Surfactant-Based Sensors in Chemical and Biochemical Detection / edited by J. G. Manjunatha.

Format:

Book

Contributor:

Manjunatha, J. G., editor.

Series:

RSC detection science series ; Number 23.

Detection Science Series : ; Number 23

Language:

English

Subjects (All):

Electrochemical sensors.

Physical Description:

1 online resource (249 pages)

Edition:

First edition.

Place of Publication:

London, England : The Royal Society of Chemistry, [2024]

Summary:

Describing the importance of surfactants in electrochemical investigations related to biologically and environmentally vital chemicals, this book charts the progression of highly responsive electrochemical sensors using surfactants as a modifying agent in the sensor field.

Contents:

Cover

Contents

Chapter 1 Review of Surfactants, Structural Properties and Their Role in Electrochemistry

1.1 Introduction

1.2 Structures and Features of Surfactants

1.2.1 Classification of Surfactants

1.3 Applications of Surfactants in Electrochemistry

1.3.1 Electroplating

1.3.2 Corrosion

1.3.3 Batteries

1.3.4 Electrochemical Sensors

1.4 Conclusion and Future Prospects

Acknowledgements

References

Chapter 2 New Approach to the Preparation of Cationic, Anionic, Neutral, and Gemini Sensors

2.1 Introduction

2.2 New and Sustainable Approach to the Preparation of Electrochemical Sensors

2.3 Types of Surfactants

2.3.1 Classification Based on Hydrophilic Head Parts

2.3.2 Classification Based on the Source

2.4 Preparation of Surfactant- based Sensors

2.4.1 Cationic Surfactant- based Sensors

2.4.2 Anionic Surfactant-based Sensors

2.4.3 Non-ionic Surfactant-based Sensors

2.4.4 Zwitterionic and Gemini Surfactant-based Sensors

2.5 Conclusion

Chapter 3 Surfactant Sensors for Bio-based Sensing

3.1 Introduction

3.2 Interactions of Anionic Surfactant Systems

3.3 Application of Surfactants in Voltammetric Methods

3.4 Surfactant Sensors in Electrochemical Systems

3.4.1 Fluorescent Surfactant Sensors

3.4.2 Potentiometric Surfactant Sensors

3.4.3 Flow Injection Analysis Surfactant Sensors

3.4.4 Amperometric Surfactant Sensors

3.4.5 Conductometric Surfactant Sensors

3.4.6 Impedimetric Surfactant Sensors

3.5 A Bio- inspired Sensor

3.6 Conclusions and Outlook

Chapter 4 An Overview of Stability, Lifetime, and Reuse of Surfactant Sensors

4.1 Introduction

4.2 Classification of Surfactants

4.2.1 Anionic Surfactants

4.2.2 Cationic Surfactants

4.2.3 Non-ionic Surfactants

4.2.4 Amphoteric (Zwitterionic) Surfactants.

4.3 Characterization Methods for Surfactants

4.3.1 Measurement of Surface Tension

4.3.2 Measurement of the Critical Micelle Concentration (CMC)

4.3.3 Measurement of the Interfacial Tension Between Liquids

4.3.4 Measurement of Dynamic Surface Tension and Interfacial Tension

4.3.6 Foam Analysis

4.3.7 Surface Rheological Investigations

4.4 Stability of Surfactant Sensors

4.5 Lifetime of Surfactant Sensors

4.6 Reuse of Surfactant Sensors

4.7 Chemical Surfactants and Sensing

4.7.1 Electronic Chemical Sensors

4.7.2 Optical Chemical Sensors

4.7.3 Acoustic Wave Chemical Sensors

4.7.4 Electrochemical Sensors

4.8 Surfactant Sensors in Chemical Detection and Application

4.8.1 Anionic Surfactant Sensors

4.8.2 Cationic Surfactant Sensors

4.8.3 Non-ionic Surfactant Sensors

4.8.4 Amphoteric (Zwitterionic) Surfactant Sensors

4.9 Biochemical Surfactants and Sensing

4.9.1 Potentiometric Surfactant Sensors

4.9.2 Impedimetric Surfactant Sensors

4.9.3 Conductometric Surfactant Sensors

4.9.4 Amperometric Surfactant Sensors

4.10 Surfactant Sensors in Biochemical Detection and Applications

4.10.1 Anionic Surfactant Sensors

4.10.2 Cationic Surfactant Sensors

4.10.3 Non-ionic Surfactant Sensors

4.10.4 Amphoteric (Zwitterionic) Surfactant Sensors

4.11 Conclusion

Chapter 5 Surfactant-based Electrochemical Sensing and Bio- sensing: Safety and Toxicity

5.1 Introduction

5.2 Surfactant Structure-dependent Synthesis and Properties

5.2.1 Surfactant Modification for Nanoparticle Synthesis

5.2.2 Surfactant Structure-dependent Nanoparticle Properties

5.3 Ionic Surfactants with Magnetic Properties

5.3.1 Applications of Magneto Surfactants

5.3.2 Saccharide-based Biosensors

5.3.3 Cytochrome Biosensor

5.3.4 Lipoprotein-based Biosensors.

5.3.5 Iron- based Biosensors

5.3.6 Electrochemical Sensors for the Detection of Various Chemicals

5.4 Conclusion and Future Outlook

Chapter 6 Surfactant-based Potentiometric Sensors for Surfactant Determination

6.1 Introduction

6.2 Surfactant- based Potentiometric Sensors for Determination of Surfactants

6.2.1 Liquid-contact Ion-selective Electrodes

6.2.2 Solid-contact Ion-selective Electrodes

6.3 Conclusion

Chapter 7 Surfactant Sensors for Environmental Analysis

7.1 Introduction

7.2 Types of Surfactant

7.2.1 Anionic Surfactants

7.2.2 Cationic Surfactants

7.2.3 Amphoteric Surfactants

7.2.4 Non-ionic Surfactants

7.3 Surfactant Sensors

7.3.1 Sensors for Surfactant Determination

7.3.2 Surfactant Sensors for Environmental Analysis

7.4 Conclusion

Chapter 8 Surfactant Sensors for Food Quality Monitoring

8.1 Introduction

8.2.1 Classification of Surfactants

8.3 Sensors

8.3.1 Chemical Sensors

8.3.2 Physical Sensors

8.3.3 Biological Sensors

8.3.4 Next Generation Sensors

8.4 Role of Surfactants in Monitoring Food Quality

8.4.1 Advantages of Surfactant-modified Sensors

8.5 Application of Surfactants in Food Quality Monitoring

8.5.1 Surfactants Used in the Detection of Allergens in Food Products

8.5.2 Detection of Vanillin in Food, Beverages, and Pharmaceuticals

8.5.3 Detection of Adulterants by Surfactant-coated Nanoparticles

8.5.4 Surfactants Used in Packaging of Food Products

8.5.5 Surfactants Used in Voltammetric Sensors

8.5.6 Detection of Quinoline Yellow (QY)

8.5.7 Curcumin Detection in Natural FoodSupplements Through a Surfactant-modified Voltammetric Sensor

8.6 Conclusion

Chapter 9 Surfactant Sensors for Pharmaceutical/Medical Applications

9.1 Introduction.

9.2 Surfactants and Their Use in Sensor Applications

9.2.1 Electrochemical Sensors

9.2.2 Chromatographic Techniques

9.2.3 Capillary Electrophoresis

9.3 Surfactant- based Sensors in Pharmaceutical Analysis

9.4 Surfactant- based Sensors in Medical Analysis

9.5 Future Outlook

9.6 Conclusion

Chapter 10 Surfactant-based Ion-selective Electrodes

0.1 Introduction

10.1.1 Materials and Characterization

10.1.2 Construction and Preparation of the Electrodes

10.1.3 Preparation of the Ion Pairs and Membranes

10.1.4 Apparatus Involved

10.2 Experimental

10.2.1 Potentiometric Titrations and Electromotive Force (emf) Measurements

10.3 Results and Discussion

10.3.1 CNTs and Surfactant Dispersion Process

10.3.2 Surfactant and CNT Adsorption Process

10.3.3 SEM (Scanning Electron Microscope) andTEM (Transmission Electron Microscope) Studies

10.3.4 Potentiometric Measurements and Zeta Potentials

10.3.5 Influence of Membrane Potential

10.4 Conclusions

Author Contributions

Conflicts of Interest

Data Availability

Funding

Chapter 11 Advantages, Limitations, Future Expectations, and Commercialization Challenges of Surfactant Sensors

11.1 Introduction

11.2 Advantages and Challenges of Sensors

11.3 Applications of Surfactant Sensors

11.4 Limitations of Surfactant Sensors

11.5 Challenges of Surfactant Sensors

11.6 Conclusion

Subject Index.

Notes:

Includes bibliographical references.

Description based on publisher supplied metadata and other sources.

Description based on print version record.

ISBN:

1-83767-118-4

1-83767-119-2