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Fibrin, tissue engineering

Johnson, R, Tatara, A., Mccreedy, D., Shiu, A., and Sakiyama-Elbert, S. 2010a. Tissue engineered fibrin scaffolds containing neural progenitors enhance functional recovery in a subacute model of SCI. [Pg.674]

Fibrin is the major protein component of blood clots and is formed by enzymatic cleavage and polymerization of fibrinogen. Because of its important role in natural wound healing process, fibrin is an attractive functional material for tissue engineering. Additional... [Pg.1103]

Sakiyama, S.E. et al.. Incorporation of heparin-binding peptides into fibrin gels enhances nenrite extension An example of designer matrices in tissue engineering, FASEB J., 13, 2214,1999. [Pg.978]

McGloughlin, T. M. (2008). Fibrin A natural biodegradable scaffold in vascular tissue engineering, 1 333-346. [Pg.132]

T.A. Ahmed, E.V. Dare, M. Hincke, Fibrin a versatile scaffold for tissue engineering applications. Tissue Eng. Part B Rev. 14 (2008) 199-215. [Pg.56]

L.J. Currie, J.R. Sharpe, R. Martin, The use of fibrin glue in skin grafts and tissue-engineered skin replacements a review, Plast. Re-constr. Surg. 108 (2001) 1713-1726. [Pg.56]

T.A. Ahmed, M. Griffith, M. Hincke, Characterization and inhibition of fibrin hydrogel-degrading enzymes during development of tissue engineering scaffolds. Tissue Eng. 13 (2007) 1469-1477. [Pg.57]

K. Ito, Y. Yamada, T. NaiM, M. Ueda, Simultaneous implant placement and bone regeneration around dental implants using tissue-engineered bone with fibrin glue, mesenchymal stem cells and platelet-rich plasma, Clin. Oral Implants Res. 17 (2006) 579-586. [Pg.57]

S.J. Zhu, B.H. Choi, J.H. Jung, S.H. Lee, J.Y. Huh, T.M. You, et al., A comparative histologic analysis of tissue-engineered bone using platelet-rich plasma and platelet-enriched fibrin glue. Oral Surg. Oral Med. Oral Pathol. Oral Radiol. Endod. 102 (2006) 175-179. [Pg.57]

F. Verseijden, et al.. Comparing scaffold-free and fibrin-based adipose-derived stromal cell constructs for adipose tissue engineering an in vitro and in vivo smdy. Cell Transplant 21 (2012) 2283-2297. [Pg.242]

F.M. Shaikh, A. Callanan, E.G. Kavanagh, PE. Burke, PA. Grace, T.M. McGloughUn, Fibrin a natural biodegradable scaffold in vascular tissue engineering. Cells Tissues Organs 188 (4) (2008) 333-346. [Pg.367]

J. Kopp, M.G. Jeschke, A.D. Bach, U. Kneser, R.E. Horch, Applied tissue engineering in the closure of severe bums and chronic wounds using cultured human autolc ous keratinocytes in a natural fibrin matrix. Cell Tissue Bank. 5 (2) (2004) 89—96. [Pg.367]

D. Le Nihouannen, L.L. Guehennec, T. RouiUon, P Pilet, M. Bilban, P Layrolle, G. Daculsi, Micro-architecture of calcium phosphate granules and fibrin glue composites for bone tissue engineering. Biomaterials 27 (13) (2006) 2716-2722. [Pg.367]

Beier, J. P., Stem-Straeter, J., Foerster, V. T., Kneser, U., Stark, G. B. Bach, A. D. (2006) Tissue engineering of injectable muscle three-dimensional myoblast-fibrin injection in the syngeneic rat animal model. Plast Recomtr Surg, 118, 1113-21 discussion 1122—4. [Pg.172]

Park, S. H., Park, S. R., Chung, S. 1., Pai, K. S. Min, B. H. (2005c) Tissue-engineered cartilage using fibrin/hyaluronan composite gel and its in vivo implantation. Artif Organs, 29, 838 5. [Pg.177]

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See also in sourсe #XX -- [ Pg.354 ]



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