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Handbook of Tissue Engineering Scaffolds: Volume Two provides a comprehensive and authoritative review on recent advancements in the application and use of composite scaffolds in tissue engineering. Chapters focus on specific tissue/organ (mostly on the structure and anatomy), the materials used for treatment, natural composite scaffolds, synthetic composite scaffolds, fabrication techniques, innovative materials and approaches for scaffolds preparation, host response to the scaffolds, challenges and future perspectives, and more. Bringing all the information together in one major reference, the authors systematically review and summarize recent research findings, thus providing an in-depth understanding of scaffold use in different body systems. - Dedicated to the specialist topic of composite scaffolds, featuring all human body systems - Covers basic fundamentals and advanced clinical applications - Includes up-to-date information on preparation methodology and characterization techniques - Highlights clinical data and case studies
Handbook of Tissue Engineering Scaffolds: Volume One, provides a comprehensive and authoritative review on recent advancements in the application and use of composite scaffolds in tissue engineering. Chapters focus on specific tissue/organ (mostly on the structure and anatomy), the materials used for treatment, natural composite scaffolds, synthetic composite scaffolds, fabrication techniques, innovative materials and approaches for scaffolds preparation, host response to the scaffolds, challenges and future perspectives, and more. Bringing all the information together in one major reference, the authors systematically review and summarize recent research findings, thus providing an in-depth understanding of scaffold use in different body systems. - Dedicated to the specialist topic of composite scaffolds, featuring all human body systems - Covers basic fundamentals and advanced clinical applications - Includes up-to-date information on preparation methodology and characterization techniques - Highlights clinical data and case studies
Principles of Biomaterials Encapsulation: Volume Two provides an expansive and in-depth resource covering the key principles, biomaterials, techniques and applications of encapsulation in translational medicine. The book details the various biomaterials available for encapsulation, including polymers, natural and synthetic biomaterials, porous materials, and more. The advantages and disadvantages of conventional and contemporary biomaterials for encapsulations are reviewed, along with advice on the most effective materials for both shell and core. The final part of the book describes a broad range of applications in regenerative medicine, uniquely bringing encapsulation into the worlds of translational medicine and tissue engineering. This book enables readers to learn about the pros and cons of different biomaterials for encapsulation, as well as how they can be utilized in many bodily systems and tissues, such as the respiratory, digestive, endocrine and cardiovascular systems. Written and edited by well-versed materials scientists with extensive clinical, biomedical and regenerative medicine experience, this book offers a deeply interdisciplinary look at encapsulation in translational medicine. - Details the various biomaterials available for encapsulation, as well as the advantages and disadvantages of conventional and contemporary biomaterials for encapsulations - Describes a broad range of applications in regenerative medicine, uniquely bringing encapsulation into the worlds of translational medicine and tissue engineering - Written and edited by well-versed materials scientists with extensive clinical, biomedical and regenerative medicine experience, offering an interdisciplinary approach
Handbook of Nanomaterials: Biomedicine, Environment, Food, and Agriculture offers a comprehensive resource that introduces the role of nanotechnology and nanomaterials in a broad range of areas, covering fundamentals, methods, and applications.In this volume, dedicated sections focus on key applications across biomedicine, environmental remediation, food, agriculture, and other areas. In each chapter, detailed but concise information is provided on a specific application, and other key state-of-the-art technologies such as biomimetic nanotechnology and nanotechnology in 3D printing are included. In the final part of the book, there is in-depth coverage of environmental and regulatory issues relating to nanotechnology.This book is of interest to researchers and advanced students approaching nanotechnology from a range of disciplines, including materials science and engineering, chemistry, chemical engineering, electronics, energy, biomedicine, environmental science, food science, and agriculture, as well as scientists, engineers, and R&D professionals with an interest in the use of nanomaterials across a range of industries. - Introduces the reader to key applications of nanomaterials - Provides broad, systematic, concise coverage, supporting readers from a range of disciplines - Covers applications across biomedicine, environmental remediation, food, agriculture, and more
Written by a group of world-renowned experts, the second volume in this groundbreaking set continues where the first volume left off, focusing on fermentation products that contribute to human welfare across a variety of industries. Green technologies are no longer the "future" of science, but the present. With more and more mature industries, such as the process industries, making large strides seemingly every single day, and more consumers demanding products created from green technologies, it is essential for any business in any industry to be familiar with the latest processes and technologies. It is all part of a global effort to "go greener," and this is nowhere more apparent than in fermentation technology. This second volume in the groundbreaking new set, High Value Fermentation Products, focuses on industries that a concerned with human welfare, including the leather industry, textiles, pharmaceutical and medical, food processing, and others. Covering topics such as chitin and chitosan, microbial polyhydroxyalkanoates, propanediol, and many others, the editors and contributors have contributed to an extremely important facet of chemical and process engineering and how to move these industries into a much more sustainable and environmentally conscious direction. From converting waste into apparel to creating healthier foods and more effective medicines, this is truly a monumental work that is a must-have for any chemical engineer, scientist, or chemist.
Microfluidics for Cellular Applications describes microfluidic devices for cell screening from a physical, technological and applications point-of-view, presenting a comparison with the cell microenvironment and conventional instruments used in medicine. Microfluidic technologies, protocols, devices for cell screening and treatment have reached an advanced state but are mainly used in research. Sections break them down into practical applications and conventional medical procedures and offers insights and analysis on how higher resolutions and fast operations can be reached. This is an important resource for those from an engineering and technology background who want to understand more and gain additional insights on cell screening processes. - Outlines the major applications of microfluidic devices in medicine and biotechnology - Assesses the major challenges of using microfluidic devices in terms of complexity of the control set-up, ease of use, integration capability, automation level, analysis throughput, content and costs - Describes the major fabrication techniques for assembling effective microfluidic devices for bioapplications
Fused Deposition Modeling of Composite Materials is dedicated to the field of 3D-printing of composite materials using a popular technique called Fused Deposition Modeling (FDM), the world's most popular 3D printing method. But this method is currently limited to printing basic polymers and only a handful of primitive composite materials. Many future industries, such as Space, Biomed, Construction and Defense are waiting for the ability to 3D print composites and new functional materials with complex shapes and features so they can add unique and customizable features to their parts, including biocompatibility, radiation shielding, high-strength, rapid cooling, flexibility and shape-memory. The book's authors take the reader through the basics of what the FDM technique is all about and describe the advantages and new opportunities arising from 3D printing innovative materials, which include polymer-matrix composites and fully inorganic parts. They then review and discuss methods for making the different types of composite feedstock filaments needed to 3D print such materials by FDM. Finally, sections discuss the challenges that should be considered in making filaments and parts and how to go about solving them. - Covers the 3D printing of composite materials - Includes comprehensive coverage of this new and emerging technology - Written in a clear, practical and informative style, with numerous illustrations - Contains case study examples taken from cutting-edge scientific literature
Bone augmentation is a procedure to replace and repair fractured bone in extreme circumstances. The materials used in such grafting techniques must be biocompatible and might come from natural bone sources or synthetic materials. This book defines bone augmentation and describes different bone grafting materials, techniques, and applications. Recently developed materials are also explored.
Biomedical Applications of Electrospinning and Electrospraying describes the principles and laboratory set up for electrospinning and electrospraying, addressing a range of biomedical applications. Sections cover novel combinational approaches, such as electrospinning/spraying and 3D printing. Electrospinning has evolved from being a technique to prepare random networks of textile fibers to a technique to fabricate highly ordered patterns of biomedical materials of defined scale. The technological advancements in recent years with regard to the way the jet is facilitated, how the jet path is controlled, and how the fibers are collected have provided invaluable insights into controlled fabrication of a material of choice. Additionally, the electrospray technique has also evolved from being a technique to prepare food formulations to a technique to prepare cell encapsulated beads for transplantation in clinics. Several innovations in this line, such as those leading to core-shell materials have tremendously changed the way the technique is used. Thus, a combinational approach using electrospinning, electrospraying and 3D printing has emerged. - Introduces electrospinning and electrospraying concepts and describes state-of-the-art methodologies - Provides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applications - Presents details of instrumentation involved, along with novel devices for bench to bedside translation, - Covers novel combinational approaches using electrospinning, electrospraying and 3D printingIntroduces electrospinning and electrospraying concepts and describes state-of-the-art methodologies - Provides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applications - Presents details of instrumentation involved, along with novel devices for bench to bedside translation - Covers novel combinational approaches using electrospinning, electrospraying and 3D printing
Millions of patients suffer from end-stage organ failure or tissue loss annually, and the only solution might be organ and/or tissue transplantation. To avoid poor biocompatibility–related problems and donor organ shortage, however, around 20 years ago a new, hybridized method combining cells and biomaterials was introduced as an alternative to whole-organ and tissue transplantation for diseased, failing, or malfunctioning organs—regenerative medicine and tissue engineering. This handbook focuses on all aspects of intelligent scaffolds, from basic science to industry to clinical applications. Its 10 parts, illustrated throughout with excellent figures, cover stem cell engineering research, drug delivery systems, nanomaterials and nanodevices, and novel and natural biomaterials. The book can be used by advanced undergraduate- and graduate-level students of stem cell and tissue engineering and researchers in macromolecular science, ceramics, metals for biomaterials, nanotechnology, chemistry, biology, and medicine, especially those interested in tissue engineering, stem cell engineering, and regenerative medicine.