Biomedical Engineering – From Theory to Applications

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428 Biomedical Engineering – From Theory to Applications Lane, W.A. (1895). Some remarks on the treatment of fractures. Brith Med J, 1, 861. Lee, C.K., Karl, M., & Kelly, J.R. (2009). Evaluation of test protocol variables for dental implant fatigue research. Dent Mater, 25, 1419. Lee, S.H., Nomura, N. & Chiba, A. (2008). Significant improvement in mechanical properties of biomedical CoCrMo alloys with combination of N addition and Cr-enrichment. Mater Trans, 49, 260. Leinenbach, C., Fleck, C., & Eifler, D. (2004). The cyclic deformation behaviour and fatigue induced damage of the implant alloy TiAl6Nb7 in simulated physiological media. Intl J Fatigue, 26, 857. Li, J.P., Habibovic, P., Van Den Doel, M., Wilson, C.E., De Wijn, J.R., Van Blitterswijk, C.A. & De Groot, K. (2007). Bone ingrowth in porous Ti implants produced by 3D fiber deposition. Biomaterials, 28, 2810. Li, Z., Gu, X., Lou, S. & Zheng, Y. (2008). The development of binary Mg-Ca alloys for use as biodegradable materials within bones. Biomaterials, 29, 1329. Liu, Y., & Baker, T.N. (1995). Deformation characteristics of IMI685 Ti alloy under β isothermal forging conditions. Mater Sci Eng A, 197, 125. Lopez-Heredia, M.A., Sohier, J., Gaillard, C., Quillard, S., Dorget, M. & Layrolle, P. (2008). Rapid prototyped porous Ti coated with calcium phosphate as a scaffold for bone tissue engineering. Biomaterials, 29, 2608. Matsumoto, H., Watanabe, S. & Hanada, S. (2005). Beta TiNbSn alloys with low Young’s modulus and high strength. Mater Trans, 46, 1070. Ming-Wei, W., Li-Wen, Z., Ji-Bin, P., Li Chen, P., & Fan, H. (2007). Effect of temperature on vacuum hot bulge forming of BT20 Ti alloy cylindrical work piece. Trans Nonferrous Met Soc China, 17, 957. Mitchell, A., & Shrotriya, P. (2007). Onset of nanoscale wear of metallic implant materials:Influence of surface residual stresses and contact loads. Wear, 263, 1117. Miyamoto, H., Mimaki, T., & Hashimoto, S. (2001). Mater Sci Eng A, 319–321, 779. Morais, L.S., Serra, G.G., Muller, C.A., Andrade, L.R., Palermo, E.F.A., Elias, C.N., & Meyers, M. (2007). Titanium alloy mini-implants for orthodontic anchorage: Immediate loading and metal ion release. Acta Biomater, 3, 331. Mordyuk, B.N., Prokopenko, G.I. Vasylyev, M.A., & Iefimov, M.O. (2007). Effect of structure evolution induced by ultrasonic peening on the corrosion behavior of AISI-321 stainless steel. Mater Sci Eng A, 458, 253. Narushima, T. (2010). New-generation metallic biomaterials. IN NIINOMI, M. (Ed.) Metals for Biomedical Devices. Cambrigde, Woodhead Publishing. Nguyen, H.Q., Deportera, D.A., Pilliara, R.M., Valiquettea, N., & Yakubovich, R. (2004). The effect of sol–gel-formed calcium phosphate coatings on bone ingrowth and osteoconductivity of porous-surfaced Ti alloy implants. Biomaterials, 25, 865. Okazaki, Y., & Gotoh, E. (2008). Metal release from stainless steel, CoCrMoNiFe and NiTi alloys in vascular implants. Corr Sci, 50, 3429. Öztürk, O., Türkan, U., & Ahmet, E.E. (2006). Metal ion release from nitrogen ion implanted CoCrMo orthopedic implant material. Surf Coat Technol, 200, 5687. Papakyriacou, M., Mayer, H. Pypen, C., Plenk Jr, H., & Stanzl-Tschegg, S. (2000). Effects of surface treatments on high cycle corrosion fatigue of metallic implant materials. Intl J Fatigue, 22, 873. Peckner, D., & Bernstein, I.M. (1977). Handbook of Stainless Steels, McGraw-Hill Inc.
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BIOMEDICAL ENGINEERING - FROM THEOR
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free online editions of InTech Book
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VI Contents Chapter 9 Targeted Magn
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X Preface stand-alone and readers c
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2 Biomedical Engineering - From The
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4 Fig. 2. Process for retrieval inf
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6 Biomedical search engine Scientif
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8 Biomedical Engineering - From The
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10 Biomedical Engineering - From Th
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12 Bireme http://regional.bv salud.
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14 Semantic Networks analysis Biome
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100 Biomedical Engineering - From T
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108 Method (Detection) CIEF-tITP-CZ
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110 Method (Detection) Analyte Matr
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120 6. Conclusion Biomedical Engine
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150 5. Conclusions Biomedical Engin
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162 1 st phase : half year 4 2 nd p
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166 7. Innovative active training B
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172 12. Maturing projects’ story
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180 16. Acknowledgments Biomedical
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190 R* M M M M MR*M O O O O M O R*
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196 Fig. 9. Chemical structure of 5
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198 Relative Intensity (AU) Biomedi
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204 2. Preparation of IO nanopartic
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256 3. Deposition techniques Biomed
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300 2. Nanoparticles in biomedical
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478 Load F (μN) Parallel-oriented
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