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Micro- and Nanoengineering of the Cell Surface explores the direct engineering of cell surfaces, enabling materials scientists and chemists to manipulate or augment cell functions and phenotypes. The book is accessible for readers across industry, academia, and in clinical settings in multiple disciplines, including materials science, engineering, chemistry, biology, and medicine. Written by leaders in the field, it covers numerous cell surface engineering methods along with their current and potential applications in cell therapy, tissue engineering, biosensing, and diagnosis. The interface of chemistry, materials science, and biology presents many opportunities for developing innovative tools to diagnose and treat various diseases. However, cell surface engineering using chemistry and materials science approaches is a new and diverse field. This book provides a full coverage of the subject, introducing the fundamentals of cell membrane biology before exploring the key application areas. - Demystifies the direct engineering of cell surfaces, enabling materials scientists and chemists to manipulate or augment cell functions and phenotypes - Provides a toolkit of micro- and nanoengineering approaches to the manipulation of the cell surface - Unlocks the potential of cell surface manipulation for a range of new applications in the fields of in vitro research, cell therapy, tissue engineering, biosensing, and diagnostics
Supported with 140 illustrations, the volume exhaustively covers the micro- and nano-system technologies involved in developing cell-based bioengineering applications. You get full details on efforts to engineer the soluble and insoluble cell microenvironments, including the latest advances in microfluidic devices, surface patterning, 3D scaffolds, and techniques for engineering cellular mechanical properties and topography.
Fuel cells are clean and efficient energy conversion devices expected to be the next generation power source. During more than 17 decades of research and development, various types of fuel cells have been developed with a view to meet the different energy demands and application requirements. Scientists have devoted a great deal of time and effort
Nanoengineering in Musculoskeletal Regeneration provides the reader an updated summary of the therapeutic pipeline—from biomedical discovery to clinical implementation—aimed at improving treatments for patients with conditions of the muscles, tendons, cartilage, meniscus, and bone. Regenerative medicine focuses on using stem cell biology to advance medical therapies for devastating disorders. This text presents novel, significant, and interdisciplinary theoretical and experimental results related to nanoscience and nanotechnology in musculoskeletal regeneration. Content includes basic, translational, and clinical research addressing musculoskeletal repair and regeneration for the treatment of diseases and injuries of the skeleton and its associated tissues.Musculoskeletal degeneration and complications from injuries have become more prevalent as people live longer and increasingly participate in rigorous athletic and recreational activities. Additionally, defects in skeletal tissues may immobilize people and cause inflammation and pain. Musculoskeletal regeneration research provides solutions to repair, restore, or replace skeletal elements and associated tissues that are affected by acute injury, chronic degeneration, genetic dysfunction, and cancer-related defects. The goal of musculoskeletal regeneration medicine research is to improve quality of life and outcomes for people with musculoskeletal injury or degradation. - Provides broad coverage in all research areas focused on the applications of nanotechnology in musculoskeletal regeneration - Offers useful guidance for physician-scientists with expertise in orthopedics, regenerative medicine, bioengineering, biomaterials, nanoengineering, stem cell biology, and chemistry - Serves as a practical reference for many disciplines, including bioengineering, biomaterials, tissue engineering, regenerative medicine, musculoskeletal regenerative medicine, and nanomedicine
Principles of Biomaterials Encapsulation: Volume One, provides an expansive and in-depth resource covering the key principles, biomaterials, strategies and techniques for encapsulation. Volume One begins with an introduction to encapsulation, with subsequent chapters dedicated to a broad range of encapsulation principles and techniques, including spray chilling and cooling, microemulsion, polymerization, extrusion, cell microencapsulation and much more. This book methodically details each technique, assessing the advantages and disadvantages of each, allowing the reader to make an informed decision when using encapsulation in their research. Principles of Biomaterials Encapsulation: Volume One enables readers to learn about the various strategies and techniques available for encapsulation of a wide selection of biomedical substrates, such as drugs, cells, hormones, growth factors and so on. 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. As such, this book will provide a useful resource to a broad readership, including those working in the fields of materials science, biomedical engineering, regenerative and translational medicine, pharmacology, chemical engineering and nutritional science. - Details the various biomaterials available for encapsulation, as well as 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
The Handbook of Silicon Based MEMS Materials and Technologies, Second Edition, is a comprehensive guide to MEMS materials, technologies, and manufacturing that examines the state-of-the-art with a particular emphasis on silicon as the most important starting material used in MEMS. The book explains the fundamentals, properties (mechanical, electrostatic, optical, etc.), materials selection, preparation, manufacturing, processing, system integration, measurement, and materials characterization techniques, sensors, and multi-scale modeling methods of MEMS structures, silicon crystals, and wafers, also covering micromachining technologies in MEMS and encapsulation of MEMS components. Furthermore, it provides vital packaging technologies and process knowledge for silicon direct bonding, anodic bonding, glass frit bonding, and related techniques, shows how to protect devices from the environment, and provides tactics to decrease package size for a dramatic reduction in costs. - Provides vital packaging technologies and process knowledge for silicon direct bonding, anodic bonding, glass frit bonding, and related techniques - Shows how to protect devices from the environment and decrease package size for a dramatic reduction in packaging costs - Discusses properties, preparation, and growth of silicon crystals and wafers - Explains the many properties (mechanical, electrostatic, optical, etc.), manufacturing, processing, measuring (including focused beam techniques), and multiscale modeling methods of MEMS structures - Geared towards practical applications rather than theory
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
The book outlines first the importance of Extra Cellular Matrix (ECM), which is a natural surface for most of cells. In the following chapters the influence of biological, chemical, mechanical, and physical properties of surfaces in micro and nano-scale on stem cell behavior are discussed including the mechanotransduction. Biomimetic and bioinspired approaches are highlighted for developing microenvironment of several tissues, and surface engineering applications are discussed in tissue engineering, regenerative medicine and different type of biomaterials in various chapters of the book. This book brings together innovative methodologies and strategies adopted in the research and development of Advanced Surfaces in Stem Cell Research. Well-known worldwide researchers deliberate subjects including: Extracellular matrix proteins for stem cell fate The superficial mechanical and physical properties of matrix microenvironment as stem cell fate regulator Effects of mechanotransduction on stem cell behavior Modulation of stem cells behavior through bioactive surfaces Influence of controlled micro and nanoengineered surfaces on stem cell fate Nanostructured polymeric surfaces for stem cells Laser surface modification techniques and stem cells applications Plasma polymer deposition: a versatile tool for stem cell research Application of bioreactor concept and modeling techniques in bone regeneration and augmentation treatments Substrates and surfaces for control of pluripotent stem cell fate and function Application of biopolymer-based, surface modified devices in transplant medicine and tissue engineering Silk as a natural biopolymer for tissue engineering
This text book will bring together a mix of both internationally known and established senior scientists along side up and coming (but already accomplished) junior scientists that have varying expertise in fundamental and applied nanotechnology to biology and medicine.
This volume collects selected papers presented and discussed during the 9th National Conference organized by the Italian Association of Materials Engineering, AIMAT from 2008 at Piano di Sorrento (Napoli, Italy). It gives a valuable representation of highlights of the research and development activities running in 21 Italian universities and resear