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Bioinspired concepts are becoming increasingly integrated into materials and devices intended for medical applications. Biological organisms evolve within specific environmental constraints, giving rise to elegant and efficient strategies for fabricating materials that often outperform man-made materials of similar composition. A main goal of the interdisciplinary field of bioinspired materials is to unlock the secrets of this process--the composition, processing, self-assembly, hierarchical organization, and properties of biological materials--and use this information to synthesize and engineer novel functional materials for a variety of practical applications. The authors are from a variety of scientific disciplines, including biology, biochemistry, chemistry, physics, materials science, mechanical engineering, and bioengineering. This book will appeal to readers interested in the cross-disciplinary fertilization of new ideas in this emerging field. The second volume focuses on the bioinspired approaches using synthetic organic and inorganic materials, and on the fabrication using the materials for medical devices. Both volumes cover the interdisciplinary fields of biological, synthetic, and the hybrid materials and describe their medical applications ranging from molecular to cellular levels.
"This book provides insight on fabrication strategies for bioinspired materials as well as a collective review of their current and prospective applications by highlighting essential research on bioinspired processes and the nano-structural, physical, chemical, thermal, and mechanical aspects of biologically-inspired materials"--
Takes a materials science approach, correlating structure-property relationships with function across a broad range of biological materials.
This book provides an insight into the basic fundamentals of the biomaterials used for the biomedical applications, their development and processing techniques. Advanced materials are significantly utilized for the biomedical applications ranging from dental devices to cancer treatment owing to their higher biocompatibility and better interaction with tissues. This book covers the various topics that include basic biocompatibility phenomena, insight to materials science, class of different advanced materials as a biomaterials, development and processing techniques, design and analysis of the developed advanced materials, investigation of its properties and major applications. Recent information regarding the development techniques and methods for improving the properties of the advanced materials in the field of biomedical applications is highlighted in detail. The textbook offers clear explanation of the text in the chapters with self-explanatory figures and tables. It demonstrates the novel methods, opportunities and ideas for developing biomaterials in the field of biomedical applications. It also includes critical review study of the developed advanced materials for biomedical applications in a new summarized form. The inclusion of the discussions on hybrid polymer-based composites and self-healing composite materials offers a special feature in the textbook. It features a thorough overview of the simulation aspect in the biomedical applications. The book features at least 50% of its references from last three–four years’ work in the field of biomaterials and biomedical. The book content adds to the redundancy in the literature work related to biomedical and biomaterials. This book is a valuable resource for academicians, students and scholars from science and engineering background having interest in biomaterials. It is helpful to the biomedical engineering group especially in countries or location where they don’t have access to the major journals.
This book is the first 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. Topics addressed in this volume, which is devoted to bioinspired biomaterials, range from novel biomaterials for regenerative medicine through to emerging enabling technologies with applications in, for example, drug delivery, maternal–fetal medicine, peripheral nerve repair and regeneration, and brain tumor therapy. New bioinspired hydrogels receive detailed attention in the book, and a further focus is the use of bioinspired biomaterials in the regulation of stem cell fate. Here the coverage includes the role of scaffolds in cartilage regeneration, the bioapplication of inorganic nanomaterials in tissue engineering, and guidance of cell migration to improve tissue regeneration. 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 covers the latest bio-inspired materials synthesis techniques and biomedical applications that are advancing the field of tissue engineering. Bio-inspired concepts for biomedical engineering are at the forefront of tissue engineering and regenerative medicine. Scientists, engineers and physicians are working together to replicate the sophisticated hierarchical organization and adaptability found in nature and selected by evolution to recapitulate the cellular microenvironment. This book demonstrates the dramatic clinical breakthroughs that have been made in engineering all four of the major tissue types and modulating the immune system. Part I (Engineering Bio-inspired Material Microenvironments) covers Bio-inspired Presentation of Chemical Cues, Bio-inspired Presentation of Physical Cues, and Bio-inspired Integration of Natural Materials. Part II (Bio-inspired Tissue Engineering) addresses tissue engineering in epithelial tissue, muscle tissue, connective tissue, and the immune system.
Evolved in a huge number of different materials and structures, nature represents a great inspiration for scientists and researchers, which continuously focuses attention on the development of novel approaches and functional biomaterials to mimic the complex architectures and functions of the human body. Bioinspired engineering is considered today as a valuable tool for the design of clinically relevant materials and structures for regenerative sciences and, in this direction, many progresses have been recently made by the scientific research in the biomedical field. This book aims at collecting some recent works addressed to the definition of novel bioinspired approaches in bioengineering and biotechnology, presenting interesting scientific results and a comprehensive overview of attracting materials in research papers and review articles.
An authoritative introduction to the science and engineering of bioinspired materials Bioinspired Materials Science and Engineering offers a comprehensive view of the science and engineering of bioinspired materials and includes a discussion of biofabrication approaches and applications of bioinspired materials as they are fed back to nature in the guise of biomaterials. The authors also review some biological compounds and shows how they can be useful in the engineering of bioinspired materials. With contributions from noted experts in the field, this comprehensive resource considers biofabrication, biomacromolecules, and biomaterials. The authors illustrate the bioinspiration process from materials design and conception to application of bioinspired materials. In addition, the text presents the multidisciplinary aspect of the concept, and contains a typical example of how knowledge is acquired from nature, and how in turn this information contributes to biological sciences, with an accent on biomedical applications. This important resource: Offers an introduction to the science and engineering principles for the development of bioinspired materials Includes a summary of recent developments on biotemplated formation of inorganic materials using natural templates Illustrates the fabrication of 3D-tumor invasion models and their potential application in drug assessments Explores electroactive hydrogels based on natural polymers Contains information on turning mechanical properties of protein hydrogels for biomedical applications Written for chemists, biologists, physicists, and engineers, Bioinspired Materials Science and Engineering contains an indispensible resource for an understanding of bioinspired materials science and engineering.
This book highlights recent advances in the field of biomaterials design and the state of the art in biomaterials applications for biomedicine. Addressing key aspects of biomaterials, the book explores technological advances at multi-scale levels (macro, micro, and nano), which are used in applications related to cell and tissue regeneration. The book also discusses the future scope of bio-integrated systems. The contents are supplemented by illustrated examples, and schematics of molecular and cellular interactions with biomaterials/scaffolds are included to promote a better understanding of the complex biological mechanisms involved in material-to-biomolecule interactions. The book also covers factors that govern cell growth, differentiation, and regeneration in connection with the treatment and recovery of native biological systems. Tissue engineering, drug screening and delivery, and electrolyte complexes for biomedical applications are also covered in detail. This book offers a comprehensive reference guide for multi-disciplinary communities working in the area of biomaterials, and will benefit researchers and graduate students alike.
In recent years there have been tremendous advances in the fields of chemistry, physics and biology which have a direct impact on advances in biomaterials science. Many areas of healthcare depend upon the development of novel biomaterials. This book contains contribution from scientists who have made numerous innovative and exciting advances in the field of biomedical materials. The latest advances in the field are covered including studies of cell interactions with biomaterials. The assessment of the potential applications for the development of new biomaterials, tissue engineering and future medical devices are discussed. It will also provide an opportunity to discuss the latest developments in the field and the vision for the future. The book clearly illustrates how basic and applied research are being combined to produce novel biomaterials.