterization of cell encapsulated PEGDA hydrogels with applications for tissue engineered heart valves. , 2011, Acta biomaterialia.

[55]  Frederick Grinnell,et al.  Fibroblast biology in three-dimensional collagen matrices. , 2003, Trends in cell biology.

[56]  J. Hubbell,et al.  Molecularly engineered PEG hydrogels: a novel model system for proteolytically mediated cell migration. , 2005, Biophysical journal.

[57]  J. A. Hubbell,et al.  Cell‐Responsive Synthetic Hydrogels , 2003 .

[58]  Ali Khademhosseini,et al.  Modified Gellan Gum hydrogels with tunable physical and mechanical properties. , 2010, Biomaterials.

[59]  Kristi S Anseth,et al.  Activation of valvular interstitial cells is mediated by transforming growth factor-beta1 interactions with matrix molecules. , 2005, Matrix biology : journal of the International Society for Matrix Biology.

[60]  J. Shirani,et al.  Matrix metalloproteinase expression in nonrheumatic aortic stenosis. , 2000, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[61]  A. Khademhosseini,et al.  Cell-laden microengineered gelatin methacrylate hydrogels. , 2010, Biomaterials.

[62]  J. Hubbell,et al.  Incorporation of adhesion peptides into nonadhesive hydrogels useful for tissue resurfacing. , 1998, Journal of biomedical materials research.

[63]  Ali Khademhosseini,et al.  EMT-Inducing Biomaterials for Heart Valve Engineering: Taking Cues from Developmental Biology , 2011, Journal of cardiovascular translational research.

[64]  J. Elisseeff,et al.  Photoencapsulation of chondrocytes in poly(ethylene oxide)-based semi-interpenetrating networks. , 2000, Journal of biomedical materials research.

[65]  H. Boedtker,et al.  A Study of Gelatin Molecules, Aggregates and Gels , 1954 .

[66]  Kristyn S Masters,et al.  Designing scaffolds for valvular interstitial cells: cell adhesion and function on naturally derived materials. , 2004, Journal of biomedical materials research. Part A.

[67]  P. Libby,et al.  Activated Interstitial Myofibroblasts Express Catabolic Enzymes and Mediate Matrix Remodeling in Myxomatous Heart Valves , 2001, Circulation.

[68]  Henry T. Peng,et al.  Hydrogel-elastomer composite biomaterials: 3. Effects of gelatin molecular weight and type on the preparation and physical properties of interpenetrating polymer networks , 2008, Journal of materials science. Materials in medicine.

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

[70]  V. Crescenzi,et al.  New gelatin-based hydrogels via enzymatic networking. , 2002, Biomacromolecules.

[71]  J L West,et al.  Smooth muscle cell growth in photopolymerized hydrogels with cell adhesive and proteolytically degradable domains: synthetic ECM analogs for tissue engineering. , 2001, Biomaterials.

[72]  Jennifer L West,et al.  Photocrosslinkable polyvinyl alcohol hydrogels that can be modified with cell adhesion peptides for use in tissue engineering. , 2002, Biomaterials.