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This work provides the broad range of applications of inorganic compounds. Due to their well defined properties they play an important role in many fields either on a large scale in our daily life or as niche products. Experts from industry and academia present the vast amount of distinguished materials focusing on their synthesis and function. Volume 2 covers e.g. electronic, magnetic, biomedical, carbon- and sulfur-based materials and ceramics.
Many elements and inorganic compounds play an extraordinary role in daily life for numerous applications, e. g., construction materials, inorganic pigments, inorganic coatings, steel, glass, technical gases, energy storage and conversion materials, fertilizers, homogeneous and heterogeneous catalysts, photofunctional materials, semiconductors, superconductors, soft- and hard magnets, technical ceramics, hard materials, or biomedical and bioactive materials. The present book is written by experienced authors who give a comprehensive overview on the many chemical and physico-chemical aspects related to application of inorganic compounds and materials in order to introduce senior undergraduate and postgraduate students (chemists, physicists, materials scientists, engineers) into this broad field.
Many elements and inorganic compounds play an extraordinary role in daily life for numerous applications, e. g., construction materials, inorganic pigments, inorganic coatings, steel, glass, technical gases, energy storage and conversion materials, fertilizers, homogeneous and heterogeneous catalysts, photofunctional materials, semiconductors, superconductors, soft- and hard magnets, technical ceramics, hard materials, or biomedical and bioactive materials. The present book is written by experienced authors who give a comprehensive overview on the many chemical and physico-chemical aspects related to application of inorganic compounds and materials in order to introduce senior undergraduate and postgraduate students (chemists, physicists, materials scientists, engineers) into this broad field. Volume 3 presents electronic, magnetic, biomedical, carbon- and sulfur-based materials and ceramics. Vol. 1. From Construction Materials to Technical Gases. Vol. 2. From Energy Storage to Photofunctional Materials.
Materials for Biomedical Engineering: Bioactive Materials, Properties, and Applications introduces the reader to a broad range of the different types of bioactive materials used in biomedical engineering. All the main types of bioactive materials are discussed, with an emphasis placed on their synthesis, properties, performance, and potential for biomedical applications. Key chapters on modeling and surface modification and methods provide the step-by-step information needed by researchers. Important applications of bioactive materials, such as drug delivery, cancer therapy and clinical dentistry are also highlighted in detail. Final sections look at future perspectives for bioactive materials in biomedical engineering. Provides a knowledge of the range of bioactive materials available, enabling the reader to make optimal materials selection decisions Presents detailed information on current and proposed applications of the latest bioactive materials, thus empowering readers to design innovative products and processes Covers methods and provides the detailed guidance needed by researchers to replicate key procedures and contribute to further research and discovery in this important field
Many elements and inorganic compounds play an extraordinary role in daily life for numerous applications, e. g., construction materials, inorganic pigments, inorganic coatings, steel, glass, technical gases, energy storage and conversion materials, fertilizers, homogeneous and heterogeneous catalysts, photofunctional materials, semiconductors, superconductors, soft- and hard magnets, technical ceramics, hard materials, or biomedical and bioactive materials. The present book is written by experienced authors who give a comprehensive overview on the many chemical and physico-chemical aspects related to application of inorganic compounds and materials in order to introduce senior undergraduate and postgraduate students (chemists, physicists, materials scientists, engineers) into this broad field.
Biomaterials serve as synthetic or natural materials used to replace parts of living systems or to function contact with living tissue. Biomaterials are intended to interface with biological systems to evaluate, treat, augment or replace any tissue, organ or function of the body. A biomaterial is different from a biological material such as bone that is produced by a biological system. Artificial hips, vascular-stents, artificial pacemakers, and catheters are all made from different biomaterials and comprise different medical devices. This book presents new approaches to biomaterial development including multi-field bone remodelling, novel strategies for conferring antibacterial properties to bone cement, polyacrylonitrile-based biomaterials for enzyme immobilisation and functionalised magnetic nanoparticles for tissue engineering from around the globe.
Multiscale Cell-Biomaterials Interplay in Musculoskeletal Tissue Engineering and Regenerative Medicine addresses the key concepts involved in the interactions between cells and biomaterials in the musculoskeletal tissue engineering and regenerative medicine field. The updated developments and challenges of the mechanisms/mechanobiology and structure-function properties of those interactions, as well as emerging technologies underlying tissue-engineered scaffolding, are carefully discussed. Lastly, cell engineering and cell-based therapies, growth factors/drugs properties, vascularization, immunomodulation are also outlined. Given the large number of musculoskeletal disorders and related injuries that can affect muscles, bones and joints and lead to severe complications of the neuromuscular system, it is imperative to develop new treatment strategies to delay or repair associated diseases and to promote optimal long-term health. Presents the fundamentals of the complex interplay of cells with biomaterials in musculoskeletal tissue engineering Includes coverage of stem cells and cell-based therapies, in vitro and in vivo models, nanotechnology, bioprinting, computational modeling, regulatory and clinical translation, and much more Written by global leaders in the field
This book explores in depth a wide range of functional biomaterials-based systems for drug, gene delivery, and biomedical aspects. The chapters cover newer technologies such as polymeric micelle, pH-responsive biomaterials, stimuli-responsive hydrogels, silk fibroin, inorganic biomaterials, synthetic biomaterials, 3D printed biomaterials, metallic biomaterials, ceramic and hybrid biomaterials. It also describes the theranostic approaches for cancer therapy, the biomaterials-based nanofibers scaffolds in tissue engineering, as well as the strategies applications of metallic biomaterials for the medical and dental prosthetic field. This newer and updated approach will be attractive for biomedical engineering students working on materials science in the development of novel drug delivery strategies. The book will be an important reference for researchers and professionals working on biomaterial research in the pharmaceutical and medical fields.
Biomaterials research requires the union of materials scientists, engineers, biologists, biomedical doctors, and surgeons. Societal implications have invoked tremendous interest in this area of research in recent years. What started as a search for strong and durable implant materials has now led to path-breaking developments in tissue engineering,
Materials for Biomedical Engineering: Bioactive Materials for Antimicrobial, Anticancer, and Gene Therapy offers an up-to-date perspective on recent research findings regarding the application and use of these materials for disease treatment and prevention. Various types of currently investigated bioactive materials, including therapeutic nanostructures and antimicrobial hydrogels are discussed, as are their properties, impact and future role in therapeutic applications. The book will be extremely useful for new researchers who want to explore more information on the use of bioactive materials or for more experienced researchers who are interested in new trends and specific applications. Provides knowledge on the range of bioactive materials available, enabling the reader to make optimal materials selection decisions Contains detailed information on current and proposed applications of the latest bioactive materials to empower readers to design innovative products and processes Presents a strong emphasis on chemistry and the physico-chemical characterization of these materials and their application in antimicrobial, anticancer and gene therapy