Cell proliferation on three-dimensional chitosan-agarose-gelatin cryogel scaffolds for tissue engineering applications.

Tissue engineering is a potential approach for the repair of damaged tissues or organs like skin, cartilage, bone etc. Approach utilizes the scaffolds constructed from natural or synthetic polymers fabricated by the available fabrication technologies. This study focuses on the fabrication of the scaffolds using a novel technology called cryogelation, which synthesizes the scaffolds at sub-zero temperature. We have synthesized a novel scaffold from natural polymers like chitosan, agarose and gelatin in optimized ratio using the cryogelation technology. The elasticity of the scaffold was confirmed by rheological studies which supports the utility of the scaffolds for skin and cardiac tissue engineering. Proliferation of different cell types like fibroblast and cardiac cells was analysed by scanning electron microscopy (SEM) and fluorescent microscopy. Biocompatibility of the scaffolds was tested by MTT assay with specific cell type, which showed higher proliferation of the cells on the scaffolds when compared to the two dimensional culture system. Cell proliferation of C(2)C(12) and Cos 7 cells on these scaffolds was further analysed biochemically by alamar blue test and Hoechst test. Biochemical and microscopic analysis of the different cell types on these scaffolds gives an initial insight of these scaffolds towards their utility in skin and cardiac tissue engineering.

[1]  E. Sachlos,et al.  Making tissue engineering scaffolds work. Review: the application of solid freeform fabrication technology to the production of tissue engineering scaffolds. , 2003, European cells & materials.

[2]  Thomas Eschenhagen,et al.  Three‐dimensional reconstitution of embryonic cardiomyocytes in a collagen matrix: a new heart muscle model system , 1997, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[3]  Ashok Kumar,et al.  Elastic and macroporous agarose-gelatin cryogels with isotropic and anisotropic porosity for tissue engineering. , 2009, Journal of biomedical materials research. Part A.

[4]  J. Hoffman,et al.  Incidence of congenital heart disease: I. Postnatal incidence , 1995, Pediatric Cardiology.

[5]  K. Chawla,et al.  Mechanical Behavior of Materials , 1998 .

[6]  S R Gonda,et al.  Cardiac organogenesis in vitro: reestablishment of three-dimensional tissue architecture by dissociated neonatal rat ventricular cells. , 1999, Tissue engineering.

[7]  C. Kirkpatrick,et al.  Use of a collagen/elastin-membrane for the tissue engineering of dermis. , 1999, Burns : journal of the International Society for Burn Injuries.

[8]  R. Grant,et al.  Estimation of hydroxyproline by the AutoAnalyser , 1964, Journal of clinical pathology.

[9]  R. Gillum,et al.  Epidemiology of congenital heart disease in the United States. , 1994, American heart journal.

[10]  Milica Radisic,et al.  High-density seeding of myocyte cells for cardiac tissue engineering. , 2003, Biotechnology and bioengineering.

[11]  J. Hubbell,et al.  Bioactive biomaterials. , 1999, Current opinion in biotechnology.

[12]  J. Mansbridge Tissue-engineered skin substitutes. , 1999, Expert opinion on biological therapy.

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

[14]  Deepti Singh,et al.  Proliferation of Myoblast Skeletal Cells on Three-Dimensional Supermacroporous Cryogels , 2010, International journal of biological sciences.

[15]  Ashok Kumar,et al.  Cryogels: Freezing unveiled by thawing , 2010 .

[16]  R J Cohen,et al.  Cardiac muscle tissue engineering: toward an in vitro model for electrophysiological studies. , 1999, American journal of physiology. Heart and circulatory physiology.

[17]  Milica Radisic,et al.  Cardiac tissue engineering , 2013 .

[18]  K. Kar,et al.  Synthesis and characterization of elastic and macroporous chitosan-gelatin cryogels for tissue engineering. , 2009, Acta biomaterialia.

[19]  Chaozong Liu,et al.  Design and Development of Three-Dimensional Scaffolds for Tissue Engineering , 2007 .

[20]  A. Singer,et al.  Cutaneous wound healing. , 1999, The New England journal of medicine.

[21]  L. Currie,et al.  The use of fibrin glue in skin grafts and tissue-engineered skin replacements: a review. , 2001, Plastic and reconstructive surgery.

[22]  Laura E. Niklason,et al.  Replacement Arteries Made to Order , 1999, Science.

[23]  K. Cho,et al.  A new skin equivalent model: dermal substrate that combines de-epidermized dermis with fibroblast-populated collagen matrix. , 2000, Journal of dermatological science.

[24]  J. Mansbridge,et al.  Tissue-Engineered Skin Substitutes , 2020, Technology in Practical Dermatology.

[25]  M. A. Croce,et al.  Adhesion and Proliferation of Human Dermal Fibroblasts on Collagen Matrix , 2004, Journal of biomaterials applications.

[26]  D. J. Wainwright Use of an acellular allograft dermal matrix (AlloDerm) in the management of full-thickness burns. , 1995, Burns : journal of the International Society for Burn Injuries.

[27]  R. Weisel,et al.  Construction of a bioengineered cardiac graft. , 2000, The Journal of thoracic and cardiovascular surgery.

[28]  K. Harding,et al.  Clinical review Science , medicine , and the future Healing chronic wounds , 2005 .

[29]  Ashok Kumar,et al.  Skin tissue engineering for tissue repair and regeneration. , 2008, Tissue engineering. Part B, Reviews.

[30]  M. Ruel,et al.  Cardiac Tissue Engineering , 2014, Methods in Molecular Biology.

[31]  R. Weisel,et al.  Survival and function of bioengineered cardiac grafts. , 1999, Circulation.

[32]  Clifford Pereira,et al.  Review Paper: Burn Coverage Technologies: Current Concepts and Future Directions , 2007, Journal of biomaterials applications.

[33]  D. Greenhalgh,et al.  Cutaneous Wound Healing , 2007, Journal of burn care & research : official publication of the American Burn Association.

[34]  E. Rolland,et al.  Combined use of a collagen-based dermal substitute and a fibrin-based cultured epithelium: a step toward a total skin replacement for acute wounds. , 2004, Burns : journal of the International Society for Burn Injuries.

[35]  J. Vacanti,et al.  Tissue engineering : Frontiers in biotechnology , 1993 .

[36]  W. Zimmermann,et al.  Tissue Engineering of a Differentiated Cardiac Muscle Construct , 2002, Circulation research.

[37]  F J Schoen,et al.  Cardiac tissue engineering: cell seeding, cultivation parameters, and tissue construct characterization. , 1999, Biotechnology and bioengineering.

[38]  W. Zimmermann,et al.  Three-dimensional engineered heart tissue from neonatal rat cardiac myocytes. , 2000, Biotechnology and bioengineering.

[39]  A. Czeizel,et al.  Incidence of congenital heart disease in Hungary. , 1975, Human heredity.

[40]  B Page,et al.  A new fluorometric assay for cytotoxicity measurements in-vitro. , 1993, International journal of oncology.

[41]  Gordana Vunjak-Novakovic,et al.  Effects of oxygen on engineered cardiac muscle. , 2002, Biotechnology and bioengineering.

[42]  Sumrita Bhat,et al.  Supermacroprous chitosan–agarose–gelatin cryogels: in vitro characterization and in vivo assessment for cartilage tissue engineering , 2011, Journal of The Royal Society Interface.

[43]  G. Spilker,et al.  Cultured autologous keratinocytes in fibrin glue suspension, exclusively and combined with STS-allograft (preliminary clinical and histological report of a new technique). , 1994, Burns : journal of the International Society for Burn Injuries.

[44]  Ashok Kumar,et al.  Cell separation using cryogel-based affinity chromatography , 2010, Nature Protocols.

[45]  R. Langer,et al.  A tough biodegradable elastomer , 2002, Nature Biotechnology.

[46]  S. Boyce,et al.  Principles and practices for treatment of cutaneous wounds with cultured skin substitutes. , 2002, American journal of surgery.

[47]  J. Hoffman,et al.  Incidence of congenital heart disease: II. Prenatal incidence , 1995, Pediatric Cardiology.