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This wide-ranging summary of bioelectronics provides the state of the art in electronics integrated and interfaced with biological systems in one single book. It is a perfect reference for those involved in developing future distributed diagnostic devices, from smart bio-phones that will monitor our health status to new electronic devices serving our bodies and embedded in our clothes or under our skin. All chapters are written by pioneers and authorities in the key branches of bioelectronics and provide examples of real-word applications and step-by-step design details. Through expert guidance, you will learn how to design complex circuits whilst cutting design time and cost and avoiding mistakes, misunderstandings, and pitfalls. An exhaustive set of recently developed devices is also covered, providing the implementation details and inspiration for innovating new solutions and devices. This all-inclusive reference is ideal for researchers in electronics, bio/nanotechnology, and applied physics, as well as circuit and system-level designers in industry.
Here is the first introduction to the fast-growing field of bioelectronics - the comparative study phenomena and mechanisms in biology and electronics. This unique handbook deals with the design of neural networks and biosensors, explaining the analogies and differences between microelectronic technologies and natural systems as it covers everything from basic bioelectronic concepts, to the development of neural chips, to the building of biosensors and neural networks.
Medicine, chemistry, physics and engineering stand poised to benefit within the next few years from the ingenuity of complex biological structures invented and perfected by nature over millions of years. This book provides both researchers and engineers as well as students of all the natural sciences a vivid insight into the world of bioelectronics and nature's own nanotechnological treasure chamber.
Bioelectronics is a rich field of research involving the application of electronics engineering principles to biology, medicine, and the health sciences. With its interdisciplinary nature, bioelectronics spans state-of-the-art research at the interface between the life sciences, engineering and physical sciences. Introductory Bioelectronics offers a concise overview of the field and teaches the fundamentals of biochemical, biophysical, electrical, and physiological concepts relevant to bioelectronics. It is the first book to bring together these various topics, and to explain the basic theory and practical applications at an introductory level. The authors describe and contextualise the science by examining recent research and commercial applications. They also cover the design methods and forms of instrumentation that are required in the application of bioelectronics technology. The result is a unique book with the following key features: an interdisciplinary approach, which develops theory through practical examples and clinical applications, and delivers the necessary biological knowledge from an electronic engineer’s perspective a problem section in each chapter that readers can use for self-assessment, with model answers given at the end of the book along with references to key scientific publications discussions of new developments in the bioelectronics and biosensors fields, such as microfluidic devices and nanotechnology Supplying the tools to succeed, this text is the best resource for engineering and physical sciences students in bioelectronics, biomedical engineering and micro/nano-engineering. Not only that, it is also a resource for researchers without formal training in biology, who are entering PhD programmes or working on industrial projects in these areas.
This book reviews the rapidly emerging field of switchable interfaces and its implications for bioelectronics. The authors piece together early breakthroughs and key developments and highlight the future of switchable bioelectronics by focusing on bioelectrochemical processes based on mimicking and controlling biological environments with external stimuli as well as responsive systems for drug delivery. All chapters in the book strive to answer the fundamental question: How do living systems probe and respond to their surroundings? Following on from that, how can one transform these concepts to serve the practical world of bioelectronics? The central obstacle to this vision is the absence of versatile interfaces that are able to control and regulate the means of communication between biological and electronic systems. This book summarizes the overall progress made to date in building such interfaces at the level of individual biomolecules and focuses on the latest efforts to generate device platforms that integrate biointerfaces with electronics. Chapter 1 introduces the general concept of dynamic interfaces for bioelectronics and gives an overview of the importance of materials and systems for switchable bioelectronics, introducing the reader to different biointerfaces. Chapter 2 pieces together different types of stimuli-responsive polymers and applications. Chapter 3 lays special emphasis on stimuli-responsive polymers with tunable release kinetics and describes the importance of polymer design for delivery applications. Chapter 4 reviews the field of conformational switching in nanofibers for gas-sensing applications. Finally, Chapter 5 focuses on molecular imprinting polymers as recognition elements for sensing applications. As informative as it is lucid, this handbook makes an essential resource for advanced undergraduate- and graduate-level students in chemistry, as well as researchers in polymer science and electrochemistry, especially those with an interest in responsive polymers and biosensors.
"The book will give an overview of the emerging field of bioelectronics, focusing on fundamental principles. It aims to provide the motivation of the field with a focus on the most explored applications. It will provide the current understanding of the needs of a bioelectronics interface, device operation and design, and the monitoring, control, and enhancement of biological processes through the use of bioelectronic devices. The book will have a pedagogical character, to be used as a handbook for a course on bioelectronics or biomedical engineering. It can also fit into the curriculum of courses on biosensors, drug deliver, applied neuroscience, etc"--
This new volume provides an abundance of information on new biomedical applications being used today. The book covers a wide range of concepts and technologies, discussing such modern technological methods as the Internet of Things, e-pills, biomedical sensors, support vector machines, wireless devices, image and signal processing in e-health, and machine learning. It also includes a discussion on software implementation for the devices used in biomedical applications. The different types of antennas, including antennas using RF energy harvesting for biomedical applications, are covered as well.
This book addresses the fundamental challenges underlying bioelectronics and tissue interface for clinical investigation. Appropriate for biomedical engineers and researchers, the authors cover topics ranging from retinal implants to restore vision, implantable circuits for neural implants, and intravascular electrochemical impedance to detect unstable plaques. In addition to these chapters, the authors also document the approaches and issues of multi-scale physiological assessment and monitoring in both humans and animal models for health monitoring and biological investigations; novel biomaterials such as conductive and biodegradable polymers to be used in biomedical devices; and the optimization of wireless power transfer via inductive coupling for batteryless and wireless implantable medical devices. In addition to engineers and researchers, this book is also an ideal supplementary or reference book for a number of courses in biomedical engineering programs, such as bioinstrumentation, MEMS/BioMEMS, bioelectronics and sensors, and more. Analyzes and discusses the electrode-tissue interfaces for optimization of biomedical devices. Introduces novel biomaterials to be used in next-generation biomedical devices. Discusses high-frequency transducers for biomedical applications.
This book reviews the rapidly emerging field of switchable interfaces and its implications for bioelectronics. The authors piece together early breakthroughs and key developments and highlight the future of switchable bioelectronics by focusing on bioelectrochemical processes based on mimicking and controlling biological environments with external stimuli as well as responsive systems for drug delivery. All chapters in the book strive to answer the fundamental question: How do living systems probe and respond to their surroundings? Following on from that, how can one transform these concepts to serve the practical world of bioelectronics? The central obstacle to this vision is the absence of versatile interfaces that are able to control and regulate the means of communication between biological and electronic systems. This book summarizes the overall progress made to date in building such interfaces at the level of individual biomolecules and focuses on the latest efforts to generate device platforms that integrate biointerfaces with electronics. Chapter 1 introduces the general concept of dynamic interfaces for bioelectronics and gives an overview of the importance of materials and systems for switchable bioelectronics, introducing the reader to different biointerfaces. Chapter 2 pieces together different types of stimuli-responsive polymers and applications. Chapter 3 lays special emphasis on stimuli-responsive polymers with tunable release kinetics and describes the importance of polymer design for delivery applications. Chapter 4 reviews the field of conformational switching in nanofibers for gas-sensing applications. Finally, Chapter 5 focuses on molecular imprinting polymers as recognition elements for sensing applications. As informative as it is lucid, this handbook makes an essential resource for advanced undergraduate- and graduate-level students in chemistry, as well as researchers in polymer science and electrochemistry, especially those with an interest in responsive polymers and biosensors.