Loutfy H. Madkour
Carbon-Based Nanomaterials for Sustainable and Technological Applications
Loutfy H. Madkour
Carbon-Based Nanomaterials for Sustainable and Technological Applications
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Carbon-Based Nanomaterials for Sustainable and Technological Applications covers the fundamentals of Carbon-based Nanomaterials (CNMs) and their potential for technological and industrial applications. Addressing recent advancements in technology and improvement in material synthesis.
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Carbon-Based Nanomaterials for Sustainable and Technological Applications covers the fundamentals of Carbon-based Nanomaterials (CNMs) and their potential for technological and industrial applications. Addressing recent advancements in technology and improvement in material synthesis.
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Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 444
- Erscheinungstermin: 29. Oktober 2024
- Englisch
- Abmessung: 280mm x 210mm
- ISBN-13: 9781032635934
- ISBN-10: 1032635932
- Artikelnr.: 70602204
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 444
- Erscheinungstermin: 29. Oktober 2024
- Englisch
- Abmessung: 280mm x 210mm
- ISBN-13: 9781032635934
- ISBN-10: 1032635932
- Artikelnr.: 70602204
Prof. Loutfy H. Madkour is a Professor of Physical chemistry, Nanoscience and Nanotechnology Chemistry Department, Faculty of Science, Tanta University, Egypt.
1. Comprehensive Study of Carbon Nanomaterials-Based Nanostructured
Materials: Potential for Technological and Industrial Applications
1.1. Background of Carbon-Based Nanostructured Materials
1.2. History of Carbon Nanotube Composites
1.3. Characterization of CNTs
1.4. Classification of the Categories Carbon Nanotubes Types and Their
Properties
1.5. Different Allotropes of Carbon Related to Devices
1.6. Basic Structure and Morphology Features of CNTs
1.7. Production and Workplace Exposure to CNTS
1.8. Synthesis of Carbon Nanotubes (CNTs)
1.9. Growth Mechanism of Carbon Nanotubes (CNTs)
1.10. Methods of Purification and Dispersion of Carbon Nanotubes
1.11. Limitations and Modification (Functionalization)
1.12. Drug Loading Mechanism and Cellular Uptake of CNTs
1.13. Uptake of CNTs by Cell
1.14. Breakdown Mechanism of CNTs in the Body
1.15. Toxicity of CNTs
1.16. Different Impressive Properties of Carbon Nanotubes
1.17. Advantage and Disadvantage of Carbon Nanotubes (CNTs)
1.18. Administration of Carbon Nanotubes
1.19. Examples of Medical andTherapeutics Applications for Carbon Nanotubes
1.20. Applications of Graphene
1.21. Conclusions
2. Progression in Synthesis Processing and Growth Mechanism of Carbon
Nanomaterials for Advanced Macro-Scale Applications
2.1. Production and Main Processing Synthesis Methods of Carbon Nanotubes
2.2. Electric Arc Discharge Method
2.3. Laser Ablation Method
2.4. Purification of CNTs
2.5. Chemical Vapor-Phase Growth Production Deposition Method (CVD)
2.6. Vapor-Phase Growth Production Method
2.7. Other Emerging Methods
2.8. Experimental Reproducibility
2.9. In Situ Growth Deposition of CNTs and 2D Material Synthesis on Fibers
2.10. Substrate-Bound SWCNT Synthesis
2.11. Vertically Aligned SWCNTs
2.12. Recent Advances in Synthesis of Boron Nitride Nanotubes (BNNTs)
Growth
2.13. Influence of Precursor Gas Chemistry
2.14. Recent Trends in the Synthesis of CNTs
2.15. Methods of Carbon Nanotube-Based Fibers Production
2.16. Nanostructured Energy Materials in Fibers
2.17. Processing and Applications of Novel Functionalized Carbon Nanotubes
(CNTs)
2.18. Synthesis of Fullerenes
2.19. Methods of Graphene Preparation
2.20. Synthesis and Tuning Strategies of GQDs
2.21. Regulation Properties of GQDs
3. Bionanotechnological Applications of Fullerene (C60)-Based Modified
Development Imaging and Biosensing Devices
3.1. Introduction
3.2. Fullerenes, Their Properties and Production
3.3. Synthesis Methods of C60 Fullerene
3.4. Functionalization of Fullerene
3.5. Toxicity and Biocompatibility Evaluation of Fullerenes
3.6. Types of Fullerenes and Their Specific Uses (C60, C70, Fullerenols)
3.7. Uses of Fullerene
3.8. Fullerene in Biomedical Applications and Its Role in Drug Delivery
3.9. Other Biomedical Applications
3.10. Applications of Fullerenes in Biosensors
3.11. Modification of Electrodes with Fullerenes
3.12. Fullerene-Based Modified Sensors and Biosensors
3.13. Fullerene-Based Polymers
3.14. Conclusions and Future Prospective
4. Computational Simulation Optimization and Pharmaceutical Role of
CNTs-Based Development of New Target Drug Delivery Systems (DDSs) for
Enhance Efficacy in Anticancer Therapy
4.1. CNTs on Molecular Dynamics Simulation-Based Development of New Drug
Delivery Systems
4.2. Structural Properties and Functionalization of CNTs
4.3. Interactions of Carbon Nanotubes with the Cell Membrane
4.4. Molecular Dynamics Simulation of CNT-Cell Membrane Interactions
4.5. Computational Aspects of Solvent and Co-Solvent Effects on the
Interaction of Flutamide as Anticancer Drug Delivery System with CNT
4.6. DFT Interaction of Flutamide Drug with COOH- and COCl-Functionalized
CNTs
4.7. Molecular Dynamics Simulation Study of the Functionalized CNTs to
Enhance the Efficacy of the Anticancer Drug Paclitaxel
4.8. Computational Simulation Study of CNT as a Carrier in Drug Delivery
System for Carnosine Dipeptide
4.9. Computational Study of Leflunomide on the SWCNT and SWBNNT
4.10. Concluding Remarks
5. Cutting-Edge Nanobiotechnology in Advanced Drug Delivery Nanosystems for
CNTs, Fullerenes, NDs, and Graphene-Based Materials
5.1. Introduction
5.2. Carbon Nanotubes-Based Drug Delivery
5.3. Graphene/Graphene Oxide/Reduced Graphene Oxide
5.4. Graphene Quantum Dots (GQDs)
5.5. Fullerenes Composition
5.6. Nanodiamonds (NDs)-Based Drug Delivery
5.7. Carbon Nano-Onions (CNOs)-Based Drug Delivery
5.8. Carbon Nanotubes (CNTs)-Based Advanced Dermal Therapeutics
5.9. Toxicity Concerns for Carbon-Based Nanomaterials
5.10. Computational Investigations of Fixed-Free and Fixed-Fixed Types of
SWCNT Mass Sensing Biosensor
5.11. Conclusions
5.12. Future Perspectives
6. Bright Future of Carbon Nanomaterials for Cancer Nanomedicine-Based
Enzyme Immobilization Conjugates
6.1. Introduction
6.2. Nanozymes to CNM-Enzyme Conjugates
6.3. CNMs for Enzyme Mimicry, Inhibition, or Monitoring
6.4. Applications of CNM-Enzyme Conjugates
6.5. Enzymatic Biodegradation of CNMs
6.6. CNT based high-¿ dielectric Ion Sensitive Field Effect Transistor
Based Cholesterol Biosensor
6.7. Bright future of Carbon dots for cancer nanomedicine
6.8. Bright Future in the Fabrication of Portable Kits in Analytical
Systems
6.9. Conclusions and Future Perspectives
7. CNMs-Based Developed Biosensors for Rapid Technologies Detection
Antiviral Infection and Management Coronavirus Biomarkers
7.1. Background
7.2. Viral infection and nanomaterials
7.3. Graphene oxide-based fluorescent nanosensor to identify antiviral
agents via a drug repurposing screen
7.4. Carbon nanomaterial, and its derivatives as nanobiosensors versus
COVID-19
7.5. Smart nanomaterials for biosensing technologies and their consequences
7.6. Strategies to Enhance the Biosensor Performance
7.7. Emerging nanomaterials-based biosensor for SARS-CoV-2 detection
7.8. Carbon nanotubes in protection and biosensing applications
7.9. Carbon -based nanomaterials for the management of virus
7.10. Rapid and label-free detection of H5N1 virus using carbon nanotube
network field effect transistor
7.11. How the Coronavirus Infects Our Cells?
7.12. Life Cycle of the Pandemic Coronavirus
7.13. Latest Developed Biosensors for COVID-19
7.14. (CNT-FET)-based biosensor for rapid detection of SARS-CoV-2
(COVID-19)
7.15. Functional Carbon Quantum Dots as Medical Countermeasures to Human
Coronavirus
7.16. 3D-printed graphene polylactic acid devices resistant to SARS-CoV-2
7.17. Conclusion and Perspective
8. Insights on Carbon-Based Nanomaterials as Smart Nanosystems Platform for
Cancer Theranostics Sustainable Technology
8.1. Background
8.2. Functionalization Methods of carbon nanotubes
8.3. Tumor microenvironment (TME) and opportunities
8.4. Carbon nanotubes for tumor microenvironment targeting
8.5. Stimuli responsive intelligent nanomaterial in cancer theranostics
8.6. Progress of Smart Nanoparticles Based Theranostics
8.7. Physical and chemical properties responsive nanomaterials
8.8. Synthesis of Nanomaterials
8.9. Classification of Nanomaterials
8.10. Recent Trends of Nanomaterials in Cancer Theranostics
8.11. Carbon nanotubes in cancer treatment
8.12. Carbon nanotubes in cancer diagnosis
8.13. CNTs in cancer imaging
8.14. CNTs in nanobiosensors
8.15. Multi-responsive intelligent nanomaterials
8.16. Toxicological effects of nanomaterials
8.17. Current Technological Challenges and Limitations of Effective
Theranostics
8.18. Global Opportunities of Smart Nanomaterials in Next Generation Cancer
Theranostics
8.19. Advantages, challenges, and outlooks of nanomaterials
8.20. Conclusions and future prospect
List of abbreviations
References
Index
Materials: Potential for Technological and Industrial Applications
1.1. Background of Carbon-Based Nanostructured Materials
1.2. History of Carbon Nanotube Composites
1.3. Characterization of CNTs
1.4. Classification of the Categories Carbon Nanotubes Types and Their
Properties
1.5. Different Allotropes of Carbon Related to Devices
1.6. Basic Structure and Morphology Features of CNTs
1.7. Production and Workplace Exposure to CNTS
1.8. Synthesis of Carbon Nanotubes (CNTs)
1.9. Growth Mechanism of Carbon Nanotubes (CNTs)
1.10. Methods of Purification and Dispersion of Carbon Nanotubes
1.11. Limitations and Modification (Functionalization)
1.12. Drug Loading Mechanism and Cellular Uptake of CNTs
1.13. Uptake of CNTs by Cell
1.14. Breakdown Mechanism of CNTs in the Body
1.15. Toxicity of CNTs
1.16. Different Impressive Properties of Carbon Nanotubes
1.17. Advantage and Disadvantage of Carbon Nanotubes (CNTs)
1.18. Administration of Carbon Nanotubes
1.19. Examples of Medical andTherapeutics Applications for Carbon Nanotubes
1.20. Applications of Graphene
1.21. Conclusions
2. Progression in Synthesis Processing and Growth Mechanism of Carbon
Nanomaterials for Advanced Macro-Scale Applications
2.1. Production and Main Processing Synthesis Methods of Carbon Nanotubes
2.2. Electric Arc Discharge Method
2.3. Laser Ablation Method
2.4. Purification of CNTs
2.5. Chemical Vapor-Phase Growth Production Deposition Method (CVD)
2.6. Vapor-Phase Growth Production Method
2.7. Other Emerging Methods
2.8. Experimental Reproducibility
2.9. In Situ Growth Deposition of CNTs and 2D Material Synthesis on Fibers
2.10. Substrate-Bound SWCNT Synthesis
2.11. Vertically Aligned SWCNTs
2.12. Recent Advances in Synthesis of Boron Nitride Nanotubes (BNNTs)
Growth
2.13. Influence of Precursor Gas Chemistry
2.14. Recent Trends in the Synthesis of CNTs
2.15. Methods of Carbon Nanotube-Based Fibers Production
2.16. Nanostructured Energy Materials in Fibers
2.17. Processing and Applications of Novel Functionalized Carbon Nanotubes
(CNTs)
2.18. Synthesis of Fullerenes
2.19. Methods of Graphene Preparation
2.20. Synthesis and Tuning Strategies of GQDs
2.21. Regulation Properties of GQDs
3. Bionanotechnological Applications of Fullerene (C60)-Based Modified
Development Imaging and Biosensing Devices
3.1. Introduction
3.2. Fullerenes, Their Properties and Production
3.3. Synthesis Methods of C60 Fullerene
3.4. Functionalization of Fullerene
3.5. Toxicity and Biocompatibility Evaluation of Fullerenes
3.6. Types of Fullerenes and Their Specific Uses (C60, C70, Fullerenols)
3.7. Uses of Fullerene
3.8. Fullerene in Biomedical Applications and Its Role in Drug Delivery
3.9. Other Biomedical Applications
3.10. Applications of Fullerenes in Biosensors
3.11. Modification of Electrodes with Fullerenes
3.12. Fullerene-Based Modified Sensors and Biosensors
3.13. Fullerene-Based Polymers
3.14. Conclusions and Future Prospective
4. Computational Simulation Optimization and Pharmaceutical Role of
CNTs-Based Development of New Target Drug Delivery Systems (DDSs) for
Enhance Efficacy in Anticancer Therapy
4.1. CNTs on Molecular Dynamics Simulation-Based Development of New Drug
Delivery Systems
4.2. Structural Properties and Functionalization of CNTs
4.3. Interactions of Carbon Nanotubes with the Cell Membrane
4.4. Molecular Dynamics Simulation of CNT-Cell Membrane Interactions
4.5. Computational Aspects of Solvent and Co-Solvent Effects on the
Interaction of Flutamide as Anticancer Drug Delivery System with CNT
4.6. DFT Interaction of Flutamide Drug with COOH- and COCl-Functionalized
CNTs
4.7. Molecular Dynamics Simulation Study of the Functionalized CNTs to
Enhance the Efficacy of the Anticancer Drug Paclitaxel
4.8. Computational Simulation Study of CNT as a Carrier in Drug Delivery
System for Carnosine Dipeptide
4.9. Computational Study of Leflunomide on the SWCNT and SWBNNT
4.10. Concluding Remarks
5. Cutting-Edge Nanobiotechnology in Advanced Drug Delivery Nanosystems for
CNTs, Fullerenes, NDs, and Graphene-Based Materials
5.1. Introduction
5.2. Carbon Nanotubes-Based Drug Delivery
5.3. Graphene/Graphene Oxide/Reduced Graphene Oxide
5.4. Graphene Quantum Dots (GQDs)
5.5. Fullerenes Composition
5.6. Nanodiamonds (NDs)-Based Drug Delivery
5.7. Carbon Nano-Onions (CNOs)-Based Drug Delivery
5.8. Carbon Nanotubes (CNTs)-Based Advanced Dermal Therapeutics
5.9. Toxicity Concerns for Carbon-Based Nanomaterials
5.10. Computational Investigations of Fixed-Free and Fixed-Fixed Types of
SWCNT Mass Sensing Biosensor
5.11. Conclusions
5.12. Future Perspectives
6. Bright Future of Carbon Nanomaterials for Cancer Nanomedicine-Based
Enzyme Immobilization Conjugates
6.1. Introduction
6.2. Nanozymes to CNM-Enzyme Conjugates
6.3. CNMs for Enzyme Mimicry, Inhibition, or Monitoring
6.4. Applications of CNM-Enzyme Conjugates
6.5. Enzymatic Biodegradation of CNMs
6.6. CNT based high-¿ dielectric Ion Sensitive Field Effect Transistor
Based Cholesterol Biosensor
6.7. Bright future of Carbon dots for cancer nanomedicine
6.8. Bright Future in the Fabrication of Portable Kits in Analytical
Systems
6.9. Conclusions and Future Perspectives
7. CNMs-Based Developed Biosensors for Rapid Technologies Detection
Antiviral Infection and Management Coronavirus Biomarkers
7.1. Background
7.2. Viral infection and nanomaterials
7.3. Graphene oxide-based fluorescent nanosensor to identify antiviral
agents via a drug repurposing screen
7.4. Carbon nanomaterial, and its derivatives as nanobiosensors versus
COVID-19
7.5. Smart nanomaterials for biosensing technologies and their consequences
7.6. Strategies to Enhance the Biosensor Performance
7.7. Emerging nanomaterials-based biosensor for SARS-CoV-2 detection
7.8. Carbon nanotubes in protection and biosensing applications
7.9. Carbon -based nanomaterials for the management of virus
7.10. Rapid and label-free detection of H5N1 virus using carbon nanotube
network field effect transistor
7.11. How the Coronavirus Infects Our Cells?
7.12. Life Cycle of the Pandemic Coronavirus
7.13. Latest Developed Biosensors for COVID-19
7.14. (CNT-FET)-based biosensor for rapid detection of SARS-CoV-2
(COVID-19)
7.15. Functional Carbon Quantum Dots as Medical Countermeasures to Human
Coronavirus
7.16. 3D-printed graphene polylactic acid devices resistant to SARS-CoV-2
7.17. Conclusion and Perspective
8. Insights on Carbon-Based Nanomaterials as Smart Nanosystems Platform for
Cancer Theranostics Sustainable Technology
8.1. Background
8.2. Functionalization Methods of carbon nanotubes
8.3. Tumor microenvironment (TME) and opportunities
8.4. Carbon nanotubes for tumor microenvironment targeting
8.5. Stimuli responsive intelligent nanomaterial in cancer theranostics
8.6. Progress of Smart Nanoparticles Based Theranostics
8.7. Physical and chemical properties responsive nanomaterials
8.8. Synthesis of Nanomaterials
8.9. Classification of Nanomaterials
8.10. Recent Trends of Nanomaterials in Cancer Theranostics
8.11. Carbon nanotubes in cancer treatment
8.12. Carbon nanotubes in cancer diagnosis
8.13. CNTs in cancer imaging
8.14. CNTs in nanobiosensors
8.15. Multi-responsive intelligent nanomaterials
8.16. Toxicological effects of nanomaterials
8.17. Current Technological Challenges and Limitations of Effective
Theranostics
8.18. Global Opportunities of Smart Nanomaterials in Next Generation Cancer
Theranostics
8.19. Advantages, challenges, and outlooks of nanomaterials
8.20. Conclusions and future prospect
List of abbreviations
References
Index
1. Comprehensive Study of Carbon Nanomaterials-Based Nanostructured
Materials: Potential for Technological and Industrial Applications
1.1. Background of Carbon-Based Nanostructured Materials
1.2. History of Carbon Nanotube Composites
1.3. Characterization of CNTs
1.4. Classification of the Categories Carbon Nanotubes Types and Their
Properties
1.5. Different Allotropes of Carbon Related to Devices
1.6. Basic Structure and Morphology Features of CNTs
1.7. Production and Workplace Exposure to CNTS
1.8. Synthesis of Carbon Nanotubes (CNTs)
1.9. Growth Mechanism of Carbon Nanotubes (CNTs)
1.10. Methods of Purification and Dispersion of Carbon Nanotubes
1.11. Limitations and Modification (Functionalization)
1.12. Drug Loading Mechanism and Cellular Uptake of CNTs
1.13. Uptake of CNTs by Cell
1.14. Breakdown Mechanism of CNTs in the Body
1.15. Toxicity of CNTs
1.16. Different Impressive Properties of Carbon Nanotubes
1.17. Advantage and Disadvantage of Carbon Nanotubes (CNTs)
1.18. Administration of Carbon Nanotubes
1.19. Examples of Medical andTherapeutics Applications for Carbon Nanotubes
1.20. Applications of Graphene
1.21. Conclusions
2. Progression in Synthesis Processing and Growth Mechanism of Carbon
Nanomaterials for Advanced Macro-Scale Applications
2.1. Production and Main Processing Synthesis Methods of Carbon Nanotubes
2.2. Electric Arc Discharge Method
2.3. Laser Ablation Method
2.4. Purification of CNTs
2.5. Chemical Vapor-Phase Growth Production Deposition Method (CVD)
2.6. Vapor-Phase Growth Production Method
2.7. Other Emerging Methods
2.8. Experimental Reproducibility
2.9. In Situ Growth Deposition of CNTs and 2D Material Synthesis on Fibers
2.10. Substrate-Bound SWCNT Synthesis
2.11. Vertically Aligned SWCNTs
2.12. Recent Advances in Synthesis of Boron Nitride Nanotubes (BNNTs)
Growth
2.13. Influence of Precursor Gas Chemistry
2.14. Recent Trends in the Synthesis of CNTs
2.15. Methods of Carbon Nanotube-Based Fibers Production
2.16. Nanostructured Energy Materials in Fibers
2.17. Processing and Applications of Novel Functionalized Carbon Nanotubes
(CNTs)
2.18. Synthesis of Fullerenes
2.19. Methods of Graphene Preparation
2.20. Synthesis and Tuning Strategies of GQDs
2.21. Regulation Properties of GQDs
3. Bionanotechnological Applications of Fullerene (C60)-Based Modified
Development Imaging and Biosensing Devices
3.1. Introduction
3.2. Fullerenes, Their Properties and Production
3.3. Synthesis Methods of C60 Fullerene
3.4. Functionalization of Fullerene
3.5. Toxicity and Biocompatibility Evaluation of Fullerenes
3.6. Types of Fullerenes and Their Specific Uses (C60, C70, Fullerenols)
3.7. Uses of Fullerene
3.8. Fullerene in Biomedical Applications and Its Role in Drug Delivery
3.9. Other Biomedical Applications
3.10. Applications of Fullerenes in Biosensors
3.11. Modification of Electrodes with Fullerenes
3.12. Fullerene-Based Modified Sensors and Biosensors
3.13. Fullerene-Based Polymers
3.14. Conclusions and Future Prospective
4. Computational Simulation Optimization and Pharmaceutical Role of
CNTs-Based Development of New Target Drug Delivery Systems (DDSs) for
Enhance Efficacy in Anticancer Therapy
4.1. CNTs on Molecular Dynamics Simulation-Based Development of New Drug
Delivery Systems
4.2. Structural Properties and Functionalization of CNTs
4.3. Interactions of Carbon Nanotubes with the Cell Membrane
4.4. Molecular Dynamics Simulation of CNT-Cell Membrane Interactions
4.5. Computational Aspects of Solvent and Co-Solvent Effects on the
Interaction of Flutamide as Anticancer Drug Delivery System with CNT
4.6. DFT Interaction of Flutamide Drug with COOH- and COCl-Functionalized
CNTs
4.7. Molecular Dynamics Simulation Study of the Functionalized CNTs to
Enhance the Efficacy of the Anticancer Drug Paclitaxel
4.8. Computational Simulation Study of CNT as a Carrier in Drug Delivery
System for Carnosine Dipeptide
4.9. Computational Study of Leflunomide on the SWCNT and SWBNNT
4.10. Concluding Remarks
5. Cutting-Edge Nanobiotechnology in Advanced Drug Delivery Nanosystems for
CNTs, Fullerenes, NDs, and Graphene-Based Materials
5.1. Introduction
5.2. Carbon Nanotubes-Based Drug Delivery
5.3. Graphene/Graphene Oxide/Reduced Graphene Oxide
5.4. Graphene Quantum Dots (GQDs)
5.5. Fullerenes Composition
5.6. Nanodiamonds (NDs)-Based Drug Delivery
5.7. Carbon Nano-Onions (CNOs)-Based Drug Delivery
5.8. Carbon Nanotubes (CNTs)-Based Advanced Dermal Therapeutics
5.9. Toxicity Concerns for Carbon-Based Nanomaterials
5.10. Computational Investigations of Fixed-Free and Fixed-Fixed Types of
SWCNT Mass Sensing Biosensor
5.11. Conclusions
5.12. Future Perspectives
6. Bright Future of Carbon Nanomaterials for Cancer Nanomedicine-Based
Enzyme Immobilization Conjugates
6.1. Introduction
6.2. Nanozymes to CNM-Enzyme Conjugates
6.3. CNMs for Enzyme Mimicry, Inhibition, or Monitoring
6.4. Applications of CNM-Enzyme Conjugates
6.5. Enzymatic Biodegradation of CNMs
6.6. CNT based high-¿ dielectric Ion Sensitive Field Effect Transistor
Based Cholesterol Biosensor
6.7. Bright future of Carbon dots for cancer nanomedicine
6.8. Bright Future in the Fabrication of Portable Kits in Analytical
Systems
6.9. Conclusions and Future Perspectives
7. CNMs-Based Developed Biosensors for Rapid Technologies Detection
Antiviral Infection and Management Coronavirus Biomarkers
7.1. Background
7.2. Viral infection and nanomaterials
7.3. Graphene oxide-based fluorescent nanosensor to identify antiviral
agents via a drug repurposing screen
7.4. Carbon nanomaterial, and its derivatives as nanobiosensors versus
COVID-19
7.5. Smart nanomaterials for biosensing technologies and their consequences
7.6. Strategies to Enhance the Biosensor Performance
7.7. Emerging nanomaterials-based biosensor for SARS-CoV-2 detection
7.8. Carbon nanotubes in protection and biosensing applications
7.9. Carbon -based nanomaterials for the management of virus
7.10. Rapid and label-free detection of H5N1 virus using carbon nanotube
network field effect transistor
7.11. How the Coronavirus Infects Our Cells?
7.12. Life Cycle of the Pandemic Coronavirus
7.13. Latest Developed Biosensors for COVID-19
7.14. (CNT-FET)-based biosensor for rapid detection of SARS-CoV-2
(COVID-19)
7.15. Functional Carbon Quantum Dots as Medical Countermeasures to Human
Coronavirus
7.16. 3D-printed graphene polylactic acid devices resistant to SARS-CoV-2
7.17. Conclusion and Perspective
8. Insights on Carbon-Based Nanomaterials as Smart Nanosystems Platform for
Cancer Theranostics Sustainable Technology
8.1. Background
8.2. Functionalization Methods of carbon nanotubes
8.3. Tumor microenvironment (TME) and opportunities
8.4. Carbon nanotubes for tumor microenvironment targeting
8.5. Stimuli responsive intelligent nanomaterial in cancer theranostics
8.6. Progress of Smart Nanoparticles Based Theranostics
8.7. Physical and chemical properties responsive nanomaterials
8.8. Synthesis of Nanomaterials
8.9. Classification of Nanomaterials
8.10. Recent Trends of Nanomaterials in Cancer Theranostics
8.11. Carbon nanotubes in cancer treatment
8.12. Carbon nanotubes in cancer diagnosis
8.13. CNTs in cancer imaging
8.14. CNTs in nanobiosensors
8.15. Multi-responsive intelligent nanomaterials
8.16. Toxicological effects of nanomaterials
8.17. Current Technological Challenges and Limitations of Effective
Theranostics
8.18. Global Opportunities of Smart Nanomaterials in Next Generation Cancer
Theranostics
8.19. Advantages, challenges, and outlooks of nanomaterials
8.20. Conclusions and future prospect
List of abbreviations
References
Index
Materials: Potential for Technological and Industrial Applications
1.1. Background of Carbon-Based Nanostructured Materials
1.2. History of Carbon Nanotube Composites
1.3. Characterization of CNTs
1.4. Classification of the Categories Carbon Nanotubes Types and Their
Properties
1.5. Different Allotropes of Carbon Related to Devices
1.6. Basic Structure and Morphology Features of CNTs
1.7. Production and Workplace Exposure to CNTS
1.8. Synthesis of Carbon Nanotubes (CNTs)
1.9. Growth Mechanism of Carbon Nanotubes (CNTs)
1.10. Methods of Purification and Dispersion of Carbon Nanotubes
1.11. Limitations and Modification (Functionalization)
1.12. Drug Loading Mechanism and Cellular Uptake of CNTs
1.13. Uptake of CNTs by Cell
1.14. Breakdown Mechanism of CNTs in the Body
1.15. Toxicity of CNTs
1.16. Different Impressive Properties of Carbon Nanotubes
1.17. Advantage and Disadvantage of Carbon Nanotubes (CNTs)
1.18. Administration of Carbon Nanotubes
1.19. Examples of Medical andTherapeutics Applications for Carbon Nanotubes
1.20. Applications of Graphene
1.21. Conclusions
2. Progression in Synthesis Processing and Growth Mechanism of Carbon
Nanomaterials for Advanced Macro-Scale Applications
2.1. Production and Main Processing Synthesis Methods of Carbon Nanotubes
2.2. Electric Arc Discharge Method
2.3. Laser Ablation Method
2.4. Purification of CNTs
2.5. Chemical Vapor-Phase Growth Production Deposition Method (CVD)
2.6. Vapor-Phase Growth Production Method
2.7. Other Emerging Methods
2.8. Experimental Reproducibility
2.9. In Situ Growth Deposition of CNTs and 2D Material Synthesis on Fibers
2.10. Substrate-Bound SWCNT Synthesis
2.11. Vertically Aligned SWCNTs
2.12. Recent Advances in Synthesis of Boron Nitride Nanotubes (BNNTs)
Growth
2.13. Influence of Precursor Gas Chemistry
2.14. Recent Trends in the Synthesis of CNTs
2.15. Methods of Carbon Nanotube-Based Fibers Production
2.16. Nanostructured Energy Materials in Fibers
2.17. Processing and Applications of Novel Functionalized Carbon Nanotubes
(CNTs)
2.18. Synthesis of Fullerenes
2.19. Methods of Graphene Preparation
2.20. Synthesis and Tuning Strategies of GQDs
2.21. Regulation Properties of GQDs
3. Bionanotechnological Applications of Fullerene (C60)-Based Modified
Development Imaging and Biosensing Devices
3.1. Introduction
3.2. Fullerenes, Their Properties and Production
3.3. Synthesis Methods of C60 Fullerene
3.4. Functionalization of Fullerene
3.5. Toxicity and Biocompatibility Evaluation of Fullerenes
3.6. Types of Fullerenes and Their Specific Uses (C60, C70, Fullerenols)
3.7. Uses of Fullerene
3.8. Fullerene in Biomedical Applications and Its Role in Drug Delivery
3.9. Other Biomedical Applications
3.10. Applications of Fullerenes in Biosensors
3.11. Modification of Electrodes with Fullerenes
3.12. Fullerene-Based Modified Sensors and Biosensors
3.13. Fullerene-Based Polymers
3.14. Conclusions and Future Prospective
4. Computational Simulation Optimization and Pharmaceutical Role of
CNTs-Based Development of New Target Drug Delivery Systems (DDSs) for
Enhance Efficacy in Anticancer Therapy
4.1. CNTs on Molecular Dynamics Simulation-Based Development of New Drug
Delivery Systems
4.2. Structural Properties and Functionalization of CNTs
4.3. Interactions of Carbon Nanotubes with the Cell Membrane
4.4. Molecular Dynamics Simulation of CNT-Cell Membrane Interactions
4.5. Computational Aspects of Solvent and Co-Solvent Effects on the
Interaction of Flutamide as Anticancer Drug Delivery System with CNT
4.6. DFT Interaction of Flutamide Drug with COOH- and COCl-Functionalized
CNTs
4.7. Molecular Dynamics Simulation Study of the Functionalized CNTs to
Enhance the Efficacy of the Anticancer Drug Paclitaxel
4.8. Computational Simulation Study of CNT as a Carrier in Drug Delivery
System for Carnosine Dipeptide
4.9. Computational Study of Leflunomide on the SWCNT and SWBNNT
4.10. Concluding Remarks
5. Cutting-Edge Nanobiotechnology in Advanced Drug Delivery Nanosystems for
CNTs, Fullerenes, NDs, and Graphene-Based Materials
5.1. Introduction
5.2. Carbon Nanotubes-Based Drug Delivery
5.3. Graphene/Graphene Oxide/Reduced Graphene Oxide
5.4. Graphene Quantum Dots (GQDs)
5.5. Fullerenes Composition
5.6. Nanodiamonds (NDs)-Based Drug Delivery
5.7. Carbon Nano-Onions (CNOs)-Based Drug Delivery
5.8. Carbon Nanotubes (CNTs)-Based Advanced Dermal Therapeutics
5.9. Toxicity Concerns for Carbon-Based Nanomaterials
5.10. Computational Investigations of Fixed-Free and Fixed-Fixed Types of
SWCNT Mass Sensing Biosensor
5.11. Conclusions
5.12. Future Perspectives
6. Bright Future of Carbon Nanomaterials for Cancer Nanomedicine-Based
Enzyme Immobilization Conjugates
6.1. Introduction
6.2. Nanozymes to CNM-Enzyme Conjugates
6.3. CNMs for Enzyme Mimicry, Inhibition, or Monitoring
6.4. Applications of CNM-Enzyme Conjugates
6.5. Enzymatic Biodegradation of CNMs
6.6. CNT based high-¿ dielectric Ion Sensitive Field Effect Transistor
Based Cholesterol Biosensor
6.7. Bright future of Carbon dots for cancer nanomedicine
6.8. Bright Future in the Fabrication of Portable Kits in Analytical
Systems
6.9. Conclusions and Future Perspectives
7. CNMs-Based Developed Biosensors for Rapid Technologies Detection
Antiviral Infection and Management Coronavirus Biomarkers
7.1. Background
7.2. Viral infection and nanomaterials
7.3. Graphene oxide-based fluorescent nanosensor to identify antiviral
agents via a drug repurposing screen
7.4. Carbon nanomaterial, and its derivatives as nanobiosensors versus
COVID-19
7.5. Smart nanomaterials for biosensing technologies and their consequences
7.6. Strategies to Enhance the Biosensor Performance
7.7. Emerging nanomaterials-based biosensor for SARS-CoV-2 detection
7.8. Carbon nanotubes in protection and biosensing applications
7.9. Carbon -based nanomaterials for the management of virus
7.10. Rapid and label-free detection of H5N1 virus using carbon nanotube
network field effect transistor
7.11. How the Coronavirus Infects Our Cells?
7.12. Life Cycle of the Pandemic Coronavirus
7.13. Latest Developed Biosensors for COVID-19
7.14. (CNT-FET)-based biosensor for rapid detection of SARS-CoV-2
(COVID-19)
7.15. Functional Carbon Quantum Dots as Medical Countermeasures to Human
Coronavirus
7.16. 3D-printed graphene polylactic acid devices resistant to SARS-CoV-2
7.17. Conclusion and Perspective
8. Insights on Carbon-Based Nanomaterials as Smart Nanosystems Platform for
Cancer Theranostics Sustainable Technology
8.1. Background
8.2. Functionalization Methods of carbon nanotubes
8.3. Tumor microenvironment (TME) and opportunities
8.4. Carbon nanotubes for tumor microenvironment targeting
8.5. Stimuli responsive intelligent nanomaterial in cancer theranostics
8.6. Progress of Smart Nanoparticles Based Theranostics
8.7. Physical and chemical properties responsive nanomaterials
8.8. Synthesis of Nanomaterials
8.9. Classification of Nanomaterials
8.10. Recent Trends of Nanomaterials in Cancer Theranostics
8.11. Carbon nanotubes in cancer treatment
8.12. Carbon nanotubes in cancer diagnosis
8.13. CNTs in cancer imaging
8.14. CNTs in nanobiosensors
8.15. Multi-responsive intelligent nanomaterials
8.16. Toxicological effects of nanomaterials
8.17. Current Technological Challenges and Limitations of Effective
Theranostics
8.18. Global Opportunities of Smart Nanomaterials in Next Generation Cancer
Theranostics
8.19. Advantages, challenges, and outlooks of nanomaterials
8.20. Conclusions and future prospect
List of abbreviations
References
Index