Poly(lactic-co-glycolic acid) (PLGA) Nanoparticles for Drug Delivery is a comprehensive guide to PLGA nanoparticles for targeting various diseases, covering principles, formation, characterization, applications, regulations and the latest advances. Sections introduce the fundamental aspects of PLGA nanoparticles for drug delivery, including properties, preparation methods, characterization, drug loading methods, and drug release mechanisms, along with a focus on applications. Application of PLGA nanoparticles for the treatment of cancer, inflammatory, cerebral, cardiovascular, and infectious diseases, as well as in regenerative medicine, photodynamic and photothermal therapy, and gene therapy, are all explained in detail. The final chapters explore recent advances and regulatory aspects. This book is a valuable resource for researchers and advanced students across nanomedicine, polymer science, bio-based materials, chemistry, biomedicine, biotechnology, and materials engineering, as well as for industrial scientists and R&D professionals with an interest in nanoparticles for drug delivery, pharmaceutical formulations and regulations, and development of innovative biodegradable materials.

Phase Change Materials for Heat Transfer focuses on how to maximize the heat transfer rate and thermal storage capability of PCMs. Various aspects are covered, including preparation of phase change materials to heat transfer enhancement and characteristics with an emphasis on prominent applications. The book is designed in such a manner to cover the broad definitions, introduction, brief history, preparation techniques, thermophysical properties and heat transfer characteristics with mathematical models, performance-affecting factors and the applications and challenges of PCMs. This handbook will prove invaluable to readers interested in a resource with the latest information in this emerging field.

Advanced Applications of Biobased Materials: Food, Biomedical, and Environmental Applications brings together cutting-edge developments in the preparation and application of biobased materials. The book begins by providing an overview of biobased materials, their classification, and their physical and chemical modifications. This is followed by a section covering the latest techniques in fabrication, processing and characterization. Subsequent chapters are grouped by application area, offering insights into advanced and emerging utilizations of biobased materials in food, biomedical and environmental applications. Sections cover lifecycle assessment, circular economy, sustainability, and future potential. This is a valuable resource for researchers, scientists and advanced students across polymer science, sustainable materials, biomaterials, materials chemistry, composite science, nanotechnology, biomedical engineering, and environmental science, as well a great book for engineers and R&D with an interest in biobased materials for emerging applications in the areas of biomedicine, food and the environment.

Antimicrobial Nanosystems: Fabrication and Development provides an in-depth review of nanotechnological advancements in the fields of biotechnology and pharmaceutical industries to counteract bacterial infections and related health issues. Functionalized nanomaterials and their processes are covered, along with the theory and fabrication of antimicrobial nanosystems. The potential applications of antimicrobial nanosystems are also discussed along with their challenges and commercialization. This book discusses the most frequent problems caused by resistant microorganisms and difficult-to-treat bacteria and highlights the impact of recently developed antimicrobial nanosystems. Various methodsto obtain efficient nanomaterials with antimicrobial properties are described, along with their advantages, challenges, and main applications. The design of targeting antimicrobial therapeutics, able to specifically detect pathogenic microorganisms and to act in a very specific manner, is thoroughly investigated.

Light, Plasmonics and Particles focuses on the fundamental science and engineering applications of light scattering by particles, aerosols and hydrosols, and of localized plasmonics. The book is intended to be a self-contained and coherent resource volume for graduate students and professionals in the disciplines of materials science, engineering and related disciplines of physics and chemistry. In addition to chapters related to fundamental concepts, it includes detailed discussion of different numerical models, experimental systems and applications. In order to develop new devices, processes and applications, we need to advance our understanding of light-matter interactions. For this purpose, we need to have a firm grasp of electromagnetic wave phenomena, and absorption and scattering of waves by different size and shape geometrical objects. In addition, understanding of tunneling of waves based on electron and lattice vibrations and coupling with the thermal fluctuations to enhance near-field energy transfer mechanisms are required for the development of future energy harvesting devices and sensors.

Studies on integer optimization in emergency management have attracted engineers and scientists from various disciplines such as management, mathematics, computer science, and other fields. Although there are a large number of literature reports on integer planning and emergency events, few books systematically explain the combination of the two. Researchers need a clear and thorough presentation of the theory and application of integer programming methods for emergency management. Integer Optimization and its Computation in Emergency Management investigates the computation theory of integer optimization, developing integer programming methods for emergency management and explores related practical applications. Pursuing a holistic approach, this book establishes a fundamental framework for this topic, intended for graduate students who are interested in operations research and optimization, researchers investigating emergency management, and algorithm design engineers working on integer programming or other optimization applications.

Green Sustainable Process for Chemical and Environmental Engineering and Science: Applications of Advanced Nanostructured Materials in Wastewater Remediation reviews recent applications of nanostructured materials for remediation, their preparation, characterization and efficiency for water remediation technologies. The book provides ideas on how nanomaterials are the real solution to water purification or new environmental threat. Sections cover nanomaterial adsorbents, functionalized magnetic nanomaterials, nanostructured polymer hydrogels, carbon nanomaterials, biogenic nanoparticles, green chemistry concepts, aqua defluoridation, and advanced remediation techniques. The book also includes the current status of wastewater treatment using nanomaterials, along with challenges and perspectives for further improvements.

Multifunctional Phase Change Materials: Fundamentals, Properties and Applications updates on phase change materials (PCMs) used for the storage of thermal energy as sensible and latent heat. This class of materials is the subject of intensive research, both fundamental and applied, as they substantially contribute to the efficient use and conservation of waste heat and solar energy. Different groups of materials have been investigated as PCMs, including inorganic systems (salt and salt hydrates), organic, e.g., paraffins or fatty acids, polymers, and finally, hybrid materials. Recent developments are focused on multifunctional PCMs that provide functional features apart from energy storage, such as desired optical or antibacterial properties. This book presents various synthesis approaches for functionalized materials, as well as specific interactions and self-organization effects in polymer/functionalized (nano)particle systems. It reviews the current state-of-the-art in multifunctional phase change materials for thermal energy storage applications by describing the fundamentals of energy storage, the main classes of PCMs, functionalization protocols, encapsulation methods and shape stabilization procedures.

Advanced Nanomaterials and Nanocomposites for Bioelectrochemical Systems covers advancements in nanomaterial and nanocomposite applications for microbial fuel cells. One of the advantages of using microbial fuel cells is the simultaneous treatment of wastewater and the generation of electricity from complex organic waste and biomass, which demonstrates that microbial fuel cells are an active area of frontier research. The addition of microorganisms is essential to enhance the reaction kinetics. This type of fuel cell helps to convert complex organic waste into useful energy through the metabolic activity of microorganisms, thereby generating energy. By incorporating nano-scale fillers into the nanocomposite matrix, the performance of the anode material can be improved. This is an important reference source for materials scientists and engineers who want to learn more about how nanotechnology is being used to create more efficient fuel cells.

Functional Materials from Carbon, Inorganic and Organic Sources: Methods and Advances describes the basic principles, mechanisms and theoretical background of functional materials. Sections cover Carbon-based functional materials, Inorganic functional materials for renewable and sustainable energy applications, and Organic and biological based functional materials. Applications such as energy storage and conversion, electronic and photonics devices, and in medicine are also explored. Sections dive into photovoltaic devices, light emitting devices, energy storage materials and quantum dot devices, solar cell fundamentals and devices, perovskite materials and ceramic thin films. Final sections emphasize green approaches to synthesis in semiconductor nanoparticles, quinolone complexes, biomaterials and biopolymers.

Modern Luminescence: From Fundamental Concepts to Materials and Applications, Volume One, Concepts and Luminescence is a multivolume work that reviews the fundamental principles, properties and applications of luminescent materials. Topics addressed include key concepts of luminescence, with a focus on important characterization techniques to understand a wide category of luminescent materials. The most relevant luminescent materials, such as transition metals, rare-earth materials, actinide-based materials, and organic materials are discussed, along with emerging applications of luminescent materials in biomedicine, solid state devices, and the development of hybrid materials. This book is an important introduction to the underlying scientific concepts needed to understand luminescence, such as atomic and molecular physics and chemistry. Other topics explored cover the latest advances in materials characterization methods, such as Raman spectroscopy, ultrafast spectroscopy, nonlinear spectroscopy, and more. Finally, there is a focus on the materials physics of nanophotonics.

Plant Polysaccharides as Pharmaceutical Excipients explores innovative techniques and applications of plant-derived polysaccharides as pharmaceutical excipients. Plant polysaccharides are sustainable, renewable and abundantly available, offering attractive properties in terms of water solubility, swelling ability, non-toxicity and biodegradability. These qualities have resulted in extensive exploration into their applications as excipients in a variety of pharmaceutical dosage forms. This book takes a comprehensive, application-oriented approach, drawing on the very latest research that includes sources, classification and extraction methods of plant polysaccharides. Subsequent chapters focus on plant polysaccharides for individual pharmaceutical applications, enabling the reader to understand their preparation for specific targeted uses. Throughout the book, information is supported by illustrations, chemical structures, flow charts and data tables, providing a clear understanding. Finally, future perspectives and challenges are reviewed and discussed.

3D Printing Technology for Water Treatment Applications provides a state-of-the-art presentation on the application of 3D printing technology in water treatment. The book discusses numerous processes and their scope for improvement through the use of 3D-printing technology, including pollutant separation from water and an overview of the advantages and disadvantages of different 3D printed technology over current technologies. In addition, the future outlook for device development using 3D printing water purification is explored. Finally, sustainability issues relating to 3D printing-based water purification processes are discussed, describing specific technologies such as 3D printed membranes. This book will serve as a vital resource for scientists, engineers and environmental professionals working in water treatment technologies.

Presents a key overview of the latest advances in the synthesis, engineering and fabrication of carbon quantum dots for sustainable technologies

Antiviral and Antimicrobial Smart Coatings: Fundamentals and Applications provides a critical analysis of all types of smart antiviral and antimicrobial coatings currently being researched. The book opens with a discussion of the microbial and viral pathogens, including how to identify them and their interaction with surfaces. The next three sections look at the concept of smart coatings, specifically antibacterial, antifungal, and antiviral smart coatings, types, effects, and applications. The book concludes by discussing the methods and standards for characterization of coatings and then presents several real world case studies. A valuable resource for those working in the smart coatings field.

Advances in Healthcare and Protective Textiles addresses technologies that have had a major impact in industry for decades, but which are currently attracting unprecedented attention due to their applications in the fight against the Coronavirus epidemic. Recent advances in textile technology have opened new possibilities for textile researchers and scientists in antiviral textiles, flame-retardant textiles, antimicrobial textiles, insect repellent textiles, breathable medical textiles, aroma-protective textiles, high tech-textiles, smart textiles, nano textiles, and more. This book provides systematic and comprehensive coverage of cutting-edge research and developments on material design, methodologies, characterizations, processes, properties and applications of medical healthcare and protective textiles. In addition, sections pay special attention to advanced fabrication methodologies and materials used in apparel engineering.

Nanotechnology in Human Health: Current Research and Future Trends details the various challenges faced in human healthcare settings and how nanotechnology can be used to target and improve outcomes. The book describes the application of nanoparticles in the diagnosis of human diseases, including metabolic diseases, cancer, bacterial infection, organ degeneration and the various targeted, nano-based treatments available. Several chapters look at how microbial biofilms - a key clinical concern - can be mitigated using nanomaterials and nanotechnology. In addition, the book covers how different nanoparticle types can be utilized as therapeutic agents. This book combines materials science concepts and techniques with clinical insights and understanding to provide an interdisciplinary reference for materials scientists, microbiologists, biomedical engineers and clinicians with an interest in nanotechnology.

Novel Platforms for Drug Delivery Applications covers diverse aspects in the design, synthesis and characterization of novel drug delivery platforms and devices. This book comprehensively details the development, application and performance of various novel molecular frameworks as potent drug delivery vehicles. Chapters cover a range of materials and molecular platforms for drug delivery, from hydrogels, nanocarriers and metal-organic-frameworks, to ?-cyclodextrin and polyphosphazene. Each chapter discusses the benefits and limitations of each drug delivery system, as well as toxicological and safety implications. This book offers an interdisciplinary approach to this fast-moving topic, bridging the disciplines of materials science and pharmacology.

Welding of Metallic Materials: Methods, Metallurgy and Performance looks at technical welding methods used based on different principles and sources, such as heat, with or without pressure, electrical, plasma, laser and cold-based welding. The metallurgical aspects associated with the welding processes, specifically those associated with metallic alloys, are explained, alongside the advantages and welding features that are associated with specific welding processes. In addition, the performance of metallic weldments under specific conditions and environments such as offshore, oil industry, radiation and high-temperature services are discussed. This book will a vital resource for researchers, practicing engineers and undergraduate and graduate students in the field of materials science and engineering.

Lanthanide Doped Aluminate Phosphors: Synthesis, Properties, and Applications overviews advances in research on aluminate-based long persistent phosphors and their applications in lighting, display, radiation dosimetry and imaging. The book reviews the most important categories of rare earth aluminate-based phosphors, including aluminosilicates and aluminoborates. This category of material is attractive for a wide range of applications because of their high quantum efficiency, long afterglow life, chemical stability and optical properties, which is discussed throughout. Optical properties, in particular, are emphasized in the book along with the relationship of the chemical composition and doping of these materials and their optical performance. This book is suitable for researchers and practitioners working in academia and research and development in industry in the disciplines of materials science and engineering, chemistry and physics.

Adapting the Built Environment for Climate Change: Design Principles for Climate Emergencies analyzes several scenarios and proposes various adaptation strategies for climate emergencies (heat waves, wildfires, floods, and storms). Divided into three themes, the book offers an organized vision of a complex and multi-factor challenge. It covers climatic resilience and building refurbishment, implications for service life prediction and maintainability, and climate adaptation in the maintenance and management of buildings. Sections cover infrastructure materials, climate emergency adaptation and building adaptation to heat waves, wildfires, floods and storms. The book will be an essential reference resource for civil and structural engineers, architects, planners, designers and other professionals who have an interest in the adaptation of the built environment against climate change.

Smart Supercapacitors: Fundamentals, Structures and Applications presents current research and technology surrounding smart supercapacitors, also exploring their rapidly emerging characteristics and future potential advancements. The book begins by describing the basics and fundamentals related to supercapacitors and their applicability as smart and next generation energy storing devices. Subsequent sections discuss electrode materials, their fabrication, specific designing techniques, and a review of the application and commercialization of this technology. This book will appeal to researchers and engineers from both academia and industry, making it a vital resource to help them revolutionize modern supercapacitors.

Nanoelectronics: Physics, Materials and Devices addresses the concepts involved in the exploration of research on nanoscale electronics and photonic devices and their application in next-generation integrated circuits (ICs). The book presents a detailed discussion on the field of nanoscale electronic and photonic devices, as well as the most recent techniques for the modeling and simulation of these devices. It provides an in-depth analysis of theoretical frameworks, the fundamental physics underlying device operation, computational modeling, simulation methods, and circuit applications of nanoscale devices. The purpose of this book is to provide a desirable balance between basic background and concepts to improve device performance. In this book, both qualitative and quantitative approaches are considered to analyze and explore the contributions made by various researchers actively engaged in nanoscale device research. The book's main motivation is to help solve the challenges of analyzing and exploring the electrical behaviors of contemporary nanoscale device technologies. It purposefully builds the principles of nano electronic devices gradually, invigorating those of micro electronic devices.

Metal Chalcogenide Biosensors: Fundamentals and Applications provides an overview of advances in materials development of chalcogenides for use in biosensing and sensing applications. The metal chalcogenides discussed include highly reactive metals, noble metals and transition metals. Particular attention is given to the morphology, porosity, structure and fabrication of materials for biosensing applications. The connection between the chalcogenides' physical and chemical properties and device performance is explored. Key parameters for biosensor devices are investigated such as thermodynamics, kinetics, selectivity, sensitivity, efficiency and durability to aid in materials selection. Finally, a range of biosensor devices are addressed including gas biosensors, chemical biosensors, environment biosensors and biological molecule sensors. This book is suitable for those in the fields of materials science and engineering, chemistry and physics.

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. Other sections in the book cover topics related to the applications of green composites in areas such as antimicrobial agents, pathogen control, surgical applications, dentistry and cancer therapy.