Functionalized Nanomaterials for Biosensing and Bioelectronics Applications
Trends and Challenges
- 1st Edition - June 4, 2024
- Editors: Sudheesh K. Shukla, Chaudhery Mustansar Hussain, Jagriti Narang, Roberto Pilloton
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 2 3 8 2 9 - 5
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 2 3 8 4 3 - 1
Functionalized Nanomaterials for Biosensing and Bioelectronics Applications: Trends and Challenges describes current and future opportunities for integrating the unique proper… Read more
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Request a sales quote- Introduces the most common functionalized nanomaterials and their morphologies, properties, and mechanisms for sensing applications
- Reviews functionalization and fabrication methods and techniques for the integration of one- and two-dimensional materials for sensing applications
- Addresses the most relevant applications of functionalized nanomaterials for biosensing and bioelectronics applications
- Cover image
- Title page
- Table of Contents
- Copyright
- List of contributors
- Preface
- Part 1. Development of fabrication strategies of FNMS based biosensing and bioelectronics
- 1. Applications of biosensors in bio-analysis
- 1.1. Introduction
- 1.2. Principle of biosensors
- 1.3. Components of biosensors
- 1.4. Working of biosensors
- 1.5. Examples of biosensors
- 1.6. Types of biosensors
- 1.7. Applications of biosensors
- 1.8. Conclusions and prospects
- 2. Biosensing mechanisms and applications
- 2.1. Introduction
- 2.2. Signal monitoring
- 2.3. Immobilization techniques
- 2.4. Immobilization of biological receptors
- 2.5. Enzymatic reactions in biosensors
- 2.6. Transduction mechanisms
- 2.7. Influence of charge screening on biomolecule detection
- 2.8. Sensing techniques
- 2.9. Recent progress in microbial biosensors
- 2.10. Conclusions and outlook
- 3. Advantages of functionalized nanomaterials for biosensor technology
- 3.1. Introduction
- 3.2. Carbon nanotubes
- 3.3. Carbon nanotube classification by chirality
- 3.4. Biological applications
- 3.5. Limitations of carbon nanotubes
- 3.6. Quantum dots
- 3.7. Graphene oxide nanoparticles
- 3.8. Metal oxide nanoparticles
- 3.9. Metal nanoparticles
- 3.10. Magnetic nanoparticles
- 3.11. Conclusions
- 4. Nanomaterial functionalization approaches for biosensing and bioelectronic applications
- 4.1. Introduction
- 4.2. Carbon-and metal-based nanomaterials
- 4.3. Electrochemical biosensors
- 4.4. Optical biosensors
- 4.5. Conclusions and future perspectives
- 5. Molecularly imprinted polymer-based sensors: A way-forward concept for artificial antibodies
- 5.1. Introduction
- 5.2. Application of nanosized molecularly imprinted polymers
- 5.3. Nanosized molecularly imprinted polymers as efficient receptors for sensor fabrication
- 5.4. Conclusions and future perspectives
- 6. Biosensor development using functionalized 2D nanomaterials
- 6.1. Introduction
- 6.2. Biosensors based on analogs of two-dimensional nanomaterials in various fields
- 6.3. Challenges and outlook
- 6.4. Conclusions
- 7. Recent advancements in fabrication strategies for functionalized nanomaterial-based biosensors
- 7.1. Introduction
- 7.2. Inkjet printing
- 7.3. Electrospinning
- 7.4. Electrodeposition
- 7.5. Screen printing
- 7.6. Drop-casting
- 7.7. Directed self-assembly
- 7.8. Stamping
- 7.9. Chemical vapor deposition
- 7.10. Air suspension coating
- 7.11. Conclusions
- 8. Exploring the COVID-19 journey and cutting-edge biosensing approaches
- 8.1. Introduction
- 8.2. Unavoidable impacts and risks of infection
- 8.3. Infectivity emergence
- 8.4. Evolution of a new SARS-CoV-2 variant: Omicron!
- 8.5. Potential biosensing technologies
- 8.6. Vaccine effectiveness
- 8.7. Interim clinical guidance for management
- 8.8. Universal recommendations
- 8.9. Journey, impact, and biosensing approaches: Perspective overview
- 8.10. Conclusions and prospects
- Part 2. Application and future directions of different FNM-based biosensing and bioelectronics
- 9. Teaming up biosensor technology with agriculture: a detection approach for reframing agricultural sustainability and food security
- 9.1. Introduction
- 9.2. Tackling plant diseases and infections in the agricultural sector
- 9.3. Ensuring agrifood safety and security through biosensing technologies
- 9.4. Conclusions: current scenario, future perspectives, and challenges
- 10. Developments and challenges in coronavirus diagnoses: A biosensor point of view
- 10.1. Introduction
- 10.2. A sketch of conventional diagnostic methods
- 10.3. Nonconventional era: The era of antivirals/immune-boosters and vaccines
- 10.4. Discussion and future perspective
- 10.5. Conclusions
- 11. Magnetic graphene nanocomposites for electrochemical detection of heavy metal ions in coal mine areas
- 11.1. Introduction
- 11.2. Graphene/graphene oxide
- 11.3. Electrochemical detection technique
- 11.4. Conclusions
- 12. Cancer diagnosis via functionalized nanomaterial-based biosensors
- 12.1. Introduction
- 12.2. Cancer diagnosis methods
- 12.3. Biomarkers
- 12.4. Biosensors
- 12.5. Electrochemical biosensors for cancer detection
- 12.6. Optical biosensors for cancer diagnosis
- 12.7. Mass spectrometry-based biosensors for cancer diagnosis
- 12.8. Immunoassay-based biosensors for cancer diagnosis
- 12.9. Conclusions
- 13. Biosensors and bioelectronics for advanced healthcare systems
- 13.1. Introduction
- 13.2. Historical background of biosensor development
- 13.3. Static and dynamic characteristics of biosensors
- 13.4. Classification of biosensors
- 13.5. Challenges and future approaches in biosensor development
- 14. Biosensors: A promising approach for healthcare application
- 14.1. Introduction
- 14.2. Three-dimensional network: Specific surface attachment of biological elements
- 14.3. Types of biosensors, their incorporation, and applications
- 14.4. Biosensor approach for detecting biological applications
- 14.5. Anticipated property of biosensor
- 14.6. Conclusion
- 15. Challenges and prospects of functionalized nanomaterial-based biosensors
- 15.1. Introduction
- 15.2. Biosensor development
- 15.3. Challenges in biosensor development
- 15.4. Prospects
- 15.5. Conclusions
- Index
- No. of pages: 625
- Language: English
- Edition: 1
- Published: June 4, 2024
- Imprint: Woodhead Publishing
- Paperback ISBN: 9780128238295
- eBook ISBN: 9780128238431
SS
Sudheesh K. Shukla
Sudheesh K. Shukla is a researcher with the Department of Chemical Sciences, University of Johannesburg, Doornfontein Campus, Johannesburg, South Africa; and Associate Professor at the School of Chemical Engineering and Physical Sciences, Lovely Professional University, Phagwara, India. His research involves real-time analysis of biochemical markers for personalized healthcare and environmental monitoring.
CM
Chaudhery Mustansar Hussain
JN
Jagriti Narang
Jagriti Narang is an Assistant Professor at the Department of Biotechnology, Jamia Hamdard, New Delhi, and has work experience of more than 10 years. She has authored or coauthored many research papers in international peer-reviewed journals. She has edited four books and written several chapters. She is a committee member of many international conferences and is a member of Material Research Society of India and Society of Biological Chemistry. She is also an editor and peer reviewer of many international journals and has presented her papers on several international platforms. Dr. Narang has done extensive work on the fabrication of various biosensors for the diagnostic applications. She has proposed some laboratory models that can be converted into commercial monitoring device.
RP
Roberto Pilloton
Since 1986, Roberto Pilloton has been at the forefront of advancing bioanalytical methods through the innovative use of electrochemical biosensors, particularly in the domains of food, clinical, and environmental analysis. His distinguished career includes roles as a senior researcher at two of Italy's leading research institutes: the ENEA "Italian Institute of Sustainable Development" and the CNR "National Research Council." In addition to his impactful research contributions, Pilloton has imparted his knowledge as an adjunct professor, specializing in Environmental Bioanalytical Chemistry, across several esteemed Italian universities and research institutes. His dedication to education is further demonstrated by his role as a mentor, guiding students in the development of master's and PhD theses, as well as mentoring national and international fellows. Pilloton's global influence extends beyond academic circles, as he has served as a visiting scientist in prominent institutions in Paris, Stuttgart, Nice, Braunschweig, Lund, Izmir, Ceske Budejovice, and Karaikudi. Moreover, he has played a pivotal role in shaping the landscape of international conferences on biosensors, having chaired or been a member of the scientific committee. From 2015 to 2018, Pilloton served as the elected vice president of the "International Association on Environmental Analytical Chemistry" (IAEAC). Currently, he holds the esteemed position of Editor-in-Chief of the International Journal of Environmental Analytical Chemistry at Taylor and Francis, and he is a valuable member of the editorial boards of two MDPI journals: Sensors and Biosensors.