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Biomedical foams are a new class of materials, which are increasingly being used for tissue engineering applications. Biomedical Foams for Tissue Engineering Applications provides a comprehensive review of this new class of materials, whose structure can be engineered to meet the requirements of nutrient trafficking and cell and tissue invasion, and to tune the degradation rate and mechanical stability on the specific tissue to be repaired. Part one explores the fundamentals, properties, and modification of biomedical foams, including the optimal design and manufacture of biomedical foam pore structure for tissue engineering applications, biodegradable biomedical foam scaffolds, tailoring the pore structure of foam scaffolds for nerve regeneration, and tailoring properties of polymeric biomedical foams. Chapters in part two focus on tissue engineering applications of biomedical foams, including the use of bioactive glass foams for tissue engineering applications, bioactive glass and glass-ceramic foam scaffolds for bone tissue restoration, composite biomedical foams for engineering bone tissue, injectable biomedical foams for bone regeneration, polylactic acid (PLA) biomedical foams for tissue engineering, porous hydrogel biomedical foam scaffolds for tissue repair, and titanium biomedical foams for osseointegration. Biomedical Foams for Tissue Engineering Applications is a technical resource for researchers and developers in the field of biomaterials, and academics and students of biomedical engineering and regenerative medicine. - Explores the fundamentals, properties, and modification of biomedical foams - Includes intense focus on tissue engineering applications of biomedical foams - A technical resource for researchers and developers in the field of biomaterials, and academics and students of biomedical engineering and regenerative medicine
Metallic Foam Bone: Processing, Modification and Characterization and Properties examines the use of porous metals as novel bone replacement materials. With a strong focus on materials science and clinical applications, the book also examines the modification of metals to ensure their biocompatibility and efficacy in vivo. Initial chapters discuss processing and production methods of metals for tissue engineering and biomedical applications that are followed by topics on practical applications in orthopedics and dentistry. Finally, the book addresses the surface science of metallic foam and how it can be tailored for medical applications. This book is a valuable resource for materials scientists, biomedical engineers, and clinicians with an interest in innovative biomaterials for orthopedic and bone restoration. - Introduces biomaterials researchers to a promising, rapidly developing technology for replacing hard tissue - Increases familiarity with a range of technologies, enabling materials scientists and engineers to improve the material properties of porous metals - Explores the clinical applications of metal foams in orthopedics and dentistry
In order to grow replacement tissues, 3D scaffolds are widely used as a template for tissue engineering and regeneration. These scaffolds, which are typically 'seeded' with cells, support the growth of new tissues. However, in order to achieve successful tissue growth, the scaffold must meet specific requirements and are often 'functionalized' to accentuate particular properties. Functional 3D tissue engineering scaffolds: materials, technologies, and applications, is a comprehensive review of functional 3D scaffolds, providing information on the fundamentals, technologies, and applications. Part 1 focuses on the fundamentals of 3D tissue scaffolds, examining information on materials, properties, and trends. Part 2 discusses a wide range of conventional technologies for engineering functional 3D scaffolds, leading the way to a discussion on CAD and advanced technologies for functional 3D scaffold engineering. Chapters in part 3 study methods for functionalizing scaffolds to support a variety of in vivo functions whilst the final set of chapters provides an important review of the most significant applications of functional 3D scaffolds within tissue engineering. This book is a valuable resource for biomaterial scientists and biomedical engineers in academia and industry, with interests in tissue engineering and regenerative medicine. - Provides a self-contained work for the field of biomaterials and tissue engineering - Discusses all the requirements a scaffold must meet and a wide range of strategies to create them - Highlights significant and successful applications of functional 3D scaffolds
This contributed volume reviews the latest advances on relevant 3D tissue engineered in vitro models of disease making use of biomaterials and microfluidics. The main focus of this book is on advanced biomaterials and microfluidics technologies that have been used in in vitro mimetic 3D models of human diseases and show great promise in revolutionizing personalized medicine. Readers will discover important topics involving biomaterials and microfluidics design, advanced processing techniques, and development and validation of organ- and body-on-a-chip models for bone, liver, and cancer research. An in depth discussion of microfabrication methods for microfluidics development is also provided. This work is edited by two truly multidisciplinary scientists and includes important contributions from well-known experts in their fields. The work is written for both early stage and experienced researchers, and well-established scientists enrolled in the fields of biomaterials, microfluidics, and tissue engineering, and is especially suited to those who wish to become acquainted with the principles and latest developments of in vitro models of diseases, such as professionals working in pharma, medicine, and engineering.
Polymeric foams are sturdy yet lightweight materials with applications across a variety of industries, from packaging to aerospace. As demand for these materials increase, so does innovation in the development of new processes and products. This book captures the most dynamic advances in processes, technologies, and products related to the polymeric foam market. It describes the latest business trends including new microcellular commercialization, sustainable foam products, and nanofoams. It also discusses novel processes, new and environmentally friendly blowing agents, and the development and usage of various types of foams, including bead and polycarbonate, polypropylene, polyetherimide microcellular, and nanocellular. The book also covers flame-retardant foams, rigid foam composites, and foam sandwich composites and details applications in structural engineering, electronics, and insulation. Authored by leading experts in the field, this book minimizes the gap between research and application in this important and growing area.
Polymeric foams or cellular or expanded polymers have characteristics that makes their usage possible for several industrial and household purposes. This book is focused on the recent advancements in the synthesis of polymer foams, various foaming methods, foaming technology, mechanical and physical properties, and the wide variety of its applications. Divided into 11 chapters, it explains empirical models connecting the geometrical structure of foams with their properties including structure-property relations. This book: Describes functional foams, their manufacturing methods, properties, and applications. Covers various blowing agents, greener methods for foaming, and their emerging applicability. Illustrates comparative information regarding polymeric foams and their recent developments with polymer nanocomposite foams. Includes applications in mechanical, civil, biomedical, food packaging, electronics, health care industry, and acoustics fields. Reviews elastomeric foams and their nanocomposite derivatives. This book is aimed at researchers and graduate students in materials science, mechanical engineering, and polymer science.
Bionanocomposites in Tissue Engineering and Regenerative Medicine explores novel uses of these in tissue engineering and regenerative medicine. This book offers an interdisplinary approach, combining chemical, biomedical engineering, materials science and pharmacological aspects of the characterization, synthesis and application of bionanocomposites. Chapters cover a broad selection of bionanocomposites including chitosan, alginate and more, which are utilized in tissue engineering, wound healing, bone repair, drug formulation, cancer therapy, drug delivery, cartilage regeneration and dental implants. Additional sections of Bionanocomposites in Tissue Engineering and Regenerative Medicine discuss, in detail, the safety aspects and circular economy of bionanocomposites - offering an insight into the commercial and industrial aspects of these important materials. Bionanocomposites in Tissue Engineering and Regenerative Medicine will prove a highly useful text for for those in the fields of biomedical engineering, chemistry, pharmaceutics and materials science, both in academia and industrial R&D groups. Each bionanocomposite type is covered individually, providing specific and detailed information for each material Covers a range of tissue engineering and regenerative medicine applications, from dental and bone engineering to cancer therapy Offers an integrated approach, with contributions from authors across a variety of related disciplines, including biomedical engineering, chemistry and materials science
Investigation on biobased nanomaterials has provided new insights into the rapidly advancing fields of the biomedical and environmental sciences by showing how these nanomaterials are effective in biomedicine and environmental remediation. These particles hold tremendous prospective applications, and are likely to become the next generation of particles in these areas. As such, research is ongoing and the data generated should have the potential for a sustainable future in both the environmental and biomedical fields. This book presents important findings on the role of and identification of novel applications of biobased nanomaterials. Unlike other books in this field, this book focuses entirely on sustainable application and remediation in biomedicine and environmental science. The chapters are written in such a way as to make them accessible to the reader, and furthermore, the volume can be readily adopted as a reference, or used as a guide for further research. This project was based on recent research (the last 5 years) and developed through an extensive literature search. The editors have also compiled some advanced, outstanding texts that should be of benefit to graduate students in their research.
The increased use of biodegradable synthetic or natural scaffolds combined with cells and/or biological molecules, in order to create functional replacement tissue in a damaged tissue site, has led to the need for the development of 'best practice' methods in the area of tissue engineering to help ensure the creation of safe, high quality products. Standardisation in cell and tissue engineering introduces concepts and current practice in the field of cell and tissue engineering to a wide audience and aims to provide awareness of the importance of standardisation in this area while suggesting directions for further investigation.Part one provides an overview of methods for cell and tissue engineering and includes chapters on the fundamentals of cell and matrix biology for tissue engineering, 3D collagen biomatrix development, and control and vascularisation of tissue-engineered constructs. Part two begins with a chapter exploring the methods and protocols of standardisation in cell and tissue engineering before moving on to highlight issues of quality control in cell and tissue engineering, standardised chemical analysis and testing of biomaterials and principles of good laboratory practice (GLP) for in vitro cell culture applications.Standardisation in cell and tissue engineering is a standard reference for leading research groups, government agencies, regulatory bodies, and researchers and technicians at all levels across the whole range of disciplines using cell culture within the pharmaceutical, biotechnology and biomedical industries. - Introduces concepts and current practice in the field of cell and tissue engineering - Highlights the importance of standardisation in cell and tissue engineering and suggests directions for further investigation - Explores methods and protocols of standardisation in cell and tissue engineering and issues of quality control in cell and tissue engineering
Tissue Engineering: Current Status and Challenges bridges the gap between biomedical scientists and clinical practitioners. The work reviews the history of tissue engineering, covers the basics required for the beginner, and inspires those in the field toward future research and application emerging in this fast-moving field. Written by global experts in the field for those studying and researching tissue engineering, the book reviews regenerative technologies, stem cell research and regeneration of organs. It then moves to soft tissue engineering (heart, vascular, muscle and 3D scaffolding and printing), hard tissue engineering (bone, dental myocardial and musculoskeletal) and translational avenues in the field. - Introduces readers to the history and benefits of tissue engineering - Includes coverage of new techniques and technologies, such as nanotechnology and nanoengineering - Presents concepts, ideology and theories which form the foundation for next-generation tissue engineering