| Contributors |
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xiii | |
| Preface |
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xix | |
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1 Magneto-controlled enzyme reactions |
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1 | (24) |
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1 Introduction: Signal-controlled artificial biomolecular systems |
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2 | (2) |
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2 Bioelectrocatalytic reactions performed with enzymes conjugated to magnetic microparticles and controlled by external magnetic field |
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4 | (3) |
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3 Assembling conducting nanowires from magnetic nanoparticles in the presence of external magnetic field |
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7 | (2) |
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4 Magneto-controlled enzyme biocatalytic cascades: Substrate channeling vs. free diffusion |
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9 | (5) |
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5 Magnetohydrodynamic effect applied to enzyme bioelectrocatalytic reactions |
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14 | (3) |
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17 | (4) |
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21 | (1) |
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21 | (1) |
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21 | (4) |
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2 Functionalization of multiwalled carbon nanotubes for enzyme immobilization |
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25 | (14) |
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26 | (1) |
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2 Multiwalled carbon nanotubes |
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27 | (2) |
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29 | (6) |
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35 | (1) |
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36 | (1) |
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36 | (3) |
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3 Immobilization of enzymes on iron oxide magnetic nanoparticles: Synthesis, characterization, kinetics and thermodynamics |
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39 | (42) |
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40 | (4) |
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44 | (6) |
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3 Instrumental characterization of nanoparticles before and after immobilization of enzymes |
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50 | (3) |
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4 Determination of operating parameters |
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53 | (1) |
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53 | (2) |
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6 Thermal inactivation kinetics |
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55 | (1) |
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56 | (1) |
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8 Reusability of immobilized enzymes |
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57 | (1) |
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57 | (18) |
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10 Summary and conclusion |
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75 | (1) |
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76 | (1) |
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76 | (3) |
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79 | (2) |
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4 Strategies to rationalize enzyme immobilization procedures |
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81 | (30) |
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Caterina G.C. Marques Netto |
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82 | (2) |
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84 | (17) |
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3 Proposition of an enzyme immobilization database |
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101 | (2) |
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103 | (1) |
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104 | (1) |
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104 | (1) |
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104 | (7) |
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5 Fibrous polymer functionalized magnetic biocatalysts for improved performance |
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111 | (22) |
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112 | (3) |
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115 | (6) |
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3 Magnetic nanoparticles conjugate properties |
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121 | (4) |
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4 Stability, reusability and efficiency |
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125 | (5) |
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130 | (1) |
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131 | (1) |
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131 | (2) |
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6 Improvement in biochemical characteristics of cross-linked enzyme aggregates (CLEAs) with magnetic nanoparticles as support matrix |
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133 | (26) |
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134 | (5) |
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139 | (15) |
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154 | (1) |
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155 | (1) |
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155 | (3) |
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158 | (1) |
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7 Magnetic bead-based semi-automated phage display panning strategy for the directed evolution of antibodies |
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159 | (20) |
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160 | (1) |
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2 Magnetic nanoparticle-based panning protocol |
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161 | (14) |
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3 Other phage display application of KingFisher |
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175 | (1) |
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176 | (1) |
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176 | (1) |
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176 | (2) |
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178 | (1) |
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8 On-bead enzyme-catalyzed signal amplification for the high-sensitive detection of disease biomarkers |
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179 | (20) |
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180 | (8) |
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188 | (6) |
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3 Conclusion and perspective |
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194 | (1) |
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194 | (1) |
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195 | (4) |
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9 Organophosphonate functionalized Au/Si@Fe304: Versatile carrier for enzyme immobilization |
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199 | (16) |
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200 | (3) |
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203 | (5) |
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3 Results and discussions |
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208 | (3) |
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211 | (1) |
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211 | (1) |
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211 | (3) |
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214 | (1) |
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10 Bioelectrocatalysis at carbon nanotubes |
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215 | (34) |
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1 Introduction: Structural and electrochemical properties of carbon nanotubes |
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216 | (3) |
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2 Enzyme immobilization at carbon nanotubes |
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219 | (2) |
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3 Bioelectrocatalysis at carbon nanotubes |
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221 | (2) |
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4 Homogeneous dispersion of carbon nanotubes by using room temperature ionic liquids (RTILs) |
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223 | (6) |
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5 Rational grafting of carbon nanotubes for enzyme immobilization |
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229 | (7) |
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6 Electrodeposition of gold-carbon nanotubes composites for enhanced bioelectrocatalysis |
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236 | (5) |
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241 | (1) |
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241 | (1) |
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241 | (8) |
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11 Molecular wiring of glucose oxidase enzyme with Mn polypyridine complex on MWCNT modified electrode surface and its bio electrocatalytic oxidation and glucose sensing |
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249 | (14) |
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250 | (4) |
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254 | (2) |
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3 Characterization of the f-MWCNT@[ Mn2(phen)4(0)CI2]2+-Nf@GOx |
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256 | (2) |
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4 Bioelectrocatalytic application of GOx modified electrode |
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258 | (2) |
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260 | (1) |
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260 | (1) |
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260 | (3) |
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12 Use of functionalized carbon nanotubes for the development of robust nanobiocatalysts |
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263 | (40) |
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265 | (3) |
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268 | (5) |
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3 Interactions between CNTs and proteins |
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273 | (12) |
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4 Characterization of CNTs-enzyme conjugates |
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285 | (6) |
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5 Stability and reusability of nanobiocatalysts |
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291 | (4) |
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295 | (1) |
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296 | (1) |
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296 | (7) |
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13 Biocatalytic hydrogenations on carbon supports |
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303 | (24) |
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304 | (2) |
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2 Carbon immobilized enzymes for redox biocatalysis |
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306 | (6) |
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3 Carbon nanotube supported biocatalysis in flow |
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312 | (4) |
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316 | (6) |
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322 | (1) |
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323 | (1) |
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323 | (4) |
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14 Nano-immobilized cellulases for biomass processing with application in biofuel production |
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327 | (20) |
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328 | (4) |
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332 | (2) |
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3 Immobilization of cellulases |
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334 | (6) |
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4 Reusability of immobilized enzyme |
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340 | (1) |
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5 Application of nanomaterial immobilized enzyme |
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341 | (2) |
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343 | (1) |
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344 | (1) |
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344 | (1) |
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344 | (3) |
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15 Few biomedical applications of carbon nanotubes |
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347 | (18) |
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348 | (1) |
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2 Synthesis and purification of MWCNTs |
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349 | (2) |
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3 Biomedical applications |
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351 | (1) |
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4 CNTs as immobilization matrix for biomolecules |
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351 | (4) |
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355 | (1) |
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6 Enzymatic biosensors developed in our lab using MWCNTs |
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356 | (3) |
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359 | (2) |
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361 | (4) |
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16 Multiwalled carbon nanotubes bound beta-galactosidase: It's activity, stability and reusability |
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365 | (42) |
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366 | (12) |
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378 | (6) |
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384 | (12) |
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396 | (2) |
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398 | (6) |
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404 | (3) |
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17 Exfoliated and water dispersible biocarbon nanotubes for enzymology applications |
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407 | (24) |
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408 | (4) |
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412 | (5) |
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3 Preparation of bioCNT-HRP complex and enzyme immobilization studies |
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417 | (2) |
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419 | (8) |
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427 | (2) |
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429 | (1) |
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429 | (2) |
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18 Stabilization of phytase on multi-walled carbon nanotubes via covalent immobilization |
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431 | (22) |
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Mohammad Pooya Naghshbandi |
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432 | (4) |
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2 Equipment, materials and procedures |
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436 | (13) |
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449 | (1) |
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449 | (4) |
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19 A simple magnetic nanoparticle-poly-enzyme nanobead sandwich assay for direct, ultrasensitive DNA detection |
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453 | (28) |
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454 | (13) |
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467 | (10) |
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477 | (1) |
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478 | (1) |
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478 | (2) |
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480 | (1) |
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20 Enzymes immobilization onto magnetic nanoparticles to improve industrial and environmental applications |
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481 | (17) |
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482 | (6) |
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2 Magnetic nanoparticles properties |
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488 | (2) |
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3 Methodologies for enzyme immobilization on MNPs |
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490 | (2) |
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4 Mechanisms of enzyme immobilization onto MNPs |
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492 | (1) |
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5 Immobilization of peroxidase on modified magnetic nanoparticles |
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493 | (1) |
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6 Characterization of immobilized enzymes onto MNPs |
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494 | (1) |
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7 Evaluation of immobilized enzymes |
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495 | (2) |
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8 Enzymatic bioremediation of textile industry wastewater containing direct green or reactive red azo dye |
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497 | (1) |
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498 | (1) |
| References |
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498 | |
Lisainfo e-raamatute kohta