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The generation of tridimensional tissues, assembled from scaffolding materials populated with biologically functional cells, is the great challenge and hope of tissue bioengineering and regenerative medicine. The generation of biomaterials capable of harnessing the immune system has been particularly successful. This book provides a comprehensive view of how immune cells can be manipulated to suppresses inflammation, deliver vaccines, fight cancer cells, promote tissue regeneration or inhibit blood clotting and bacterial infections by functionally engineered biomaterials. However, long-lived polymers, such as those employed in orthopedic surgery or vascular stents, can often induce an immune reaction to their basic components. As a result, this book is also an important step towards coming to understand how to manipulate biomaterials to optimize their beneficial effects and downplay detrimental immune responses.
This book is the second of two volumes that together offer a comprehensive account of cutting-edge advances in the development of biomaterials for use within tissue engineering and regenerative medicine. In this volume, which is devoted to biomimetic biomaterials, the opening section discusses bone regeneration by means of duck’s feet-derived collagen scaffold and the use of decellularized extracellular matrices. The role of various novel biomimetic hydrogels in regenerative medicine is then considered in detail. The third section focuses on the control of stem cell fate by biomimetic biomaterials, covering exosome-integrated biomaterials for bone regeneration, cellular responses to materials for biomedical engineering, and the regulation of stem cell functions by micropatterned structures. Finally, the use of nano-intelligent biocomposites in regenerative medicine is addressed, with discussion of, for example, recent advances in biphasic calcium phosphate bioceramics and blood-contacting polymeric biomaterials. The authors are recognized experts in the interdisciplinary field of regenerative medicine and the book will be of value for all with an interest in regenerative medicine based on biomaterials.
This book provides a comprehensive overview of the cascade of events activated in the body following the implant of biomaterials and devices. It is one of the first books to shed light on the role of the host immune response on therapeutic efficacy, and reviews the state-of-the-art for both basic science and medical applications. The text examines advantages and disadvantages of the use of synthetic versus natural biomaterials. Particular emphasis is placed on the role of biomimicry in the development of smart strategies able to modulate infiltrating immune cells, thus reducing side effects (such as acute and chronic inflammation, fibrosis and/or implant rejection) and improving the therapeutic outcome (healing, tissue restoration). Current cutting-edge approaches in tissue engineering, regenerative medicine, and nanomedicine offer the latest insights into the role immunomodulation in improving tolerance during tissue transplant in the treatment of orthopaedic, pancreatic, and hepatic diseases. "Immune Response to Implanted Materials and Devices" is intended for an audience of graduate students and professional researchers in both academia and industry interested in the development of smart strategies, which are able to exploit the self-healing properties of the body and achieve functional tissue restoration.
The generation of tridimensional tissues, assembled from scaffolding materials populated with biologically functional cells, is the great challenge and hope of tissue bioengineering and regenerative medicine. The generation of biomaterials capable of harnessing the immune system has been particularly successful. This book provides a comprehensive view of how immune cells can be manipulated to suppresses inflammation, deliver vaccines, fight cancer cells, promote tissue regeneration or inhibit blood clotting and bacterial infections by functionally engineered biomaterials. However, long-lived polymers, such as those employed in orthopedic surgery or vascular stents, can often induce an immune reaction to their basic components. As a result, this book is also an important step towards coming to understand how to manipulate biomaterials to optimize their beneficial effects and downplay detrimental immune responses. Dr. Santambrogio is Professor of Pathology, Microbiology and Immunology and Orthopedic Surgery at the Albert Einstein College of Medicine. She received her M.D. from the University of Perugia and her Ph.D. from the University of Padua in Italy. She received her postdoctoral training at NYU and Harvard Medical School. One of the focuses of the research in her laboratory is the understanding of the immune responses to implanted biomaterials. .
This book serves as a good starting point for anyone interested in the application of tissue engineering. It offers a colorful mix of topics, which explain the obstacles and possible solutions for TE applications. The first part covers the use of adult stem cells and their applications. The following chapters offer an insight into the development of a tailored biomaterial for organ replacement and highlight the importance of cell-biomaterial interaction. In summary, this book offers insights into a wide variety of cells, biomaterials, interfaces and applications of the next generation biotechnology, which is tissue engineering.
Work in the area of biomaterials and stem cell therapy has revealed great potential for many applications, from the treatment of localized defects and diseases to the repair and replacement of whole organs. Researchers have also begun to develop a better understanding of the cellular environment needed for optimal tissue repair and regeneration. Biomaterials and Stem Cells in Regenerative Medicine explores a range of applications for biomaterials and stem cell therapy and describes recent research on suitable cell scaffolds and substrates for tissue repair and reconstruction. Featuring contributions by experts in the field, the book explores important scientific and clinical aspects. It covers the basic science involved in structure and properties, techniques and technological innovations in processing and characterization, and applications of biomaterials and stem cells. Topics include: Polymeric systems for stem cell delivery The potential of membranes and porous scaffolds in tissue repair, including myocardial, periodontal, ophthalmic, and bone tissues The optimization of the interaction between stem cells and biomaterial substrates The source and nature of stem cells for tissue engineering applications The clinical translation of stem cell–based tissue engineering for regenerative medicine From fundamental principles to recent advances at the macro, micro, nano, and molecular scales, the book brings together current knowledge on biomaterials and stem cells in the context of regenerative medicine. It also stimulates discussion about future research directions. This unique book offers a valuable benchmark for the current status of clinically relevant research and development in stem cells and regenerative medicine. It bridges the gaps in experimental approaches and understanding among the materials science and engineering, biological sciences, and biomedical science and engineering communities, making it a valuable reference for graduate students, researchers, and practitioners working in the multidisciplinary field of biomedical research.
The book Biomaterials in Regenerative Medicine is addressed to the engineers and mainly medical practitioners as well as scientists and PhD degree students. The book indicates the progress in research and in the implementation of the ever-new biomaterials for the application of the advanced types of prosthesis, implants, scaffolds and implant-scaffolds including personalised ones. The book presents a theoretical approach to the synergy of technical, biological and medical sciences concerning materials and technologies used for medical and dental implantable devices and on metallic biomaterials. The essential contents of the book are 16 case studies provided in each of the chapters, comprehensively describing the authors' accomplishments of numerous teams from different countries across the world in advanced research areas relating to the biomaterials applied in regenerative medicine and dentistry. The detailed information collected in the book, mainly deriving from own and original research and R
This book comprehensively explores the basic concepts and applications of biomaterials in tissue engineering and regenerative medicine. The book is divided into four sections; the first section deals with the basic concepts and different types of biomaterials used in tissue engineering. The second section discusses the functional requirements and types of materials that are used in developing state-of-the-art of scaffolds for tissue engineering applications. The third section presents the applications of biomaterials for hard and soft tissue engineering, as well as for specialized tissue engineering. The last section addresses the future prospects of nanobiomaterials, intelligent biomaterials, and 3D bioprinting biomaterials in tissue engineering and regenerative medicine. It also discusses various in vitro disease models for tissue bioengineering and regenerative medicine. As such, it offers a valuable resource for students, researchers, scientists, entrepreneurs, and medical/healthcare professionals.
This book presents a wide and interdisciplinary overview of the current state of the art in the development of biomimetic materials for tissue regeneration on the basis of relevant and high-impact clinical needs. It specifically emphasizes the regeneration of bone, cartilage, and osteochondral tissues as well as soft tissues such as nerves, heart,
Regeneration of tissues and organs remains one of the great challenges of clinical medicine, and physicians are constantly seeking better methods for tissue repair and replacement. Tissue engineering and regenerative medicine have been investigated for virtually every organ system in the human body, and progress is made possible by advances in materials science, polymer chemistry, and molecular biology. This book reviews the current status of biomaterials for regenerative medicine, and highlights advances in both basic science and clinical practice. The latest methods for regulating the biological and chemical composition of biomaterials are described, together with techniques for modulating mechanical properties of engineered constructs. Contributors delineate methods for guiding the host response to implantable materials, and explain the use of biologically-inspired materials for optimal biological functionality and compatibility. The book culminates in a discussion of the clinical applications of regenerative medicine. By integrating engineering and clinical medicine, Engineering Biomaterials for Regenerative Medicine examines how tissue engineering and regenerative medicine can be translated into successful therapies to bridge the gap between laboratory and clinic. The book will aid materials scientists and engineers in identifying research priorities to fulfill clinical needs, and will also enable physicians to understand novel biomaterials that are emerging in the clinic. This integrated approach also gives engineering students a sense of the excitement and relevance of materials science in the development of novel therapeutic strategies.