Biomedical Engineering Reference
In-Depth Information
194. P.L. Tremblay, V. Hudon, F. Berthod, L. Germain, and F.A. Auger, Inosculation
of tissue-engineered capillaries with the host's vasculature in a recon-
structed skin transplanted on mice,
Am. J. Transplant.,
Vol. 5, pp. 1002-10,
May 2005.
195. M.C. Ford, J.P. Bertram, S.R. Hynes, M. Michaud, Q. Li, M. Young, S.S. Segal,
J.A. Madri, and E.B. Lavik, A macroporous hydrogel for the coculture of neu-
ral progenitor and endothelial cells to form functional vascular networks in
vivo,
Proc. Natl. Acad. Sci. U.S.A.,
Vol. 103, pp. 2512-7, Feb 21 2006.
196. V. Nehls, E. Schuchardt, and D. Drenckhahn, The effect of fi broblasts, vas-
cular smooth muscle cells, and pericytes on sprout formation of endothelial
cells in a fi brin gel angiogenesis system,
Microvasc. Res.,
Vol. 48, pp. 349-63,
Nov 1994.
197. S.W. Cho, S.H. Lim, I.K. Kim, Y.S. Hong, S.S. Kim, K.J. Yoo, H.Y. Park, Y. Jang,
B.C. Chang, C.Y. Choi, K.C. Hwang, and B.S. Kim, Small-diameter blood
vessels engineered with bone marrow-derived cells,
Ann. Surg.,
Vol. 241,
pp. 506-15, Mar 2005.
198. N. Hibino, T. Shin'oka, G. Matsumura, Y. Ikada, and H. Kurosawa, The tis-
sue-engineered vascular graft using bone marrow without culture,
J. Thorac.
Cardiovasc. Surg.,
Vol. 129, pp. 1064-70, May 2005.
199. S. Kaushal, G.E. Amiel, K.J. Guleserian, O.M. Shapira, T. Perry,
F.W. Sutherland, E. Rabkin, A.M. Moran, F.J. Schoen, A. Atala, S. Soker,
J. Bischoff, and J.E. Mayer, Jr., Functional small-diameter neovessels created using
endothelial progenitor cells expanded ex vivo,
Nat. Med.,
Vol. 7, pp. 1035-40,
Sep 2001.
200. J. Yamashita, H. Itoh, M. Hirashima, M. Ogawa, S. Nishikawa, T. Yurugi,
M. Naito, K. Nakao, and S. Nishikawa, Flk1-positive cells derived from embry-
onic stem cells serve as vascular progenitors,
Nature,
Vol. 408, pp. 92-6, Nov 2
2000.
201. S. Kaihara, J. Borenstein, R. Koka, S. Lalan, E.R. Ochoa, M. Ravens, H. Pien,
B. Cunningham, and J.P. Vacanti, Silicon micromachining to tissue engineer
branched vascular channels for liver fabrication,
Tissue Eng.,
Vol. 6, pp. 105-17,
Apr 2000.
202. S.M. Peirce, E.J. Van Gieson, and T.C. Skalak, Multicellular simulation pre-
dicts microvascular patterning and in silico tissue assembly,
FASEB J.,
Vol. 18,
pp. 731-3, Apr 2004.
203. C.R. Anderson, A.M. Ponce, and R.J. Price, Immunohistochemical identifi ca-
tion of an extracellular matrix scaffold that microguides capillary sprouting
in vivo,
J. Histochem. Cytochem.,
Vol. 52, pp. 1063-72, Aug 2004.
204. H.C. Ott, T.S. Matthiesen, S.K. Goh, L.D. Black, S.M. Kren, T.I. Netoff, and
D.A. Taylor, Perfusion-decellularized matrix: Using nature's platform to
engineer a bioartifi cial heart,
Nat. Med.,
Vol. 14, pp. 213-21, Feb 2008.
205. K. Linke, J. Schanz, J. Hansmann, T. Walles, H. Brunner, and H. Mertsching,
Engineered liver-like tissue on a capillarized matrix for applied research,
Tissue Eng.,
Vol. 13, pp. 2699-707, Nov 2007.
206. D. Kaigler, G. Pagni, C.H. Park, S.A. Tarle, R.L. Bartel, and W.V. Giannobile,
Angiogenic and osteogenic potential of bone repair cells for craniofacial
regeneration,
Tissue Eng. Part A,
Vol. 16, pp. 2809-20, Sep 2010.
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