Biomedical Engineering – From Theory to Applications

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408 Biomedical Engineering – From Theory to Applications Pardoe, H., Clark, P. R., St Pierre, T. G., Moroz, P. & Jones, S. K. (2003). A magnetic resonance imaging based method for measurement of tissue iron concentration in liver arterially embolized with ferrimagnetic particles designed for magnetic hyperthermia treatment of tumors. Magnetic Resonance Imaging 21(5): 483-488. Patil, S., Sandberg, A., Heckert, E., Self, W. & Seal, S. (2007). Protein adsorption and cellular uptake of cerium oxide nanoparticles as a function of zeta potential. Biomaterials 28: 4600-4607. Perez, J. M., Josephson, L., O'Loughlin, T., Hogemann, D. & Weissleder, R. (2002). Magnetic relaxation switches capable of sensing molecular interactions. Nature Biotechnology 20(8): 816-820. Pileri, P., Uematsu, Y., Campagnoli, S., Galli, G., Falugi, F., Petracca, R., Weiner, A. J., Houghton, M., Rosa, D., Grandi, G. & Abrignani, S. (1998). Binding of hepatitis C virus to CD81. Science 282(5390): 938-941. Plank, C., Schillinger, U., Scherer, F., Bergemann, C., Remy, J. S., Krotz, F., Anton, M., Lausier, J. & Rosenecker, J. (2003). The magnetofection method: Using magnetic force to enhance gene delivery. Biological Chemistry 384(5): 737-747. Prasad, B. L. V., Stoeva, S. I., Sorensen, C. M., Zaikovski, V. & Klabunde, K. J. (2003). Gold nanoparticles as catalysts for polymerization of alkylsilanes to siloxane nanowires, filaments, and tubes. Journal of the American Chemical Society 125(35): 10488-10489. Sawakami-Kobayashi, K., Segawa, O., Obata, K., Hornes, E., Yohda, M., Tajima, H. & Machida, M. (2003). Multipurpose robot for automated cycle sequencing. Biotechniques 34(3): 634-637. Schotter, J., Kamp, P. B., Becker, A., Puhler, A., Reiss, G. & Bruckl, H. (2004). Comparison of a prototype magnetoresistive biosensor to standard fluorescent DNA detection. Biosensors & Bioelectronics 19(10): 1149-1156. Schratzberger, P., Reinisch, N., Prodinger, W. M., Kahler, C. M., Sitte, B. A., Bellmann, R., FischerColbrie, R., Winkler, H. & Wiedermann, C. J. (1997). Differential chemotactic activities of sensory neuropeptides for human peripheral blood mononuclear cells. Journal of Immunology 158(8): 3895-3901. Schwalbe, M., Pachmann, K., Hoffken, K. & Clement, J. H. (2006). Improvement of the separation of tumour cells from peripheral blood cells using magnetic nanoparticles. Journal of Physics-Condensed Matter 18(38): S2865-S2876. Stampfli, M. R., Miescher, S., Aebischer, I., Zurcher, A. W. & Stadler, B. M. (1994). Inhibition of human IgE synthesis by anti-IgE antibodies requires divalent recognition. European Journal of Immunology 24(9): 2161-2167. Takahashi, M., Yoshino, T. & Matsunaga, T. (2010). Surface modification of magnetic nanoparticles using asparagines-serine polypeptide designed to control interactions with cell surfaces. Biomaterials 31(18): 4952-4957. Tanaka, T., Maruyama, K., Yoda, K., Nemoto, E., Udagawa, Y., Nakayama, H., Takeyama, H. & Matsunaga, T. (2003). Development and evaluation of an automated workstation for single nucleotide polymorphism discrimination using bacterial magnetic particles. Biosensors & Bioelectronics 19(4): 325-330.
The Potential of Genetically Engineered Magnetic Particles in Biomedical Applications Tanaka, T. & Matsunaga, T. (2000). Fully automated chemiluminescence immunoassay of insulin using antibody-protein A-bacterial magnetic particle complexes. Analytical Chemistry 72(15): 3518-3522. Tanaka, T., Takeda, H., Kokuryu, Y. & Matsunaga, T. (2004). Spontaneous integration of transmembrane peptides into a bacterial magnetic particle membrane and its application to display of useful proteins. Analytical Chemistry 76(13): 3764-3769. Tiwari, A., Punshon, G., Kidane, A., Hamilton, G. & Seifalian, A. M. (2003). Magnetic beads (Dynabead) toxicity to endothelial cells at high bead concentration: Implication for tissue engineering of vascular prosthesis. Cell Biology and Toxicology 19(5): 265-272. Ugelstad, J., Berge, A., Ellingsen, T., Aune, O., Kilaas, L., Nilsen, T. N., Schmid, R., Stenstad, P., Funderud, S., Kvalheim, G., Nustad, K., Lea, T., Vartdal, F. & Danielsen, H. (1988). Monosized magnetic particles and their use in selective cell separation. Makromolekulare Chemie-Macromolecular Symposia 17: 177-211. Weissleder, R., Kelly, K., Sun, E. Y., Shtatland, T. & Josephson, L. (2005). Cell-specific targeting of nanoparticles by multivalent attachment of small molecules. Nature Biotechnology 23: 1418-1423. Wright, L. D., Cresson, E. L., Skeggs, H. R., Wood, T. R., Peck, R. L., Wolf, D. E. & Folkers, K. (1952). Isolation of crystalline biocytin from yeast extract. Journal of the American Chemical Society 74(8): 1996-1999. Xu, C. J., Xu, K. M., Gu, H. W., Zhong, X. F., Guo, Z. H., Zheng, R. K., Zhang, X. X. & Xu, B. (2004). Nitrilotriacetic acid-modified magnetic nanoparticles as a general agent to bind histidine-tagged proteins. Journal of the American Chemical Society 126(11): 3392-3393. Xu, L., Yu, H., Akhras, M. S., Han, S. J., Osterfeld, S., White, R. L., Pourmand, N. & Wang, S. X. (2008). Giant magnetoresistive biochip for DNA detection and HPV genotyping. Biosensors & Bioelectronics 24(1): 99-103. Yoshino, T., Kaji, C., Nakai, M., Saito, F., Takeyama, H. & Matsunaga, T. (2008). Novel method for evaluation of chemicals based on ligand-dependent recruitment of GFP labeled coactivator to estrogen receptor displayed on bacterial magnetic particles. Analytica Chimica Acta 626(1): 71-77. Yoshino, T., Kato, F., Takeyama, H., Nakai, M., Yakabe, Y. & Matsunaga, T. (2005). Development of a novel method for screening of estrogenic compounds using nano-sized bacterial magnetic particles displaying estrogen receptor. Analytica Chimica Acta 532(2): 105-111. Yoshino, T. & Matsunaga, T. (2005). Development of efficient expression system for protein display on bacterial magnetic particles. Biochemical and Biophysical Research Communications 338(4): 1678-1681. Yoshino, T. &Matsunaga, T. (2006). Efficient and stable display of functional proteins on bacterial magnetic particles using Mms13 as a novel anchor molecule. Applied and Environmental Microbiology 72(1): 465-471. Yoshino, T., Nishimura, T., Mori, T., Suzuki, S., Kambara, H., Takeyama, H. & Matsunaga, T. (2009). Nano-sized bacterial magnetic particles displaying pyruvate phosphate dikinase for pyrosequencing. Biotechnology and Bioengineering 103(1): 130-137. 409
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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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472 Nb b b l l1 Biomedical Engineer
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478 Load F (μN) Parallel-oriented
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