| Preface |
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xiii | |
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1 Amperometric Biosensors |
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1 | (84) |
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1 | (22) |
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1.1.1 Definition of the Term "Biosensor" |
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3 | (4) |
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1.1.2 Milestones and Achievements Relevant to Biosensor Research and Development |
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7 | (1) |
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1.1.3 "First-Generation" Biosensors |
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7 | (1) |
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1.1.4 "Second-Generation" Biosensors |
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7 | (6) |
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1.1.5 "Third-Generation" Biosensors |
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13 | (2) |
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1.1.6 Reagentless Biosensor Architectures |
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15 | (3) |
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1.1.7 Parameters with a Major Impact on Overall Biosensor Response |
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18 | (4) |
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1.1.8 Application Areas of Biosensors |
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22 | (1) |
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1.2 Criteria for "Good" Biosensor Research |
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23 | (2) |
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1.3 Defining a Standard for Characterizing Biosensor Performances |
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25 | (3) |
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1.4 Success Stories in Biosensor Research |
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28 | (27) |
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1.4.1 Direct ET Employed for Biosensors and Biofuel Cells |
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29 | (3) |
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1.4.2 Direct ET with Glucose Oxidase |
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32 | (4) |
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1.4.3 Mediated ET Employed for Biosensors and Biofuel Cells |
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36 | (2) |
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1.4.4 Nanomaterials and Biosensors |
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38 | (1) |
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1.4.4.1 Modification of Macroscopic Transducers with Nanomaterials |
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39 | (2) |
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1.4.4.2 Nanometric Transducers |
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41 | (1) |
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1.4.4.3 Modification of Biomolecules with Nanomaterials |
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42 | (1) |
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1.4.5 Implanted Biosensors for Medical Research and Health Check Applications |
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42 | (6) |
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1.4.6 Nucleic Acid-Based Biosensors: Nucleic Acid Chips, Arrays, and Microarrays |
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48 | (4) |
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52 | (1) |
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1.4.7.1 Labeled Approaches |
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53 | (1) |
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1.4.7.2 Nonlabeled Approaches |
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54 | (1) |
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55 | (30) |
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56 | (1) |
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57 | (1) |
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57 | (4) |
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61 | (24) |
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2 Imaging of Single Biomolecules by Scanning Tunneling Microscopy |
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85 | (58) |
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85 | (2) |
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2.2 Interfacial Electron Transfer in Molecular and Protein Film Voltammetry |
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87 | (5) |
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2.2.1 Theoretical Notions of Interfacial Chemical and Bioelectrochemical Electron Transfer |
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88 | (2) |
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2.2.2 Nuclear Reorganization Free Energy |
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90 | (1) |
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2.2.3 Electronic Tunneling Factor in Long-Range Interfacial (Bio)electrochemical Electron Transfer |
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90 | (2) |
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2.3 Theoretical Notions in Bioelectrochemistry towards the Single-Molecule Level |
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92 | (5) |
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2.3.1 Biomolecules in Nanoscale Electrochemical Environment |
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92 | (1) |
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2.3.2 Theoretical Frameworks and Interfacial Electron Transfer Phenomena |
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92 | (1) |
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2.3.2.1 Redox (Bio)molecules in Electrochemical STM and Other Nanogap Configurations |
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93 | (2) |
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2.3.2.2 New Interfacial (Bio)electrochemical Electron Transfer Phenomena |
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95 | (2) |
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2.4 In Situ Imaging of Bio-related Molecules and Linker Molecules for Protein Voltammetry with Single-Molecule and Sub-molecular Resolution |
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97 | (10) |
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2.4.1 Imaging of Nucleobases and Electronic Conductivity of Short Oligonucleotides |
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97 | (1) |
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2.4.2 Functionalized Alkanethiols and the Amino Acids Cysteine and Homocysteine |
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98 | (2) |
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2.4.2.1 Functionalized Alkanethiols as Linkers in Metalloprotein Film Voltammetry |
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100 | (2) |
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2.4.2.2 In Situ STM of Cysteine and Homocysteine |
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102 | (2) |
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2.4.2.3 Theoretical Computations and STM Image Simulations |
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104 | (1) |
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2.4.3 Single-Molecule Imaging of Bio-related Small Redox Molecules |
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105 | (2) |
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2.5 Imaging of Intermediate-Size Biological Structures: Lipid Membranes and Insulin |
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107 | (5) |
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2.5.1 Biomimetic Mono- and Bilayer Membranes on Au(111) Electrode Surfaces |
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107 | (2) |
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2.5.2 Monolayers of Human Insulin on Different Low-Index Au Electrode Surfaces Mapped to Single-Molecule Resolution by In Situ STM |
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109 | (3) |
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2.6 Interfacial Electrochemistry and In Situ Imaging of Redox Metalloproteins and Metalloenzymes at the Single-Molecule Level |
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112 | (11) |
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2.6.1 Metalloprotein Voltammetry at Bare and Modified Electrodes |
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112 | (1) |
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2.6.2 Single-Molecule Imaging of Functional Electron Transfer Metalloproteins by In Situ STM |
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112 | (2) |
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2.6.2.1 Small Redox Metalloproteins: Blue Copper, Heme, and Iron-Sulfur Proteins |
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114 | (1) |
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2.6.2.2 Single-Molecule Tunneling Spectroscopy of Wild-Type and Cys Mutant Cytochrome b562 |
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114 | (2) |
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2.6.2.3 Cytochrome c4: A Prototype for Microscopic Electronic Mapping of Multicenter Redox Metalloproteins |
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116 | (3) |
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2.6.2.4 Redox Metalloenzymes in Electrocatalytic Action Imaged at the Single-Molecule Level: Multicopper and Multiheme Nitrite Reductases |
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119 | (1) |
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2.6.2.5 Au-Nanoparticle Hybrids of Horse Heart Cytochrome c and P. aeruginosa Azurin |
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120 | (3) |
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2.7 Some Concluding Observations and Outlooks |
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123 | (20) |
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126 | (1) |
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126 | (17) |
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3 Applications of Neutron Reflectivity in Bioelectrochemistry |
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143 | (46) |
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143 | (1) |
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3.2 Theoretical Aspects of Neutron Scattering |
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144 | (10) |
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144 | (1) |
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3.2.2 Scattering from a Single Nucleus |
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145 | (2) |
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3.2.2.1 The Fermi Pseudo Potential |
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147 | (1) |
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3.2.3 Scattering from a Collection of Nuclei |
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147 | (1) |
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3.2.3.1 Neutron Scattering Cross Sections |
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147 | (1) |
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3.2.3.2 Coherent and Incoherent Scattering |
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148 | (1) |
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3.2.3.3 Effective Potential and Scattering Length Density |
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148 | (1) |
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3.2.4 Theoretical Expressions for Specular Reflectivity |
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149 | (1) |
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3.2.4.1 The Continuum Limit |
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149 | (2) |
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3.2.4.2 The Kinematic Approach |
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151 | (3) |
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154 | (14) |
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3.3.1 Experimental Aspects of Reflectometer Operation |
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154 | (3) |
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3.3.2 Substrate Preparation and Characterization |
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157 | (3) |
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3.3.3 Cell Design and Assembly |
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160 | (2) |
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3.3.4 Data Acquisition and Analysis |
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162 | (6) |
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168 | (14) |
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3.4.1 Supported Proteins, Peptides, and Membranes without Potential Control |
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168 | (1) |
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3.4.1.1 Quartz- and Silicon-Supported Bilayers |
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168 | (2) |
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3.4.1.2 Hybrid Bilayers on Solid Supports |
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170 | (3) |
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3.4.1.3 Protein Adsorption and DNA Monolayers |
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173 | (2) |
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3.4.2 Electric Field-Driven Transformations in Supported Model Membranes |
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175 | (7) |
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3.5 Summary and Future Aspects |
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182 | (7) |
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184 | (1) |
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185 | (4) |
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4 Model Lipid Bilayers at Electrode Surfaces |
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189 | (40) |
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189 | (1) |
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4.2 Biomimetic Membranes: Scope and Requirements |
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189 | (3) |
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4.3 Electrochemical Impedance Spectroscopy |
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192 | (2) |
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4.4 Formation of Lipid Films in Biomimetic Membranes |
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194 | (7) |
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196 | (2) |
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4.4.2 Langmuir-Blodgett and Langmuir-Schaefer Transfer |
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198 | (2) |
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4.4.3 Rapid Solvent Exchange |
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200 | (1) |
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4.4.4 Fluidity in Biomimetic Membranes |
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201 | (1) |
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4.5 Various Types of Biomimetic Membranes |
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201 | (21) |
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4.5.1 Solid-Supported Bilayer Lipid Membranes |
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201 | (2) |
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4.5.2 Tethered Bilayer Lipid Membranes |
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203 | (1) |
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4.5.2.1 Spacer-Based tBLMs |
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204 | (1) |
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4.5.2.2 Thiolipid-Based tBLMs |
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205 | (10) |
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4.5.2.3 Thiolipid-Spacer-Based tBLMs |
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215 | (1) |
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4.5.3 Polymer-Cushioned Bilayer Lipid Membranes |
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216 | (2) |
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4.5.4 S-Layer Stabilized Bilayer Lipid Membranes |
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218 | (2) |
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4.5.5 Protein-Tethered Bilayer Lipid Membranes |
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220 | (2) |
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222 | (7) |
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223 | (1) |
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223 | (6) |
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229 | (40) |
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229 | (6) |
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5.1.1 Enzymatic Fuel Cell Design |
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231 | (1) |
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5.1.2 Enzyme Electron Transfer |
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231 | (4) |
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5.2 Bioanodes for Glucose Oxidation |
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235 | (8) |
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243 | (12) |
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5.4 Assembled Biofuel Cells |
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255 | (4) |
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5.5 Conclusions and Future Outlook |
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259 | (10) |
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261 | (1) |
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262 | (7) |
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6 Raman Spectroscopy of Biomolecules at Electrode Surfaces |
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269 | (66) |
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269 | (1) |
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270 | (2) |
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6.3 SERS and Surface-Enhanced Resonant Raman Spectroscopy |
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272 | (4) |
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6.4 Comparison of SE(R)RS and Fluorescence for Biological Studies |
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276 | (2) |
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278 | (2) |
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280 | (1) |
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6.7 SERS Surfaces for Electrochemistry |
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281 | (10) |
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6.8 Tip-Enhanced Raman Spectroscopy |
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291 | (1) |
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6.9 SE(R)RS of Biomolecules |
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292 | (23) |
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6.9.1 DNA Bases, Nucleotides, and Their Derivatives |
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292 | (4) |
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6.9.2 DNA and Nucleic Acids |
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296 | (3) |
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6.9.3 Amino Acids and Peptides |
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299 | (4) |
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6.9.4 Proteins and Enzymes |
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303 | (1) |
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303 | (4) |
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307 | (1) |
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308 | (2) |
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6.9.5 Membranes, Lipids, and Fatty Acids |
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310 | (1) |
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6.9.6 Metabolites and Other Small Molecules |
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311 | (1) |
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6.9.6.1 Neurotransmitters |
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311 | (1) |
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6.9.6.2 Nicotinamide Adenine Dinucleotide |
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312 | (1) |
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6.9.6.3 Flavin Adenine Dinucleotide |
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313 | (2) |
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315 | (1) |
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315 | (1) |
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315 | (20) |
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316 | (19) |
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7 Membrane Electroporation in High Electric Fields |
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335 | (34) |
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335 | (3) |
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7.1.1 Giant Vesicles as Model Membrane Systems |
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335 | (2) |
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7.1.2 Mechanical and Rheological Properties of Lipid Bilayers |
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337 | (1) |
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7.2 Electrodeformation and Electroporation of Membranes in the Fluid Phase |
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338 | (4) |
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7.3 Response of Gel-Phase Membranes |
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342 | (3) |
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7.4 Effects of Membrane Inclusions and Media on the Response and Stability of Fluid Vesicles in Electric Fields |
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345 | (5) |
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7.4.1 Vesicles in Salt Solutions |
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345 | (2) |
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7.4.2 Vesicles with Cholesterol-Doped Membranes |
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347 | (2) |
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7.4.3 Membranes with Charged Lipids |
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349 | (1) |
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7.5 Application of Vesicle Electroporation |
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350 | (7) |
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7.5.1 Measuring Membrane Edge Tension from Vesicle Electroporation |
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350 | (3) |
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7.5.2 Vesicle Electrofusion |
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353 | (1) |
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7.5.2.1 Fusing Vesicles with Identical or Different Membrane Composition |
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353 | (2) |
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7.5.2.2 Vesicle Electrofusion: Employing Vesicles as Microreactors |
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355 | (2) |
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7.6 Conclusions and Outlook |
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357 | (12) |
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358 | (1) |
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358 | (11) |
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8 Electroporation for Medical Use in Drug and Gene Electrotransfer |
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369 | (20) |
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369 | (1) |
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8.2 A List of Definitions |
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370 | (1) |
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8.3 How We Understand Permeabilization at the Cellular and Tissue Level |
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371 | (3) |
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8.4 Basic Aspects of Electroporation that are of Particular Importance for Medical Use |
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374 | (3) |
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374 | (1) |
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375 | (1) |
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8.4.3 Delivery of Other Molecules |
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376 | (1) |
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8.4.4 Delivery of Electric Pulses |
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376 | (1) |
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8.4.5 End of the Permeabilized State |
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376 | (1) |
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377 | (1) |
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8.5 How to Deliver Electric Pulses in Patient Treatment |
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377 | (1) |
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8.5.1 Pulse Generators and Electrodes |
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377 | (1) |
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377 | (1) |
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8.6 Treatment and Post-treatment Management |
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378 | (1) |
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8.7 Clinical Results with Electrochemotherapy |
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378 | (2) |
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8.7.1 Tumors Up to Three Centimeters in Size |
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378 | (2) |
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380 | (1) |
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8.8 Use in Internal Organs |
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380 | (1) |
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381 | (1) |
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381 | (1) |
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8.8.3 Brain Metastases, Brain Tumors, and Other Tumors in Soft Tissues |
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381 | (1) |
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381 | (1) |
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381 | (5) |
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8.9.1 Gene Electrotransfer to Muscle |
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383 | (1) |
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8.9.2 Gene Electrotransfer to Skin |
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383 | (1) |
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8.9.3 Gene Electrotransfer to Tumors |
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384 | (1) |
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8.9.4 Gene Electrotransfer to Other Tissues |
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385 | (1) |
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386 | (3) |
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386 | (3) |
| Index |
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389 | |
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