Biomedical Engineering Reference
In-Depth Information
199. Li, W. J.; Cooper, J. A. J.; Mauck, R. L.; Tuan, R. S. Fabrication and Characterization of Six
Electrospun Poly(alpha-hydroxy ester)-based Fibrous Scaffolds for Tissue Engineering Appli-
cations.
Acta. Biomater.
2006,
2,
377-385.
200. Thorvaldsson, A.; Stenhamre, H.; Gatenholm, P.; Walkenstrom, P. Electrospinning of Highly
Porous Scaffolds for Cartilage Regeneration.
Biomacromolecules
2008,
9,
1044-1049.
201. Li, W. J.; Danielson, K. G.; Alexander, P. G.; Tuan, R. S. Biological Response of Chondro-
cytes Cultured in Three-Dimensional Nanofibrous Poly(epsilon-caprolactone) Scaffolds.
J. Biomed. Mater. Res. A
2003,
67,
1105-1114.
202. Ma, Z.; Kotaki, M.; Inai, R.; Ramakrishna, S. Potential of Nanofiber Matrix as Tissue-
Engineering Scaffolds.
Tissue Eng.
2005,
11,
101-109.
203. Yao, C.; Slamovich, E. B.; Webster, T. J. Improved bone cell adhesion on nanophase titanium
and Ti6Al4V. In
American Ceramic Society Conference Proceedings
,
2005
, January 23-28,
Cocoa Beach, FL.
204. Miller, D. C.; Thapa, A.; Haberstroh, K. M.; Webster, T. J. Endothelial and Vascular Smooth
Muscle Cell Function on Poly(lactic-co-glycolic acid) with Nano Structured Surface Features.
Biomaterials
2004,
25,
53-61.
205. Choudhary, S.; Haberstroh, K. M.; Webster, T. J. Greater Endothelial Cell Responses to Nano-
phase Metals.
Int. J. Nanomed.
2006,
1,
37-47.
206. Zhao, L.; He, C.; Zhang, D. M.; Chang, J.; Cui, L. Comparison of Electrospun PBSU and
PLGA Scaffolds Applied in Vascular Tissue Engineering.
J. Biomim. Biomater. Tissue Eng.
2009,
2,
27-38.
207. Pattison, M. A.; Wurster, S.; Webster, T. J.; Haberstroh, K. M. Three-Dimensional, Nano-
Structured PLGA Scaffolds for Bladder Tissue Replacement Applications.
Biomaterials
2005,
26
(15)
,
2491-2500.
208. Webster, T. J.; Waid, M. C.; McKenzie, J. L.; Price, R. L.; Ejiofor, J. U. Nano-Biotechnology:
Carbon Nanofibres as Improved Neural and Orthopaedic Implants.
Nanotechnology
2004,
15,
48.
209. Seil, J. T.; Webster, T. J. Electrically Active Nanomaterials as Improved Neural Tissue Regen-
eration Scaffolds.
Wiley Interdiscip. Nanomed Rev. Nanobiotechnol Rev.
2010,
2,
635-647.
210. Johnson, C.
Getting an Artificial Leg up
. 2000 June 13, 2012. Available from:
http://www.abc.
net.au/science/slab/leg/default.htm
.
211. Smith, G. C.; Plettenburg, D. H. Efficiency of Voluntary Closing Hand and Hook Prostheses.
Prosthet. Orthot. Int.
2010,
34,
411-427.
212. Tang, S. F. T.; Chen, C. P. C.; Chen, M. J. L.; Chen, W. P.; Leong, C. P.; Chu, N. K. Transmeta-
tarsal Amputation Prosthesis with Carbon-Fiber Plate: Enhanced Gait Function.
Am. J. Phys.
Med. Rehabil.
2004,
83,
124-130.
213. Boriani, S.; Bandiera, S.; Biagini, R.; De Iure, F.; Giunti, A. The use of the Carbon-Fiber
Reinforced Modular Implant for the Reconstruction of the Anterior Column of the Spine.
A Clinical and Experimental Study Conducted on 42 Cases.
Chir. Organic. Mov.
2000,
85,
309-335.
214. Nguyen-Vu, T. D. B.; Chen, H.; Cassell, A. M.; Andrews, R.; Meyyappan, M.; Li, J. Vertically
Aligned Carbon Nanofiber Arrays: An Advance Towards Electrial-Neural Interfaces.
Small
2006,
2,
89-94.
215. McKnight, T. E.; Melechko, A. V.; Fletcher, B. I.; Jones, S. W.; Hensley, D. K.; Peckys, D. B.;
Griffin, G. D.; Simpson, M. I.; Ericson, M. N. Resident Neuroelectrochemical Interfacing
using Carbon Nanofiber Arrays.
J. Phys. Chem. B
2006,
110,
15317-15327.
216. Shalak, R.; Fox, C. F., Eds.;
Tissue Engineering
, Liss, New York, 1988.
217. Jagur-Grodzinski, J. Polymers for Tissue Engineering, Medical Devices, and Regenerative Med-
icine. Concise General Review of Recent Studies.
Polymer. Adv. Technol.
2006,
17,
395-418.
