Biomedical Engineering Reference
In-Depth Information
83. Maquet, V. et al. Preparation, characterization, and
in vitro
degradation of bioresorbable and bioactive
composites based on Bioglass-fi lled polylactide foams.
J. Biomed. Mater. Res. A
, 66, 335, 2003.
84. Nam, Y.S. and Park, T.G. Biodegradable polymeric microcellular foams by modifi ed thermally induced
phase separation method.
Biomaterials
, 20, 1783, 1999.
85. Ansaloni, L. et al. Experimental evaluation of Surgisis as scaffold for neointestine regeneration in a rat
model.
Tra nspla nt Proc.
, 38, 1844, 2006.
86. Hodde, J. Naturally occurring scaffolds for soft tissue repair and regeneration.
Tissue Eng.
, 8, 295,
2002.
87. Badylak, S. et al. Resorbable bioscaffold for esophageal repair in a dog model.
Pediatr. Surg
., 35, 1097,
2000.
88. Zheng, M.H. et al. Porcine small intestine submucosa (SIS) is not an acellular collagenous matrix and
contains porcine DNA: possible implications in human implantation.
J. Biomed. Mater. Res. B
,
Appl.
Biomater.
, 73, 61, 2005.
89. Lee, M., Dunn, J.C., and Wu, B.M. Scaffold fabrication by indirect three-dimensional printing.
Biomaterials
, 26, 4281, 2005.
90. Gardner-Thorpe, J. et al. Angiogenesis in tissue-engineered small intestine.
Tissue Eng.
, 9, 1255, 2003.
91. Babensee, J.E., McIntire, L.V., and Mikos, A.G. Growth factor delivery for tissue engineering.
Pharm.
Res.
, 17, 497, 2002.
92. Nomi, M. et al. Principles of neovascularization for tissue engineering.
Mol. Aspects Med.
, 23, 463,
2002.
93. Nillesen, S.T. et al. Increased angiogenesis and blood vessel maturation in acellular collagen-heparin
scaffolds containing both FGF2 and VEGF.
Biomaterials
, 28, 1123, 2007.
94. Ennett, A.B., Kaigler, D., and Mooney, D.J. Temporally regulated delivery of VEGF
in vitro
and
in vivo
.
J. Biomed. Mater. Res. A
,
79, 176, 2006.
95. Richardson, T.P. et al. Polymeric system for dual growth factor delivery.
Nat. Biotechnol.
, 19, 1029,
2001.
96. Hench, L.L. and Polak, J.M. Third-generation biomedical materials.
Science
, 295, 1014, 2002.
97. Day, R.M. Assessment of polyglycolic acid mesh and bioactive glass for soft-tissue engineering scaf-
folds.
Biomaterials
,
25, 5857, 2004.
98. Day, R.M. et al.
In vitro
and
in vivo
analysis of macroporous biodegradable poly(d,l-lactide-
co
-glycolide)
scaffolds containing bioactive glass.
J. Biomed. Mater. Res. A
, 75, 778, 2005.
99. Day, R.M. Bioactive glass stimulates the secretion of angiogenic growth factors and angiogenesis
in vitro
.
Tissue Eng.
, 11, 768, 2005.