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<b>Preface xv<br /> <br /> </b><b>Part 1: New Materials and Methods 1<br /> <br /> </b><b>1 ZnO and Graphene Microelectrode Applications in Biosensing 3<br /> </b><i>Susana Campuzano, María Pedrero, Georgia-Paraskevi Nikoleli, José M. Pingarron, Dimitrios P. Nikolelis, Nikolaos Tzamtzis and Vasillios N. Psychoyios<br /> <br /> </i>1.1 Biosensors Based on Nanostructured Materials 4<br /> <br /> 1.2 Graphene Nanomaterials Used in ElectrochemicalBiosensor Fabrication 5<br /> <br /> 1.3 ZnO Nanostructures Used in the Fabrication of Electrochemical Biosensors 7<br /> <br /> 1.4 Miniaturized Graphene and ZnO Nanostructured Electrochemical Biosensors for Food and Clinical Applications 10<br /> <br /> 1.5 Conclusions and Future Prospects 30<br /> <br /> Acknowledgements 32<br /> <br /> References 32<br /> <br /> <b>2 Assembly of Polymers/Metal Nanoparticles and Their Applications as Medical Devices 37<br /> </b><i>Magdalena Stevanovic<br /> <br /> </i>2.1 Introduction 38<br /> <br /> 2.2 Platinum Nanoparticles 40<br /> <br /> 2.3 Gold Nanoparticles 41<br /> <br /> 2.4 Silver Nanoparticles 44<br /> <br /> 2.5 Assembly of Polymers/Silver Nanoparticles 45<br /> <br /> 2.6 Conclusion 51<br /> <br /> Acknowledgements 51<br /> <br /> References 52<br /> <br /> <b>3 Gold Nanoparticle-Based Electrochemical Biosensors for Medical Applications 63<br /> </b><i>Ülkü</i> <i>Anik<br /> <br /> </i>3.1 Introduction 63<br /> <br /> 3.2 Gold Nanoparticles 64<br /> <br /> 3.3 Conclusion 76<br /> <br /> References 76<br /> <br /> <b>4 Impedimetric DNA Biosensors Based on Nanomaterials 81<br /> </b><i>Manel del Valle and Alessandra Bonanni<br /> <br /> </i>4.1 Introduction 82<br /> <br /> 4.2 Electrochemical Impedance Spectroscopy for Genosensing 85<br /> <br /> 4.3 Nanostructured Carbon Used in Impedimetric Genosensors 91<br /> <br /> 4.4 Nanostructured Gold Used in Impedimetric Genosensors 97<br /> <br /> 4.5 Quantum Dots for Impedimetric Genosensing 100<br /> <br /> 4.6 Impedimetric Genosensors for Point-of-Care Diagnosis 101<br /> <br /> 4.7 Conclusions (Past, Present and Future Perspectives) 102<br /> <br /> Acknowledgements 104<br /> <br /> References 104<br /> <br /> <b>5 Graphene: Insights of its Application in Electrochemical Biosensors for Environmental Monitoring 111<br /> </b><i>G.A. Álvarez-Romero, G. Alarcon-Angeles and A. Merkoçi<br /> <br /> </i>5.1 Introduction 112<br /> <br /> 5.2 Environmental Applications of Graphene-based Biosensors 117<br /> <br /> 5.3 Conclusions and Perspectives 133<br /> <br /> References 134<br /> <br /> <b>6 Functional Nanomaterials for Multifarious Nanomedicine 141<br /> </b><i>Ravindra P. Singh, Jeong-Woo Choi, Ashutosh Tiwari and Avinash Chand Pandey<br /> <br /> </i>6.1 Introduction 142<br /> <br /> 6.2 Nanoparticle Coatings 145<br /> <br /> 6.3 Cyclic Peptides 147<br /> <br /> 6.4 Dendrimers 149<br /> <br /> 6.5 Fullerenes/Carbon Nanotubes/Graphene 156<br /> <br /> 6.6 Functional Drug Carriers 157 <p>6.7 MRI Scanning Nanoparticles 162<br /> <br /> 6.8 Nanoemulsions 165<br /> <br /> 6.9 Nanofibers 166<br /> <br /> 6.10 Nanoshells 169<br /> <br /> 6.11 Quantum Dots 171<br /> <br /> 6.12 Nanoimaging 179<br /> <br /> 6.13 Inorganic Nanoparticles 180<br /> <br /> 6.14 Conclusions 182<br /> <br /> Acknowledgement 183<br /> <br /> References 183<br /> <br /> <b>Part 2: Principals and Prospective 199<br /> <br /> </b><b>7 Computational Nanochemistry Study of the Molecular Structure, Spectra and Chemical Reactivity Properties of the BFPF Green Fluorescent Protein Chromophore 201<br /> </b><i>Daniel Glossman-Mitnik<br /> <br /> </i>7.1 Introduction 201<br /> <br /> 7.2 Theory and Computational Details 202<br /> <br /> 7.3 Results and Discussion 206<br /> <br /> 7.4 Conclusions 233<br /> <br /> Acknowledgements 234<br /> <br /> References 234<br /> <br /> <b>8 Biosynthesis of etal Nanoparticles and Their Applications 239<br /> </b><i>Meryam Sardar, Abhijeet Mishra and Razi Ahmad<br /> <br /> </i>8.1 Introduction 240<br /> <br /> 8.2 Synthesis of Metal Nanoparticles 241<br /> <br /> 8.3 Applications 253<br /> <br /> 8.4 Conclusions 255<br /> <br /> Acknowledgement 256<br /> <br /> References 257<br /> <br /> <b>9 Ionic Discotic Liquid Crystals: Recent Advances and Applications 267<br /> </b><i>Santanu Kumar Pal and Sandeep Kumar<br /> <br /> </i>9.1 Introduction 268<br /> <br /> 9.2 Part I: Chromonic LCs 271<br /> <br /> 9.3 Part II: Thermotropic Ionic Discotic Liquid Crystals 282<br /> <br /> Acknowledgement 309<br /> <br /> References 309<br /> <br /> <b>10 Role of Advanced Materials as Nanosensors in Water Treatment 315<br /> </b><i>Sheenam Thatai, Parul Khurana and Dinesh Kumar<br /> <br /> </i>10.1 Introduction 315<br /> <br /> 10.2 Nanoparticles 318<br /> <br /> 10.3 Different Fabrication Methods of Nanoparticles 319<br /> <br /> 10.4 Core Material/Nanofillers 321<br /> <br /> 10.5 Shell Material/Nanomatrix 324<br /> <br /> 10.6 Core-Shell Material 326<br /> <br /> 10.7 Properties of Metal Nanoparticles and Core-Shell Nanocomposites 330<br /> <br /> 10.8 Detection of Heavy Metals Using Smart Core-Shell Nanocomposites 333<br /> <br /> 10.9 Conclusions 337<br /> <br /> Acknowledgement 337<br /> <br /> References 338<br /> <br /> <b>Part 3: Advanced Structures and Properties 345<br /> <br /> </b><b>11 Application of Bioconjugated Nanoporous Gold Films in Electrochemical Biosensors 347<br /> </b><i>Leila Kashefi-Kheyrabadi, Abolhassan Noori and Masoud Ayatollahi Mehrgardi<br /> <br /> </i>11.1 Introduction 348<br /> <br /> 11.2 Fabrication of Nanoporous Gold 349<br /> <br /> 11.3 Nucleic Acids (NAs)-Based Biosensors 351<br /> <br /> 11.4 Protein-Nanostructured Gold Bioconjugates in Biosensing 356<br /> <br /> 11.5 Conclusion 369<br /> <br /> References 369<br /> <br /> <b>12 Combination of Molecular Imprinting and Nanotechnology: Beginning of a New Horizon 375<br /> </b><i>Rashmi Madhuri, Ekta Roy, Kritika Gupta and Prashant K. Sharma<br /> <br /> </i>12.1 Introduction 376<br /> <br /> 12.2 Classification of Imprinted Nanomaterials 383<br /> <br /> 12.3 Imprinted Materials at Nanoscale 421<br /> <br /> 12.4 Conclusions and Future Outlook 427<br /> <br /> Acknowledgements 428<br /> <br /> References 428<br /> <br /> <b>13 Structural, Electrical and Magnetic Properties of Pure and Substituted BiFeO3 Multiferroics 433<br /> </b><i>S. Jangid, S. K. Barbar and M. Roy<br /> <br /> </i>13.1 Introduction 434<br /> <br /> 13.2 Synthesis of Materials 446<br /> <br /> 13.3 Structural and Morphological Analyses 454<br /> <br /> 13.4 Electrical Properties 467<br /> <br /> 13.5 Magnetic Properties 476<br /> <br /> 13.6 Thermal Analysis (MDSC Studies) 489<br /> <br /> 13.7 Summary and Conclusion 496<br /> <br /> References 498<br /> <br /> <b>14 Synthesis, Characterization and Rietveld Studies of Sr-modified PZT Ceramics 507<br /> </b><i>Kumar Brajesh, A.K. Himanshu and N.K. Singh<br /> <br /> </i>14.1 Introduction 508<br /> <br /> 14.2 Experiment 509<br /> <br /> 14.3 Rietveld Refinement Details 510<br /> <br /> 14.4 Results and Discussion 511<br /> <br /> 14.5 Conclusions 521<br /> <br /> References 521<br /> <br /> Index 523</p>

<p><b>Ashutosh Tiwari</b> is an Associate Professor at the Biosensors and Bioelectronics Centre, Linköping University, Sweden; Editor-in-Chief, <i>Advanced Materials Letters</i>; Secretary General, International Association of Advanced Materials; a materials chemist and also a docent in applied physics at Linköping University, Sweden. He has published more than 350 articles, patents, and conference proceedings in the field of materials science and technology and has edited/authored more than fifteen books on the advanced state-of-the-art of materials science. He is a founding member of the Advanced Materials World Congress and the Indian Materials Congress.</p> <p><b>Anthony P.F. Turner</b> is currently Head of Division FM-Linköping University’s new Centre for Biosensors and Bioelectronics. His previous thirty-five year academic career in the UK culminated in the positions of Principal (Rector) of Cranfield University and Distinguished Professor of Biotechnology. Professor Turner has more than 600 publications and patents in the field of biosensors and biomimetic sensors and is best known for his role in the development of glucose sensors for home-use by people with diabetes. He published the first textbook on biosensors in 1987 and is Editor-In-Chief of the principal journal in his field, <i>Biosensors & Bioelectronics</i>, which he co-founded in 1985.</p>

<p><b>This book provides detailed reviews of a range of nanostructures used in the construction of biosensors as well as the applications of these biosensor nanotechnologies in the biological, chemical, and environmental monitoring fields</b></p> <p>Biological sensing is a fundamental tool for understanding living systems, but also finds practical application in medicine, drug discovery, process control, food safety, environmental monitoring, defense, and personal security. Moreover, a deeper understanding of the bio/electronic interface leads us towards new horizons in areas such as bionics, power generation, and computing. Advances in telecommunications, expert systems, and distributed diagnostics prompt us to question the current ways we deliver healthcare, while robust industrial sensors enable new paradigms in R&D and production.</p> <p>Despite these advances, there is a glaring absence of suitably robust and convenient sensors for body chemistries. This book examines some of the emerging technologies that are fueling scientific discovery and underpinning new products to enhance the length and quality of our lives.</p> <p>The 14 chapters written by leading experts cover such topics as:</p> <ul> <li>ZnO and graphene microelectrode applications in biosensing</li> <li>Assembly of polymers/metal nanoparticles</li> <li>Gold nanoparticle-based electrochemical biosensors</li> <li>Impedimetric DNA sensing employing nanomaterials</li> <li>Graphene and carbon nanotube-based biosensors</li> <li>Computational nanochemistry study of the BFPF green fluorescent protein chromophore</li> <li>Biosynthesis of metal nanoparticles</li> <li>Bioconjugated-nanoporous gold films in electrochemical biosensors</li> <li>The combination of molecular imprinting and nanotechnology</li> <li>Principles and properties of multiferroics and ceramics</li> </ul> <p><b>Readership</b><br /> The book is written for a large and broad readership including researchers and university graduate students from diverse backgrounds such as chemistry, materials science, physics, pharmacy, medical science, biomedical engineering, and nanotechnology.</p>

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