Green sustainable process for chemical and environmental engineering and science : biomedical applications of green composites / edited by Inamuddin, Tariq Altalhi.

Format:

Book

Contributor:

Inamuddin, 1980- editor.

Altalhi, Tariq, editor.

Language:

English

Subjects (All):

Biomedical materials--Environmental aspects.

Biomedical materials.

Composite materials.

Drug delivery systems.

Drug Delivery Systems.

Green Chemistry Technology.

Composite Resins.

Ceramides.

Capsules.

Medical Subjects:

Drug Delivery Systems.

Green Chemistry Technology.

Composite Resins.

Ceramides.

Capsules.

Physical Description:

1 online resource (382 pages)

Edition:

1st ed.

Place of Publication:

Amsterdam, The Netherlands ; Oxford, England ; Cambridge, Massachusetts : Elsevier, [2023]

Summary:

Biomedical Applications of Green Composites reviews the use of green composite materials in drug delivery, with a focus on capsules, resins and ceramides in biomedical fields.Chapters present green composites of polymeric origin and targeted delivery of drugs into various parts of the human body.

Contents:

Front cover

Half Title

Title

Copyright

Contents

Contributors

Chapter 1 Green Composites for Drugs Capsule Coatings

1.1 Introduction

1.2 Capsule

1.3 Techniques for manufacturing capsules

1.3.1 Preparation of soft capsule

1.3.2 Preparation of hard capsule

1.4 Polymers for capsule coating

1.4.1 Gelatin composites capsule

1.4.2 Starch composites capsule

1.4.3 Chitosan composites capsule

1.4.4 Hypromellose composites capsule

1.4.5 Other natural polymer composites for capsule coating

1.5 Conclusion

References

Chapter 2 Applications of bioresins and biopolymers derived from natural resources as composites in drug delivery

2.1 Introduction

2.2 Bioresins

2.3 Bioresin composites

2.4 Applications of Bioresins as composites in drug delivery

2.5 Biopolymers

2.6 Biopolymer composites

2.7 Biopolymer composites for pH sensitive colon drug delivery

2.8 Biopolymer composites for transdermal drug delivery

2.9 Biopolymer composites for buccal drug delivery

2.10 Biopolymer composites for ocular drug delivery

2.11 Biopolymer nanocomposites for theranostic applications in cancer

2.12 Biopolymer composites for tissue engineering

2.13 Biopolymer conjugates for gene delivery

2.14 Conclusion

Chapter 3 Skin ceramides based systems in transdermal drug delivery and skin care

3.1 Introduction

3.2 Skin care products

3.3 Dermal and transdermal drug delivery

3.4 Concluding remarks

Chapter 4 Biomedical applications of bio-degradable green composites

4.1 Introduction

4.2 Biodegradable green composites for biomedical applications

4.2.1 Natural fibers \(biofibers\) as reinforcing materials

4.2.2 Biopolymers, biodegradable natural polymers or biobinders

4.3 Current biomedical applications of biodegradable green composites.

4.3.1 Drug delivery

4.3.2 Tissue engineering

4.3.3 Wound care

4.3.4 Health care and hygiene materials

4.3.5 Three-dimensional printing bioinks

4.3.6 Biosensing

4.4 Conclusions and future perspectives

Chapter 5 Applications of Composite Materials in Drug Delivery Systems

5.1 Introduction

5.2 Green composites

5.2.1 Natural fibres

5.2.2 Fibre Extraction Process

5.2.3 Pre-treatment

5.2.4 Biopolymers

5.2.5 Superiority of bio-polymer composite

5.2.6 Factors influencing robustness of composite

5.3 Benefits of green composites

5.4 Disadvantages of green composites

5.5 Drug delivery applications

5.5.1 Composite in transdermal drug delivery

5.5.2 Composite as implant

5.5.3 Composite in wound healing

5.5.4 Composites in cancer chemotherapy

5.5.5 Composite in tissue engineering

5.6 Conclusion

Chapter 6 Green composites materials as a carrier for pulmonary drug delivery

6.1 Introduction

6.2 Role of polymers in biomedical field

6.3 Role of green composites in biomedical field

6.4 Pulmonary drug delivery systems

6.4.1 Green composites

6.4.2 Synthetic biodegradable polymer

6.4.3 Biodegradable polymeric microspheres

6.5 Clinical trials

6.6 Inhaler devices

6.7 Human factors

6.8 Scale-up challenges

6.9 Conclusion

Chapter 7 Antimicrobial Green Composites

7.1 Introduction

7.2 History of antibiotics

7.3 Mechanisms of antibiotic and microbial resistance

7.4 Antimicrobial green composites

7.4.1 Antimicrobial mechanisms of polymers

7.4.2 Chitosan composites

7.4.3 Poly (ɛ-Lysine) composites

7.4.4 Dextran composites

7.4.5 Gelatin composites

7.4.6 Nisin composites

7.4.7 Pectin composites

7.5 Conclusion

Chapter 8 Antibacterial and anti-fungal coating

8.1 Introduction.

8.2 Polymeric green composites

8.3 Applications of antibacterial and anti-fungal coatings

8.4 Coating methods of polymeric green composites

8.4.1 Sol-gel technique

8.4.2 Pulsed lase deposition

8.4.3 Spin coating technique

8.4.4 Dip coating technique

8.4.5 Spray coating

8.5 Conclusion

Chapter 9 Peptide based composites for biomedical application: focus on the new age of pathogen control

9.1 Composite materials to tackle antibiotic resistance: a paradigm shift

9.2 Biomedical challenges of pathogen control

9.2.1 Emergence of next-gen drug resistance

9.2.2 The general principle of antibiosis: why conventional drugs fall short?

9.2.3 Evolution of a "gain of function": molecularmechanism in drug resistance

9.3 Mechanistic interaction of peptide/non-peptide in composites

9.3.1 Recent developments in peptide based composites

9.4 Antimicrobial Peptides in action

9.5 Pipeline for developing peptide based novel composites for pathogen control

9.5.1 Characterization of the peptide entity in the bio-composite

9.6 Challenges &amp

future prospect of peptide based composites for pathogen control

9.7 Conclusion

Chapter 10 The composition, bio-functionalities and challenges in use of Green composites in dentistry

10.1 Introduction

10.2 Background

10.2.1 Uses of composites in dentistry

10.2.2 The desired qualities in the green composites would be

10.3 Composition of green composites

10.3.1 The prime concerns in preparation of green composites are

10.3.2 The two main components of the green composites include

10.3.3 Natural/biofibers may be classified in 2 categories

10.3.4 Resources that can be used for preparation of natural or green composites

10.4 Biofunctionalities of green composites.

10.4.1 The considerable issues in relation with natural fiber reinforced composites are

10.5 Challenges in use of green composites

10.6 Future

10.7 Conclusion

Chapter 11 Green technology-driven novel, safe metal nanoparticles for cancer therapy: Present facts, current needs and future trends

11.1 Introduction

11.2 Nanotechnology

11.3 Green nanotechnology

11.4 Green synthesis of nano-particulates

11.5 Green nanocarriers and cancer therapy

11.5.1 Lung cancer

11.5.2 Gastric cancer

11.5.3 Liver cancer

11.5.4 Breast cancer

11.5.5 Colon cancer

11.6 Risks perspective

11.6.1 Risk assessment

11.6.2 Risk management

11.6.3 Risk communication

11.7 Clinical trials

11.8 Market overview of green nanocarriers

11.9 Scale-up challenges

11.10 Conclusion

Acknowledgment

Chapter 12 Recent trends in the applications of nanocomposites in cancer theranostics

12.1 Introduction

12.2 Nanoparticles for the construction of nanotheranostic agents

12.2.1 Gold nanoparticles

12.2.2 Upconversion nanoparticles

12.2.3 Magnetic nanoparticles

12.2.4 Carbon based nanomaterials

12.2.5 Silica based nanoparticles

12.2.6 Semiconductor nanoparticles

12.2.7 Conducting polymer based nanoparticles

12.3 Nanocomposites in phototherapy of cancer

12.3.1 Photothermal therapy

12.3.2 Photodynamic therapy

12.3.3 Combined therapy

12.4 Nanocomposites for multimodal imaging guided combinatorial therapies

12.5 Miscellaneous applications of nanocomposites in cancer therapy

12.6 Design strategies for achieving synergistic theranostic effect

12.7 Conclusion

Chapter 13 Advance applications of polymeric green composites inmedical bio-science - Bone engineering

13.1 Introduction.

13.2 Various polymeric green composite materials for bio-medical applications

13.2.1 For bone engineering

13.2.2 Implants and medical devices \(Bio-resorbable green composite materials\)

13.2.3 Wound dressing

13.3 Application of green composite in bone engineering, orthopaedic/craniofacial implants and wound dressing

13.3.1 Principle of tissue engineering

13.3.2 Bone engineering with bio-degradable (green composite) scaffold

13.3.3 Studies related to the application of bio-degradable (green composite) scaffold for bone engineering, orthopaedic/craniofacial implants and wound dressing

13.4 Conclusion

Acknowledgments

Chapter 14 Biocompatible and biodegradable materials in medical applications

14.1 Introduction

14.2 Animal-Based biomaterials

14.2.1 Chitosan

14.2.2 Collagen

14.2.3 Gelatine

14.3 Plant-Based materials

14.3.1 Cellulose

14.3.2 Carrageenan

14.3.3 Pectin

14.4 Other bio-based materials

14.4.1 Dextran

14.4.2 Bacterial cellulose (BC)

14.4.3 Alginate

14.4.4 Agarose

14.5 Future trend

14.6 Conclusion

Conflict of interest

Index

Back cover.

Notes:

Includes bibliographical references and index.

Description based on print version record.

Description based on publisher supplied metadata and other sources.

Other Format:

Print version: Inamuddin Green Sustainable Process for Chemical and Environmental Engineering and Science

ISBN:

9780323951692

9780323951708

0323951708

OCLC:

1369659051