Gradient nanofibrous chitosan/poly ɛ-caprolactone scaffolds as extracellular microenvironments for vascular tissue engineering.

One of the major challenges of tissue-engineered small-diameter blood vessels is restenosis caused by thrombopoiesis. The goal of this study was to develop a 3D gradient heparinized nanofibrous scaffold, aiding endothelial cells lined on the lumen of blood vessel to prevent thrombosis. The vertical graded chitosan/poly ɛ-caprolactone (CS/PCL) nanofibrous vessel scaffolds were fabricated with chitosan and PCL by sequential quantity grading co-electrospinning. To mimic the natural blood vessel microenvironment, we used heparinization and immobilization of vascular endothelial growth factor (VEGF) in the gradient CS/PCL. The quantity of heparinized chitosan nanofibers increased gradually from the tunica adventitia to the lumen surfaces in the gradient CS/PCL wall of tissue engineered vessel. More heparin reacted to chitosan nanofiber in gradient CS/PCL than in uniform CS/PCL nanofibrous scaffolds. Antithrombogenic properties of the scaffolds were enhanced by the heparinization of these scaffolds, as shown by activated partial thromboplastin time and platelet adhesion assay. Compared to the uniform CS/PCL scaffold, the release of VEGF from the gradient CS/PCL was more stable and sustained, and the burst release of VEGF was reduced approximately 42.5% within the initial 12 h. The adhesion and proliferation of human umbilical vein endothelial cells (HUVEC) were enhanced on the gradient CS/PCL scaffold. Furthermore, HUVEC grew and formed an entire monolayer on the top side of the gradient CS/PCL scaffold. Therefore, use of vertical gradient heparinized CS/PCL nanofibrous scaffolds could provide an approach to create small-diameter blood vessel grafts with innate properties of mammalian vessels of anticoagulation and rapid induction of re-endothelialization.

[1]  G. Sonenshein,et al.  Heparin prevents vascular smooth muscle cell progression through the G1 phase of the cell cycle. , 1989, The Journal of biological chemistry.

[2]  Y. Joung,et al.  Controlled release of heparin-binding growth factors using heparin-containing particulate systems for tissue regeneration , 2008 .

[3]  N. L'Heureux,et al.  Human tissue-engineered blood vessels for adult arterial revascularization , 2007, Nature Medicine.

[4]  Min Zhou,et al.  Development and validation of small-diameter vascular tissue from a decellularized scaffold coated with heparin and vascular endothelial growth factor. , 2009, Artificial organs.

[5]  Vinoy Thomas,et al.  An in vitro regenerated functional human endothelium on a nanofibrous electrospun scaffold. , 2010, Biomaterials.

[6]  J. Hubbell,et al.  Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering , 2005, Nature Biotechnology.

[7]  J. Hubbell,et al.  Three-dimensional extracellular matrix-directed cardioprogenitor differentiation: systematic modulation of a synthetic cell-responsive PEG-hydrogel. , 2008, Biomaterials.

[8]  B. Johansson,et al.  Production of extracellular matrix components in tissue-engineered blood vessels. , 2006, Tissue engineering.

[9]  Young Ha Kim,et al.  Efficient revascularization by VEGF administration via heparin-functionalized nanoparticle-fibrin complex. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[10]  David L Kaplan,et al.  Growth factor gradients via microsphere delivery in biopolymer scaffolds for osteochondral tissue engineering. , 2009, Journal of controlled release : official journal of the Controlled Release Society.

[11]  Milica Radisic,et al.  Scaffolds with covalently immobilized VEGF and Angiopoietin-1 for vascularization of engineered tissues. , 2010, Biomaterials.

[12]  Seeram Ramakrishna,et al.  Electrospun biocomposite nanofibrous scaffolds for neural tissue engineering. , 2008, Tissue engineering. Part A.

[13]  G. Goodhill,et al.  A new chemotaxis assay shows the extreme sensitivity of axons to molecular gradients , 2004, Nature Neuroscience.

[14]  V. Guarino,et al.  Influence of gelatin cues in PCL electrospun membranes on nerve outgrowth. , 2010, Biomacromolecules.

[15]  Byung-Soo Kim,et al.  Control of basic fibroblast growth factor release from fibrin gel with heparin and concentrations of fibrinogen and thrombin. , 2005, Journal of controlled release : official journal of the Controlled Release Society.

[16]  P. W. Wang,et al.  Electrospun collagen-chitosan nanofiber: a biomimetic extracellular matrix for endothelial cell and smooth muscle cell. , 2010, Acta biomaterialia.

[17]  Robert J Fisher,et al.  Heparin-regulated release of growth factors in vitro and angiogenic response in vivo to implanted hyaluronan hydrogels containing VEGF and bFGF. , 2006, Biomaterials.

[18]  B. Bay,et al.  Evaluation of electrospun PCL/gelatin nanofibrous scaffold for wound healing and layered dermal reconstitution. , 2007, Acta biomaterialia.

[19]  Ning‐Ping Huang,et al.  The effect of nanofibrous galactosylated chitosan scaffolds on the formation of rat primary hepatocyte aggregates and the maintenance of liver function. , 2009, Biomaterials.

[20]  Anthony Atala,et al.  Development of a composite vascular scaffolding system that withstands physiological vascular conditions. , 2008, Biomaterials.

[21]  Benjamin Chu,et al.  Antithrombogenic property of bone marrow mesenchymal stem cells in nanofibrous vascular grafts , 2007, Proceedings of the National Academy of Sciences.

[22]  Jennifer L West,et al.  Covalently immobilized gradients of bFGF on hydrogel scaffolds for directed cell migration. , 2005, Biomaterials.

[23]  L. León,et al.  Vascular grafts , 2003, Expert review of cardiovascular therapy.

[24]  Wei He,et al.  Tubular nanofiber scaffolds for tissue engineered small-diameter vascular grafts. , 2009, Journal of biomedical materials research. Part A.

[25]  Glenn D Prestwich,et al.  Engineered extracellular matrices with cleavable crosslinkers for cell expansion and easy cell recovery. , 2008, Biomaterials.

[26]  J. Huot,et al.  Integrating the VEGF signals leading to actin-based motility in vascular endothelial cells. , 2000, Trends in cardiovascular medicine.

[27]  H. Sung,et al.  Heparin-functionalized chitosan-alginate scaffolds for controlled release of growth factor. , 2009, International journal of pharmaceutics.

[28]  Richard A Gemeinhart,et al.  Cellular alignment by grafted adhesion peptide surface density gradients. , 2004, Journal of biomedical materials research. Part A.

[29]  J. Feijen,et al.  In vitro evaluation of heparinized Cuprophan hemodialysis membranes. , 1997, Journal of biomedical materials research.

[30]  G. Golomb,et al.  Perivascular delivery of heparin for the reduction of smooth muscle cell proliferation after endothelial injury. , 1999, Journal of controlled release : official journal of the Controlled Release Society.

[31]  Martin Ehrbar,et al.  Cell‐demanded release of VEGF from synthetic, biointeractive cell‐ingrowth matrices for vascularized tissue growth , 2003, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.