List of Contributors xiPreface xiiiAbout the Editors xvii1 Introduction 1Hamida Hallil and Hadi Heidari1.1 Overview 11.2 Sensors: History and Terminology 21.2.1 Definitions and General Characteristics 31.2.2 Influence Quantities 51.3 Smart Sensors for Environmental and Medical Applications 61.4 Outline 8Reference 92 Field Effect Transistor Technologies for Biological and Chemical Sensors 11Anne-Claire Salaün, France Le Bihan, and Laurent Pichon2.1 Introduction 112.2 FET Gas Sensors 122.2.1 Materials 122.2.1.1 Inorganic Semiconductors 122.2.1.2 Semiconductor Polymers 122.2.1.3 Nanostructured Materials 132.2.2 FET as Gas Sensors 132.2.2.1 Pioneering FET Gas Sensors 132.2.2.2 OFET Gas Sensors 132.2.2.3 Nanowires-Based FET Gas Sensors 142.3 Ion-Sensitive Field Effect Transistors Based Devices 182.3.1 Classical ISFET 182.3.2 Other Technologies 192.3.2.1 EGFET: Extended Gate FET 202.3.2.2 SGFET: Suspended Gate FFETs 202.3.2.3 DGFET: Dual-Gate FETs 202.3.2.4 Water Gating FET or Electrolyte Gated FET 212.3.2.5 Other FETs 232.3.3 BioFETs 232.3.3.1 General Considerations 232.3.3.2 DNA BioFET 232.3.3.3 Protein BioFET 252.3.3.4 Cells 252.4 Nano-Field Effect Transistors 252.4.1 Fabrication of Nano-Devices 252.4.1.1 Silicon Nano-Devices 252.4.1.2 Carbon Nanotubes Nano-Devices 282.4.2 Detection of Biochemical Particles by Nanostructures-Based FET 282.4.2.1 SiNW pH Sensor 292.4.2.2 DNA Detection Using SiNW-Based Sensor 302.4.2.3 Protein Detection 322.4.2.4 Detection of Bacteria and Viruses 33References 343 Mammalian Cell-Based Electrochemical Sensor for Label-Free Monitoring of Analytes 43Md. Abdul Kafi, Mst. Khudishta Aktar, and Hadi Heidari3.1 Introduction 433.2 State-of-the-Art Cell Chip Design and Fabrication 453.3 Substrate Functionalization Strategies at the Cell-Electrode Interface 483.4 Electrochemical Characterization of Cellular Redox 493.5 Application of Cell-Based Sensor 513.6 Prospects and Challenges of Cell-Based Sensor 543.7 Conclusion 56References 564 Electronic Tongues 61Flavio M. Shimizu, Maria Luisa Braunger, Antonio Riul, Jr., and Osvaldo N. Oliveira, Jr.4.1 Introduction 614.2 General Applications of E-tongues 634.3 Bioelectronic Tongues (bETs) 654.4 New Design of Electrodes or Measurement Systems 664.5 Challenges and Outlook 73Acknowledgments 73References 745 Monitoring of Food Spoilage Using Polydiacetylene- and Liposome-Based Sensors 81Max Weston, Federico Mazur, and Rona Chandrawati5.1 Introduction 815.2 Polydiacetylene for Visual Detection of Food Spoilage 825.2.1 Contaminant Detection 835.2.2 Freshness Indicators 855.2.3 Challenges, Trends, and Industrial Applicability in the Food Industry 875.3 Liposomes 885.3.1 Pathogen Detection 885.3.1.1 Escherichia coli 885.3.1.2 Salmonella spp. 905.3.1.3 Other Bacterium 905.3.1.4 Viruses, Pesticides, and Toxins 915.3.2 Stability of Liposome-Based Sensors 935.3.3 Industrial Applicability of Liposomes 935.4 Conclusions 94References 946 Chemical Sensors Based on Metal Oxides 103K. S. Shalini Devi, Aadhav Anantharamakrishnan, Uma Maheswari Krishnan, and Jatinder Yakhmi6.1 Introduction 1036.2 Classes of MOx-Based Chemical Sensors 1046.3 Synthesis of MOx Structures 1046.4 Mechanism of Sensing by MOx 1056.5 Factors Influencing Sensing Performance 1066.6 Applications of MOx-Based Chemical Sensors 1096.6.1 MOx Sensors for Environmental Monitoring 1096.6.2 MOx Sensors in Clinical Diagnosis 1126.6.3 MOx Sensors in Pharmaceutical Analysis 1136.6.4 MOx-Based Sensors in Food Analysis 1166.6.5 MOx Sensors in Agriculture 1176.6.6 MOx Sensors for Hazard Analysis 1176.6.7 Flexible Sensors Based on MOx 1186.6.8 MOx-Based Lab-on-a-Chip Sensors 1186.7 Concluding Remarks 119Acknowledgment 119References 1207 Metal Oxide Gas Sensor Electronic Interfaces 129Zeinab Hijazi, Daniele D. Caviglia, and Maurizio Valle7.1 General Introduction 1297.1.1 Gas Sensing System 1297.1.2 Gas Sensing Technologies 1307.2 MOX Gas Sensors 1317.2.1 Principle of Operation 1317.2.2 Assessment of Available MOX-Based Gas Sensors 1327.3 System Requirements and Literature Review 1347.3.1 System Requirements 1347.3.2 Wide Range Resistance Interface Review 1367.4 Resistance to Time/Frequency Conversion Architecture 1377.4.1 Electronic Circuit Description 1377.4.2 Specifications for Each Building Block to Preserve High Linearity 1387.4.2.1 Resistance to Current Conversion (R-to-I) 1387.4.2.2 Switches 1417.4.2.3 Current to Voltage Conversion (I-to-V) 1417.4.2.4 Voltage to Time/Period (V-to-T) Conversion 1417.5 Power Consumption 1417.5.1 Power Consumption of MOX Gas Sensor 1417.5.2 Low Power Operating Mode 1427.5.3 Power Consumption at Circuit Level 1427.6 Conclusion 143References 1438 Smart and Intelligent E-nose for Sensitive and Selective Chemical Sensing Applications 149Saakshi Dhanekar8.1 Introduction 1498.1.1 The Human Olfactory System 1508.1.2 The Artificial Olfactory System 1508.1.2.1 Sensor Array 1518.1.2.2 Multivariate Data Analysis 1528.1.2.3 Pattern Recognition Methods 1538.2 What is an Electronic Nose? 1548.3 Applications of E-nose 1558.3.1 Key Applications of E-nose 1558.3.2 E-nose for Chemical Sensing 1558.4 Types of E-nose 1578.5 Examples of E-nose 1588.6 Improvements and Challenges 1658.7 Conclusion 165References 1669 Odor Sensing System 173Takamichi Nakamoto and Muis Muthadi9.1 Introduction 1739.2 Odor Biosensor 1749.3 Prediction of Odor Impression Using Deep Learning 1769.4 Establishment of Odor-Source Localization Strategy Using Computational Fluid Dynamics 1819.4.1 Background of Odor-Source Localization 1819.4.2 Sensor Model with Response Delay 1829.4.3 Simulation of Testing Environment Using CFD 1839.4.4 Simulation of Biologically Inspired Odor-Source Localization 1859.4.4.1 Odor Plume Tracking Strategy 1859.4.4.2 Result 1869.4.5 Summary of Odor Source Localization Strategy 1879.5 Conclusion 188Acknowledgments 189References 18910 Microwave Chemical Sensors 193Hamida Hallil and Corinne Dejous10.1 Interests of Electromagnetic Transducer Gas Sensors at Microwave Frequencies 19310.2 Operating Principle 19310.2.1 Electromagnetic Transducers 19310.2.2 The Case of Microwave Transducers 19510.3 Theory of Microwave Transducers: Design, Methodology, and Approach 19610.4 Microwave Structure-Based Chemical Sensor 20010.4.1 Manufacturing Techniques 20010.4.2 Chemical Microwave Sensors 20010.4.3 Wireless Interrogation Schemes 20410.5 Multivariate Data Analysis and Machine Learning for Targeted Species Identification 20710.6 Conclusion and Prospects 209Acknowledgments 210References 210Index 217

Hamida Hallil, PhD, is an Associate Professor at the IMS Laboratory (UMR CNRS 5218), University of Bordeaux. She has been involved in several national and international research projects, including the Merlion PHC and CAMUS projects and the Bordeaux University project. Professor Hallil also served on the organizing or technical committees of several conferences, including IEEE SENSORS '16 and '17, DTIP '17 and '18, and IEEE NMDC '17 and '18.Hadi Heidari, PhD, is a Lecturer in the School of Engineering at the University of Glasgow. He is a senior member of the IEEE and has served as member of the IEEE Circuits and Systems Society Board of Governors (BoG) and the IEEE Sensors Council Administrative Committee (AdCom). Professor Heidari has served on the organizing committee of several conferences, including IEEE SENSORS '16 and '17, NGCAS '17, BioCAS'18, and PRIME '15. He is also a co-author of Magnetic Sensors for Biomedical Applications (Wiley-IEEE Press).