Biomedical Engineering – From Theory to Applications

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426 Biomedical Engineering – From Theory to Applications Bou-Saleh, Z., Shahryari, A., & Omanovic, S. (2007). Thin Sol Film, 515, 4727. Brandes, E.A. & Brook, G.B. (1992). Smithells Metals Reference Book. 7th ed. Oxford, Butterworth-Heinemann. Browne, M., & Gregson, P.J. (2000). Effect of mechanical surface pretreatment on metal ion release. Biomaterials, 21, 385. Brune, D. (1986). Metal release from dental biomaterialsm, Biomaterials, 7, 163. Buford, A., & Goswami, T. (2004). Review of wear mechanisms in hip implants: Paper I – General. Mater Des, 25, 385. Campbel, F.C. (2006). Manufacturing Technology for Aerospace Structural, Elsevier. Chan S.Y., Park, C.H., & Moriwaki. T. (2010). Mirror finishing of CoCrMo alloy using elliptical vibration cutting. Prec Eng, 34, 784. Chen, Q., Liu, L. & Zhang, S.-M. (2010). The potential of Zr-based bulk metallic glasses as biomaterials. Front Mater Sci China, 4, 34. Chiba, A., Lee, S.-H., Matsumoto, H. & Nakamura, M. (2009). Construction of processing map for biomedical Co28Cr6Mo0.16N alloy by studying its hot deformation behavior using compression tests. Mater Sci Eng A, 513-514, 286. Dearnley, P.A., Dahma, K.L., & Çimenoglu, H. (2004). The corrosion–wear behaviour of thermally oxidised CP-Ti and Ti6Al4V. Wear, 256, 469. Dewidar, M.M., Khalil, K.A, & Lim J.K. (2007). Processing and mechanical properties of porous 316L stainless steel for biomedical applications, Trans Nonferrous Met Soc China, 17, 468. Di Mario, C., Griffiths, H., Goktekin, O., Peeters, N., Verbist, J., Bosiers, M., Deloose, K., Heublein, B., Rohde, R., Kasese, V., Ilsley, C. & Erbel, R. (2004). Drug-eluting bioabsorbable magnesium stent. J Interv Cardiol, 17, 391. Ferrari, F., Miotello, A., Pavloski, L., Galvanetto, E., Moschini, G., Galassini, S., Passi, P., Bogdanovie, S., Fazini, S., Jaksi, M., & Valkovi, V. (1993). Metal-ion release. from Ti and TiN coated implants in rat bone. Nuclear Instr Meth Phys Res B, 79, 421. Fleck, C., & Eifler, D. (2010). Corrosion, fatigue and corrosion fatigue behaviour of metal implant materials, especially Ti alloys. Intl J Fatigue, 32, 929. Geringera, J., Foresta, B., & Combrade, P. (2005). Fretting-corrosion of materials used as orthopaedic implants, Wear, 259, 943. Germain, L., Gey, N., Humbert, M., Vob, P., Jahazi, M., & Bocher, P. (2008). Texture heterogeneities induced by subtransus processing of near a Ti alloys. Acta Mater, 56, 4298. Goodfellow (2007). Iron (Fe) - Material information. Goodfellow Corporation. Habibovic, P., Barrère, F., Blitterswijk, C.A.V., Groot, K.D. & Layrolle, P. (2002). Biomimetic hydroxyapatite coating on metal implants. J Am Ceram Soc, 83, 517. Han, Y.S., & Hong, S.H. (1999). Microstructural changes during superplastic deformation of Fe24Cr7Ni3Mo0.14N duplex stainless steel. Mater Sci Eng A, 266, 276. Hanawa, T. (2004). Metal ion release from metal implants, Mater Sci Eng C, 24, 745. Hänzi, A.C., Sologubenko, A.S. & Uggowitzer, P.J. (2009). Design strategy for microalloyed ultra-ductile magnesium alloys for medical applications. Mater Sci Forum, 618-619, 75. Harman, M.K., Banks, S.A., & Hodge, W.A. (1997). Wear analysis of a retrieved hip implant with titanium nitride coating. J Arthroplast, 12, 938.
Metals for Biomedical Applications Hermawan, H. & Mantovani, D. (2009). Degradable metallic biomaterials: The concept, current developments and future directions. Minerv Biotecnol, 21, 207. Hermawan, H., Alamdari, H., Mantovani, D. & Dubé, D. (2008). Iron-manganese: New class of degradable metallic biomaterials prepared by powder metallurgy. Powder Metall, 51, 38. Hermawan, H., Dubé, D. & Mantovani, D. (2010). Developments in metallic biodegradable stents. Acta Biomater, 6, 1693. Heublein, B., Rohde, R., Kaese, V., Niemeyer, M., Hartung, W. & Haverich, A. (2003). Biocorrosion of magnesium alloys: A new principle in cardiovascular implant technology? Heart, 89, 651. Hollander, D.A., Von Walter, M., Wirtz, T., Sellei, R., Schmidt-Rohlfing, B., Paar, O. & Erli, H.-J. (2006). Structural, mechanical and in vitro characterization of individually structured Ti6Al4V produced by direct laser forming. Biomaterials, 27, 955. Hu, Z.M., Brooks, J.W., & Dean, T.A. (1999). Experimental and theoretical analysis of deformation and microstructural evolution in the hot-die forging of Ti alloy aerofoil sections. J Mater Proc Technol, 88, 251. Huang, J.C., & Chuang, T.H. (1999). Progress on superplasticity and superplastic forming in Taiwan during 1987-1997. Mater Chem Phys, 57, 195. Karla, M., & Kelly, J.R. (2009). Influence of loading frequency on implant failure under cyclic fatigue conditions. Dent Mater, 25, 1426. Kern, M., & Thompson, V.P. (1993). Sandblasting and silica-coating of dental alloys: volume loss, morphology and changes in the surface composition. Dent Mater, 9, 155. Kohn, D.H. (1998). Metals in medical applications, Curr Op Solid State Mater Sci, 3, 309. Komotori, L.J., Hisamori, N., & Ohmoric, Y. (2007). The corrosion/wear mechanisms of Ti6Al4V alloy for different scratching rates. Wear, 263, 412. Krishna, V.G., Prasad, Y.V.R.K., Birla, N.C., & Rao, G.S. (1997). Processing map for the hot working near-alpha Ti alloy 685. J Mater Proc Technol, 71, 377. Kubiak, K., & Sieniaski, J. (1998). Development of the microstructure and fatigue strength of two phase Ti alloys in the processes of forging and heat treatment. J Mater Proc Technol, 78, 117. Kumar, S., & Narayanan, T.S.N.S. (2008). Corrosion behaviour of Ti15Mo alloy for dental implant applications. J Dentist, 36, 500. Kumar, S., Narayanan, T.S.N.S., Raman, S.G.S., & Seshadri, S.K. (2010). Evaluation of fretting corrosion behaviour of CP-Ti for orthopaedic implant applications, Tribol Intl, 43, 1245. Kuroda, D., Niinomi, M., Morinaga, M., Kato, Y. & Yashiro, T. (1998). Design and mechanical properties of new [beta] type Ti alloys for implant materials. Mater Sci Eng A, 243, 244. Kwok, C.T., Cheng, F.T., & Man, H.C. (2003). Effect of processing conditions on the corrosion performance of laser surface-melted AISI 440C martensitic stainless steel. Surf Coat Technol, 166, 221. Lahann, J., Klee, D., Thelen, H., Bienert, H., Vorwerk, D. & Hocker, H. (1999). Improvement of haemocompatibility of metallic stents by polymer coating. J Mater Sci Mater Med, 10, 443. Lambotte, A. (1909). Technique et indication des prothèses dans le traitement des fractures. Presse Med, 17, 321. 427
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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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