Polymers in Modern Medicine – Part 2 examines the innovative use of polymers in advanced healthcare applications, focusing on personalized medicine, regenerative therapies, and diagnostics. The book highlights groundbreaking topics such as polymer-based nanomedicine for cancer therapy, polymeric hydrogels, biopolymers, and the role of polymers in diagnostics and vaccines. Building on foundational principles, it explores polymeric approaches to sustainable and patient-specific treatments. Readers will gain a deep understanding of emerging polymer technologies and biocompatible materials and their impact on cutting-edge medical solutions. This resource bridges the gap between scientific research and practical implementation in the pharmaceutical, biomaterial, and medical device industries. Key Features: - Covers polymers in regenerative medicine, nanomedicine, and diagnostics. - Insights into polymeric hydrogels, biopolymers, and smart polymers. - Sustainability and patient-specific applications in healthcare.

Polymers in Modern Medicine – Part 1 offers an in-depth exploration of the transformative role of polymers in healthcare and medical innovation. This comprehensive book examines the diverse applications of polymeric materials in areas such as controlled drug delivery, tissue engineering, diagnostics, regenerative medicine, and personalized therapies. With chapters spanning polymeric scaffolds, nanotechnology, smart polymers, biopolymers, and polymer-based implants, it provides detailed insights into the science and technology shaping modern medicine. The book also highlights cutting-edge advancements in polymeric coatings for medical devices, cancer nanomedicine, and vaccine development, emphasizing sustainability and biocompatibility. Key Features: - Latest advancements in polymer nanotechnology, scaffolds, hydrogels, and smart polymers. - Applications in drug delivery, prosthetics, diagnostics, and regenerative medicine. - Discusses biocompatible, sustainable, and personalized polymeric materials. - Bridges the gap between academia, industry, and clinical research.

Bioceramics: Status in Tissue Engineering and Regenerative Medicine (Part 2) presents recent advancements in biocompatible ceramics and bioactive glasses, emphasizing their expanding applications in hard and soft tissue engineering. This book explores innovative manufacturing techniques like 3D printing and additive manufacturing and examines the therapeutic potential of bioceramics in areas such as bone regeneration, microbial infection management, wound healing, and cancer treatment. It also discusses current challenges, clinical applications, and future research directions. This book is a valuable resource for those developing biocompatible materials for medical applications. Key Features: - Comprehensive overview of bioceramic and bioactive glass applications in tissue engineering. - In-depth analysis of manufacturing techniques, including 3D printing and additive manufacturing. - Insights into clinical challenges, preclinical assessments, and future perspectives in regenerative medicine.

Bioceramics: Status in Tissue Engineering and Regenerative Medicine (Part 1) provides an in-depth look into the recent advancements in biocompatible ceramics, glasses, and composites for tissue engineering and regenerative medicine. It explores topics ranging from the structure and processing of bioactive glasses to the applications of bioinert and bioresorbable ceramics in medical treatments. The book discusses key aspects of bioceramics, including their therapeutic potential in soft tissue healing and cancer therapy, along with challenges and opportunities for future research. Researchers, bioengineers, and professionals in biomedical sciences will find this volume an essential resource for understanding both the fundamentals and applications of bioceramics. Key Features: - Comprehensive coverage of bioceramics, bioactive glasses, and composites, including their manufacturing techniques. - State-of-the-art insights into bioceramics and glass-ceramics in tissue engineering and regenerative medicine. - Focus on preclinical assessment, clinical applications, challenges, and future perspectives.

Applications of Nanoparticles in Drug Delivery and Therapeutics is an authoritative review on nanoparticle-based drug delivery systems. This comprehensive volume focuses on the transformative role of nanoparticles in enhancing drug delivery systems and advancing therapeutic applications. By bridging the gap between laboratory research and clinical practice, this book offers a thorough exploration of how nanotechnology is revolutionizing the pharmaceutical industry. The book is structured into well-organized chapters, each dedicated to a specific aspect of nanoparticle-based drug delivery and therapy. Initial chapters provide a foundational understanding of nanoparticle synthesis, characterization, and functionalization. Subsequent sections cover various types of nanoparticles, including liposomes, dendrimers, and polymeric nanoparticles, highlighting their unique properties and applications. The latter chapters delve into case studies and clinical trials, showcasing real-world applications and the therapeutic potential of nanoparticle technologies in treating diseases like cancer, cardiovascular disorders, and neurodegenerative diseases. Key features of this book include detailed discussions on the design and optimization of nanoparticles for targeted drug delivery, insights into the regulatory and safety aspects of nanomedicine, and comprehensive reviews of current and emerging therapeutic applications. The book also offers practical guidance on the challenges and future directions in the field, making it an invaluable reference for researchers and practitioners alike. Chapters 1 and 2 are based on the introduction of nanomaterials used as drug delivery systems, their manufacturing approaches and applications. Chapters 3 and 4 emphasize on the use of nanoparticles in medical diagnostics and in intervention devices. Chapters 5 and 6 illustrate the use of lipids-based nanoparticles in medical imaging and drug delivery. Chapter 7 specifically discusses amino acid functionalized inorganic nanoparticles in diagnostics. Chapter 8 is focused on the special class of nanoparticles “hybrid nanocomposites”. Chapters 9 and 10 covers the applications of silica and fullerene nanomaterials in anticancer drug delivery. The book is intended as a resource for pharmaceutical scientists, biomedical researchers, and healthcare professionals keen on the latest advancements in drug delivery systems. It also serves as essential reading for graduate students and academics in pharmacology and medical courses that require learning about modern drug delivery systems.

2D Materials: Chemistry and Applications, Part 2 addresses the cutting-edge advancements in the synthesis, functionalization, and applications of two-dimensional materials, focusing on graphene and other emerging materials like boron nitride, germanene, silicene, and stanene. This volume explores the potential of these materials in energy storage, nanoelectronics, waste management, and more, while addressing challenges like toxicity and cost-effective production. The book highlights innovative approaches to graphene-based supercapacitors, nanoparticle-functionalized graphene, and the application of 2D materials in diverse fields. It also provides insights into the toxicity and remediation strategies of graphene family materials and outlines the roadmap for sustainable graphene production. This book is ideal for researchers, academics, and professionals in materials science, nanotechnology, chemistry, and environmental engineering. Key Features: Advanced applications of graphene-based supercapacitors. Functionalization and applications of boron nitride, germanene, silicene, and stanene. Insights into graphene toxicity and remediation approaches. Roadmap for cost-effective graphene production and waste management.

Nanotechnology: A Quick Guide to Materials and Technologies invites readers to explore the cutting-edge world of nanotechnology, offering a comprehensive yet accessible introduction to this rapidly evolving field. The content provides a foundation for understanding the field and details the properties of significant nanomaterials. Readers will also gain insights into innovative processes while receiving a balanced perspective on the social and regulatory aspects of nanotechnology. Key Features: Foundational Knowledge: Begins with an overview of nanotechnology, its history, and its key concepts, Diverse Nanomaterials: Explores various types of nanomaterials, including nanoparticles, nanowires, and carbon-based materials like graphene, detailing their properties and potential applications. Advanced Applications: Explores the real-world uses of nanotechnology across multiple sectors, such as medicine, electronics, energy, and environmental science, demonstrating its transformative impact. Fabrication and Characterization: Covers techniques for creating and analyzing nanomaterials, offering insights into the processes that drive innovation in the field. Ethical and Societal Considerations: Discusses the broader implications of nanotechnology, including ethical, societal, and regulatory aspects Ideal for students, educators, researchers, and industry professionals, this guide serves as an informative resource for anyone looking to deepen their understanding of nanotechnology.

2D Materials: Chemistry and Applications offers a concise exploration of the revolutionary 2D materials synthesis, their properties, and diverse applications. It presents information about graphene and other 2D materials like germanene and stanene, emphasizing their synthesis, functionalization, and technological use. The book chapters in part 1 cover the foundational aspects of graphene' structure and production techniques, highlighting their potential in areas like energy storage, drug delivery, and nanoelectronics. The book also explains the versatile applications of graphene-based nanocomposites, highlighting their multifunctional capabilities. Chapters also demonstrate the impact of functionalization on applications like biomedical imaging, microbial control, and environmental sustainability. The challenges and solutions concerning the toxicity of graphene-related materials are also highlighted. This book is a foundational resource for researchers, academics, and industry professionals in materials science, nanotechnology, chemistry, and environmental engineering on 2D materials.

Recent Advancements in Multidimensional Applications of Nanotechnology provides a comprehensive overview of the latest advancements and applications of nanotechnology across various dimensions. Covering a wide range of topics, from electron microscopy to nanotherapeutic strategies, the book explores the diverse applications of nanotechnology in industries and research fields. Key Features: Comprehensive Coverage: Gain insights into electron microscopy, biogenic synthesis methods, energy applications, and more. Industry Applications: Discover how nanotechnology is revolutionizing industries such as energy, oil and gas, agriculture, and healthcare. Cutting-Edge Developments: Stay ahead of the curve with discussions on copper oxide nanoparticles, nano-coatings, and thin film optimization for solar cells. Biomedical Breakthroughs: Explore the exciting realm of biomedical applications, from metallic nanoparticles in healthcare to biogenic synthesis methods. Practical Insights: Benefit from practical insights and case studies that showcase real-world applications of nanotechnology.

This comprehensive book explores the techniques, materials, and real-world applications of thermal spray coatings across various industries, including power generation, aerospace, medical, and automotive sectors. Readers will learn about the basic science and engineering aspects of thermal spray technology, its historical developments, and the diverse range of materials used, from metallic to ceramic materials, and nano-crystallization materials. Distinct thermal spray techniques are explained (flame spray, detonation-gun spray, high-velocity oxy-fuel spray, electric arc spray, plasma spray and cold spray). Chapters on advanced topics also give an understanding of crucial material properties such as high temperature corrosion, oxidation, erosion or wear resistance, and biocompatibility. Key features - Contributions from materials science experts with references for each topic - Gives a comprehensive overview of materials and distinct spray techniques used in thermal coatings - Dedicated chapters for applications of thermal coatings in different industries - Covers recent trends and new advances such as surface modification techniques to improve functionality and performance This book is intended as a resource for an in-depth understanding of the fundamentals and applications of thermal spray coatings for students, professionals and researchers in materials science and chemical engineering disciplines.