Biomedical Engineering Reference
In-Depth Information
[26]
Sekine H, T Shimizu, K Hobo, S Sekiya, J Yang, M Yamato, H Kurosawa, E Kobayashi and T
Okano (2008). Endothelial cell coculture within tissue-engineered cardiomyocyte sheets enhances
neovascularization and improves cardiac function of ischemic hearts. Circulation 118: S145-S152.
[27]
Jay SM, BR Shepherd, JW Andrejecsk, TR Kyriakides, JS Pober and WM Saltzman (2010).
Dual delivery of VEGF and MCP-1 to support endothelial cell transplantation for therapeutic
vascularization. Biomaterials 31: 3054-3062.
[28]
Saif J, TM Schwarz, DY Chau, J Henstock, P Sami, SF Leicht, PC Hermann, S Alcala, F
Mulero, KM Shakesheff, C Heeschen and A Aicher (2010). Combination of injectable multiple
growth factor-releasing scaffolds and cell therapy as an advanced modality to enhance tissue
neovascularization. Arteriosclerosis, Thrombosis, and Vascular Biology 30: 1897-1904.
[29]
Martinez EC, J Wang, SU Gan, R Singh, CN Lee and T Kofidis (2010). Ascorbic acid improves
embryonic cardiomyoblast cell survival and promotes vascularization in potential myocardial
grafts in vivo. Tissue Engineering Part A 16: 1349-1361.
[30]
Smart N, CA Risebro, JE Clark, E Ehler, L Miquerol, A Rossdeutsch, MS Marber and PR Riley
(2010). Thymosin beta4 facilitates epicardial neovascularization of the injured adult heart.
Annals of the New York Academy of Sciences 1194: 97-104.
[31]
Kumbar S, L Nair, S Bhattacharyya and C Laurencin (2010). Contribution of extracellular
matrix to the mechanical properties of the heart. Mol Cell Cardiology 48: 490-496.
[32]
Kim DH, EA Lipke, P Kim, R Cheong, S Thompson, M Delannoy, KY Suh, L Tung and A
Levchenko (2010). Nanoscale cues regulate the structure and function of macroscopic cardiac
tissue constructs. Proceedings of the National Academy of Sciences of the USA 107:
565-570.
[33]
Kumbar S, L Nair, S Bhattacharyya and C Laurencin (2006). Polymeric nanofibers as novel car-
riers for the delivery of therapeutic molecules. Nanoscience Nanotechnology 6: 2591.
[34]
Ma PX and Zhang R (1999). Synthetic nano-scale fibrous extracellular matrix. Biomedical
Materials Research Part A 46: 60.
[35]
Matthews JA, GE Wnek, DG Simpson and GL Bowlin (2002). Electrospinning of collagen
nanofibers. Biomacromolecules 3: 232-238.
[36]
Zhang SG (2003). Fabrication of novel biomaterials through molecular self-assembly. Nature
Biotechnology 21: 1171-1178.
[37]
Woo K, V Chen and PX Ma (2003). Nano-fibrous scaffolding architecture selectively enhances
protein adsorption contributing to cell attachment. Biomaterial Research Part A 67: 531-537.
[38]
Tayalia P and D Mooney (2009). Controlled growth factor delivery for tissue engineering.
Advanced Materials 21: 3269-3285.
[39]
Chew SY, T Hufnagel, C Lim and KW Leong (2006). Mechanical properties of single electros-
pun drug-encapsulated nanofibres. Nanotechnology 17: 3880-3891.
[40]
Buttafoco L, NG Kolkman, P Engbers-Buijtenhuijs, AA Poot, P Dijkstra, I Vermes and J Feijen
(2006). Electrospinning of collagen and elastin for tissue engineering applications. Biomaterials
27: 724-734.
[41]
Van de Witte P, P Dijkstra, J Van den Berg and J Feijen (1996). Phase separation processes in
polymer solutions in relation to membrane formation. Membrane Science 117: 1-31.
[42]
Mikos AG and J Temenoff (2000). Formation of highly porous biodegradable scaffolds for
tissue engineering. Electron Journal of Biotechnology 3: 114-119.
[43]
Hartgerink J, E Beniash and S Stupp (2001). Self-assembly and mineralization of peptide-
amphiphile nanofibers. Science 294: 1684-1688.
[44]
Dahlin RL, FK Kasper and AG Mikos (2011). Polymeric nanofibers in tissue engineering.
Tissue Engineering Part B 17: 349-364.
[45]
Prabhakaran MP, D Kai, L Ghasemi-Mobarakeh and S Ramakrishna (2011). Electrospun
biocomposite nanofibrous patch for cardiac tissue engineering. Biomedical Materials 6: 055001.
[46]
Stout DA, J Yoo, AN Santiago-Miranda and TJ Webster (2012). Mechanisms of greater
cardiomyocyte functions on conductive nanoengineered composites for cardiovascular applica-
tion. International Journal of Nanomedicine 7: 5653-5669.
[47]
Ravichandran R, CCh Ng, S Liao, D Pliszka, M Raghunath, S Ramakrishna and CK Chan
(2012). Biomimetic surface modification of titanium surfaces for early cell capture by advanced
electrospinning. Biomedical Materials 7: 015001.
