Next Generation Nanochitosan: Applications in Animal Husbandry, Aquaculture and Food Conservation provides comprehensive and state-of-the-art-information on the application of nanochitosan for improving products, especially for the evaluation of biological active molecules, disease therapeutics, transport vehicle for DNA, targeted drug delivery, gene therapy, development of smart and high performance of fish, preservation of foods, tissue engineering, and improving the taste of aquatic and animal feeds as fish growth promoter. this book will be especially useful for industrial fisheries who deal with wild capture fishing and aquafarming and scientists and engineers working on post-capture processing stages. Details on the application of nanochitosan as an effective delivery of vaccines, hormones, vitamins, nutrients and antioxidants, biological active constituents and their wider application for the protection and management of farm animals and fishes against disease-causing pathogens are provided.

Applications of Nanotechnology in Drug Discovery and Delivery, in the Drug Discovery Update series, presents complete coverage of the application of nanotechnology in the discovery of new drugs and efficient target delivery of drugs. The book highlights recent advances of nanotechnology applications in the biomedical sciences, starting with chapters that provide the basics of nanotechnology, nanoparticles and nanocarriers. Part II deals with the application of nanotechnology in drug discovery, with an emphasis on enhanced delivery of pharmaceutical products, with Part III discussing toxicological and safety issues arising from the use of nanomaterials. This book brings together a global team of experts, making it an essential resource for researchers, drug developers, medicinal chemists, toxicologists and analytical chemists.

Emerging Nanomedicines for Diabetes Mellitus Theranostics provides readers with information on the development of efficacious nanomedicines as potential theranostic agents for diabetes. The book discusses the application of various novel nanomaterials and nanocomposites for targeted delivery of insulin, glucose sensing, including nano-tattoos as glucose monitors, biosynthesized nanoparticles for diabetes treatment, and pre-clinical and clinical assays to evaluate the efficacy of nanomedicines for diabetes treatment. This is an important references source for materials scientists, pharmaceutical scientists and biomedical engineers who want to increase their understanding of how nanotechnology is being used to improve diabetes treatment. Diabetes has emerged as one of the most common diseases associated with lifestyle choices in the modern world, with significant mortality rates. Conventional treatment methods mainly involve insulin-based therapies. However, insulin therapy possesses several limitations such as weight gain and hypoglycemia. Thus, advanced research in nanomedicine is targeting the development of new and improved diagnostics and treatment methods for diabetes.

Bionanomaterials are identified as a perfect replacement, in the quest for the search of an alternative to toxic conventional nanomaterials for biomedical applications. Bionanomaterials are the nanomaterials, that are fabricated via biomolecules or encapsulate or immobilize a conventional nanomaterial with a biomolecule. The biomolecules extracted from the microbes, plants, agricultural wastes, insects, marine organisms and certain animals are used for the formation of bionanomaterials. These bionanomaterials exhibited low or negligible toxicity towards humans, other organisms and the environment with enhanced biocompatibility, bioavailability and bioreactivity. Thus, the aim of this book is to provide an overview of various bionanomaterials, their synthesis, characterization and their application-oriented properties. The book is divided into two parts - Part 1 discusses about the bionanomaterials of exclusive natural origin, self-assembled bionanomaterials and their environmental application and Part 2 focuses on applications of distinct bionanomaterials in biomedical sciences. The 'Chapter 1 - Bionanomaterials: Definitions, sources, types, properties, market, toxicity and regulations' aims to provide an extensive overview of bionanomaterials, their definitions, sources, types and their properties. In addition, the toxicity of bionanomaterials and their regulations implied in recent times were also discussed. 'Chapter 2 - Nature inspired bionanomaterials' highlights different types of nature-inspired biosynthesized nanomaterials and their green synthesis methods, as well as some of their emerging applications, especially in the fields of nanomedicine, cosmetics, drug delivery, molecular imaging, and catalytic precursors. Further, the chapter also covers different types of bionanomaterials (e.g., viruses, protein cages, and phages) and highlights their unique properties and potential applications. 'Chapter 3 - Culinary spices mediated biogenesis of nanoparticles for cancer and diabetes treatment' deals with bionanomaterials synthesized by using extracts of culinary spices and its vital role in the treatment of distinct types of cancer and diabetes. In 'Chapter 4 - Environment friendly superhydrophobic bioactive nanocoatings', the authors have discussed the basics of exceptional water repellence behaviour and recent developments in the area of bioactive-SHC for various applications. In addition, the current and projected requirements for bioactive-SHC were also addressed. The authors of 'Chapter 5 - Self-assembly of nanobionics: from theory to application' reviewed, discussed, addressed and highlighted the recent advancements in bionics as an interdisciplinary field to understand the bionic materials and particles, that are mainly fabricated via self-assembly approach. In part 2, the 'Chapter 6 - Inorganic bionanomaterials for biomedical applications' provides an overview of inorganic bionanomaterials, its distinct types, synthesis procedures, properties and characteristics, which is essential for desired applications. 'Chapter 7 - Polymer nanomaterials for biomedical applications' is a comprehensive review of various polymer nanocomposite types, and further describes the synthesis, preparation, structure and biomedical application of nanocomposites. In addition, the recent developments in the field of polymer nanocomposites for biomedical applications were also discussed. 'Chapter 8 - Lignin nanoparticles and their biomedical applications' aims in highlighting the current trends in lignin nanoparticle depolymerization approach, focusing on microbial lignin degradation, optimization, and its biomedical applications. The authors of 'Chapter 9 - Polymer-based nanomaterials for targeted drug delivery' addressed the use of polymeric bionanomaterials, including hydrogels, electrospun nanofibrous scaffolds, nanocellulose, and carbohydrate nanocarriers with special emphasis to their material properties, fabrication technologies and applicability in specific targeted anatomical sites. Moreover, 'Chapter 10 - Cationic nanoparticles for treatment of neurological diseases' discusses about brain disorders, the role of nutraceuticals, mechanisms, delivery challenges, as well as formulation techniques and prospects of cationic nanoparticles in the therapeutic management of neuronal disorders, i.e., brain as site of drug target. Besides, 'Chapter 11 - Carbon nanomaterials for therapeutic applications' has highlighted the cutting-edge properties, mechanism of action, and advancements of carbon nanomaterials as drug delivery system in various diseases, such as cancer and inflammatory disorders. Further, the chapter also sheds light on the potential challenges, limitations, and future outlook for improving and growing carbon-based bionanomaterials. The final chapter 'Chapter 12 - Liposomal bionanomaterials for nucleic acid delivery' is a brief summary of various nucleic acid-based cationic liposomes as a potential bionanomaterial and its recent progress in the application of therapeutic nucleic acid delivery. We hope that this book will enlighten undergraduates, graduates, and industrial as well as academic researchers on the synthesis, characterization and property-oriented applications of certain exclusive bionanomaterials.

Emerging Phytosynthesized Nanomaterials for Biomedical Applications provides readers with an increased understanding of the efficacy of phytochemicals obtained from plant extracts for the synthesis of nanomaterials, mechanism of formation, and the development of functional composites, all while still minimizing toxicity to humans and the environment. The book presents various novel biomedical applications of phytosynthesized nanomaterials for cancer, diabetes and cardiovascular treatment, drug delivery, antimicrobial agents, orthopedics, and biosensors, as well as pharmaceutical product development. This is an important reference source for biomaterials scientists and plant scientists looking to increase their understanding of how photosynthesized nanomaterials can be used in biomedical applications.

This book entitled ‘Application of Nanotechnology in Food Science, Processing and Packaging’ presents up-to-date information on the emerging roles of nanotechnology in food industry, its fundamental concepts, techniques and applications. The application of nanotechnology in the food industry is an emerging area which has found tremendous use in improving food quality through the enhancement of food taste, texture, colour, and flavour. Also, its application has improved the bioavailability and target delivery of certain bioactive food ingredients through controlled release of nutrients, a feature that is impossible with the conventional methods of food processing. The application of nanotechnology in food packaging for the detection of contaminants, pathogens, biotoxins and pesticides through nanosensor safety evaluations has led to the increase in shelf-life of products and quality assurance through the detection and monitoring of toxins. This book taps from the experience of subject experts from key institutions around the world. The users of this book will benefit greatly as the chapters were simplified and arranged carefully to aid proper understanding, consistency and continuity.

Bionanotechnology: Emerging Applications of Bionanomaterials highlights a wide range of industrial applications using bionanotechnologies, with biomedical applications prominent amongst these, including drug delivery, tissue engineering, wound healing, medical implants, medical diagnostics and therapy. Other key areas include energy harvesting and storage, water/waste treatment, papermaking, textiles, construction industry, automotive, aerospace. This book is a valuable resource for all those seeking to gain a fundamental understanding of how bionanomaterials are used in a variety of industry sectors. Bionanomaterials are molecular materials composed partially or completely of biological molecules - such as proteins, enzymes, viruses, DNA and biopolymers - as well as metal, metal oxides, and carbon nanomaterials. Bionanomaterials have drawn much attention for their use in a wide range of industrial applications, including scaffolds, dental implants, drug delivery, dialysis, biobatteries, biofuel cells, air purification, and water treatment.

This book entitled 'Application of Nanotechnology in Food Science, Processing and Packaging' presents up-to-date information on the emerging roles of nanotechnology in food industry, its fundamental concepts, techniques and applications. The application of nanotechnology in the food industry is an emerging area which has found tremendous use in improving food quality through the enhancement of food taste, texture, colour, and flavour. Also, its application has improved the bioavailability and target delivery of certain bioactive food ingredients through controlled release of nutrients, a feature that is impossible with the conventional methods of food processing. The application of nanotechnology in food packaging for the detection of contaminants, pathogens, biotoxins and pesticides through nanosensor safety evaluations has led to the increase in shelf-life of products and quality assurance through the detection and monitoring of toxins. This book taps from the experience of subject experts from key institutions around the world. The users of this book will benefit greatly as the chapters were simplified and arranged carefully to aid proper understanding, consistency and continuity.

Dynamic light scattering (DLS) is an important concept that has found applications in the characterization of the biophysical properties of materials for a wide range of applications. DLS studies are extensively employed in material science and engineering to evaluate particle size distribution and surface charge for applications in nanomaterial synthesis, biomolecular analysis, pharmaceutical development and environmental applications. The aim of this book is to provide an overview of research advances relating to the principle and applications of DLS in various fields. The book is divided into two parts a Part 1 discusses the uses of DLS in material science and engineering applications and Part 2 focuses on applications of DLS in biological sciences. Chapter 1aDLS Studies: Recent Trends in Characterizationaaims to provide an overview of the working principle, mathematical models and different types of DLS analysis methods. In addition, recent trends in DLS studies and applications in various fields are also discussed. Chapter 2aApplication of DLS Technique in Nanomaterial Characterizationadiscusses the uses of DLS for nanomaterial characterization in terms of the size, size distribution and zeta potential of particles. Chapter 3aPotentialities of DLS with SAXS Studies to Analyze Heterogenous Nanocatalysta compares two techniques (DLS and SAXS) and provides evidence that nanocatalyst can be characterized more effectively by modifying DLS with SAXS. In Chapter 4aDLS Studies on Self-Assembling Copolymer Nanostructuresathe authors demonstrate the application of DLS in characterizing self-assembling and stimuli-responsive di-block copolymers in aqueous media and their association with low molecular weight drugs. Chapter 5a Slow and Ultraslow Relaxations in Molecular and Ionic Liquids-based Unary and Binary Systemsadiscusses slow and ultraslow dynamics, probed by DLS measurements, in common organic molecular liquids, ionic liquids (ILs), aqueous solutions of salts and molecular solids and liquid-liquid binary mixtures. In part 2, Chapter 6aApplications of DLS Studies in Phytochemical Analysisa discusses the application of dynamic light scattering for particle size determination using natural phytochemicals derived from plants. Chapter 7aApplications of DLS in Pharmaceutical Industrya is a comprehensive review of DLS analysis in pharmaceutical research, development and production. Chapter 8aDLS Studies of the Protein-Surfactant Systemadiscusses the relationship between viscosity and DLS measurement using the growth behavior of SDS micelle. The authors ofaChapter 9aApplications of DLS Studies in Microbial Surface Charge Analysisaprovides an overview of the wider applications of DLS studies in evaluating the surface charge of microbes via zeta potential analysis. Additionally, the mechanisms of microbial surface charge in elevating their growth rate is also discussed. The final chapteraOverview and Future Perspective of DLS Studiesais a brief summary of the application of DLS analysis in various fields and the relevant considerations for DLS analysis in particle characterization. In addition, hybrid instrumentation and DLS coupling with other techniques are discussed. We hope that this book will help to enlighten undergraduates and graduates research students as well as early and seasoned researchers on advances in DLS techniques and emerging applications.