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Biomimetic and Biohybrid Systems: First International Conference, Living Machines 2012, Barcelona, Spain, July 9-12, 2012, Proceedings (Lecture Notes in Computer Science #7375)

This book constitutes the proceedings of the First International Conference on Biomimetic and Biohybrid Systems, Living Machines 2012, held in Barcelona, Spain, in July 2012. The 28 full papers and 33 extended abstracts presented in this volume were carefully reviewed and selected for inclusion in this book. The conference addresses themes related to the development of future real-world technologies which will depend strongly on our understanding and harnessing of the principles underlying living systems and the flow of communication signals between living and artificial systems.

Biomimetic and Biohybrid Systems: Second International Conference, Living Machines 2013, London, UK, July 29 -- August 2, 2013, Proceedings (Lecture Notes in Computer Science #8064)

This book constitutes the refereed proceedings of the second International Conference on Biomimetic and Biohybrid Systems, Living Machines 2013, held in London, UK, in July/August 2013. The 65 revised full papers presented were carefully reviewed and selected from various submissions. The papers are targeted at the intersection of research on novel live-like technologies inspired by scientific investigation of biological systems, biomimetics, and research that seeks to interface biological and artificial systems to create biohybrid systems

Biomimetic Architecture and Its Role in Developing Sustainable, Regenerative, and Livable Cities: Global Perspectives and Approaches in the Age of COVID-19

This book focuses on understanding biomimetic architecture and its role as a sustainable design tool. It presents the role of biomimicry in mitigation and adaptation to climate change and examines how biomimetic architecture can provide healthy solutions to limit the spread of COVID-19 in buildings and cities. Coverage includes global examples of biomimetic approaches and buildings, an evaluation of the performance of biomimicry applications in architecture to illustrate best practices, and an exploration of how nature can offer inspiration in building design to conserve resources and save energy use as well as curb carbon emissions – a reaffirmed goal of COP 26 and an outcome of Glasgow Climate Pact. Finally, the book presents guidelines to enhance urban areas and healthier spaces in buildings to meet COVID-19 social distance regulations and beyond.Examines global applications of biomimicry in architecture;Highlights the importance of biomimicry in driving livability in cities and buildings;Explores the role of biomimetic architecture in mitigating climate change.“The line of argument developed is highly relevant to the present, in addition to being original and pertinent to research on urban regeneration, especially in regard to the exploration of the use of biomimicry architecture in response to changing urban demands.” —Alessandra Battisti, Ph.D., Professor of Architecture, University of Rome La Sapienza-

Biomimetic Architectures by Plasma Processing: Fabrication and Applications

Plasma-processed biomimetic structures are an extremely focused and small subset of biomimetics. Although other methods can also be adopted, experimental synthesis of biomimetic structures mainly focuses on plasma processing. This book deals with the theoretical description of photonic structures available in nature, and the physics and application

Biomimetic Biomaterials for Tissue Regeneration and Drug Delivery

This book illustrates the influence of biomimetics in the field of tissue engineering and drug delivery. These two distinct fields of regenerative medicine have greatly benefited from the concept of biomimetics, which focuses on using or imitating nature to develop materials for improving human lives. The book begins by highlighting the relevance and recent advances in biomimetic biomaterials. An updated and innovative content has been presented in terms of biomimetic systems that are being utilized in controlled delivery and stem cell therapy. Further, the book reviews the role of these materials in enhanced capacity for drug loading, cellular uptake, and controlled release within the target cells. The book includes advanced techniques for characterizing biomimetic biomaterials and highlights their pivotal role in providing three-dimensional templates and synthetic extracellular matrices.

Biomimetic Design Method for Innovation and Sustainability

Presenting a novel biomimetic design method for transferring design solutions from nature to technology, this book focuses on structure-function patterns in nature and advanced modeling tools derived from TRIZ, the theory of inventive problem-solving. The book includes an extensive literature review on biomimicry as an engine of both innovation and sustainability, and discusses in detail the biomimetic design process, current biomimetic design methods and tools. The structural biomimetic design method for innovation and sustainability put forward in this text encompasses (1) the research method and rationale used to develop and validate this new design method; (2) the suggested design algorithm and tools including the Find structure database, structure-function patterns and ideality patterns; and (3) analyses of four case studies describing how to use the proposed method. This book offers an essential resource for designers who wish to use nature as a source of inspiration and knowledge, innovators and sustainability experts, and scientists and researchers, amongst others.

Biomimetic Dye Aggregate Solar Cells (Springer Theses)

This thesis describes a new approach to the construction of solar cells. Following nature's example, this approach has the goal to find a biomimetic self-assembling dye, whose aggregates can mimic the natural light-harvesting system of special photosynthetic active bacteria. The thesis investigates methods to control the self-assembly such that suitable dye aggregates are formed with high internal order and size-confinement. The dye aggregates can be implemented into a new type of solar cells, designed to combine the advantages of hybrid solar cells and solid-state dye-sensitized solar cells (ss-DSSCs): dye aggregate solar cells (DASCs). This book describes the construction and first tests of a prototype for DASCs on the basis of the investigated dye aggregates. The described approach has the advantage that it will enable to build up a light-harvesting system fully synthetically in large scale in order to realize low-cost, light-weight and environmentally friendly solar cells - a worthwhile goal towards the exploitation of clean energy from sunlight.

Biomimetic Lipid Membranes: Fundamentals, Applications, and Commercialization

This book compiles the fundamentals, applications and viable product strategies of biomimetic lipid membranes into a single, comprehensive source. It broadens its perspective to interdisciplinary realms incorporating medicine, biology, physics, chemistry, materials science, as well as engineering and pharmacy at large. The book guides readers from membrane structure and models to biophysical chemistry and functionalization of membrane surfaces. It then takes the reader through a myriad of surface-sensitive techniques before delving into cutting-edge applications that could help inspire new research directions. With more than half the world's drugs and various toxins targeting these crucial structures, the book addresses a topic of major importance in the field of medicine, particularly biosensor design, diagnostic tool development, vaccine formulation, micro/nano-array systems, and drug screening/development.Provides fundamental knowledge on biomimetic lipid membranes;Addresses some of biomimetic membrane types, preparation methods, properties and characterization techniques;Explains state-of-art technological developments that incorporate microfluidic systems, array technologies, lab-on-a-chip-tools, biosensing, and bioprinting techniques;Describes the integration of biomimetic membranes with current top-notch tools and platforms;Examines applications in medicine, pharmaceutical industry, and environmental monitoring.

Biomimetic Medical Materials: From Nanotechnology to 3D Bioprinting (Advances in Experimental Medicine and Biology #1064)

This volume outlines the current status in the field of biomimetic medical materials and illustrates research into their applications in tissue engineering. The book is divided into six parts, focusing on nano biomaterials, stem cells, tissue engineering, 3D printing, immune responses and intellectual property. Each chapter has its own introduction and outlines current research trends in a variety of applications of biomimetic medical materials. The biomimetic medical materials that are covered include functional hydrogels, nanoparticles for drug delivery and medicine, the 3D bioprinting of biomaterials, sensor materials, stem cell interactions with biomaterials, immune responses to biomaterials, biodegradable hard scaffolds for tissue engineering, as well as other important topics, like intellectual property. Each chapter is written by a team of experts. This volume attempts to introduce the biomimetic properties of biomedical materials within the context of our current understanding of the nanotechnology of nanoparticles and fibres and the macroscopic aspects of 3D bioprinting.

Biomimetic Membranes for Sensor and Separation Applications (Biological and Medical Physics, Biomedical Engineering)

This book addresses the possibilities and challenges in mimicking biological membranes and creating membrane-based sensor and separation devices. Recent advances in developing biomimetic membranes for technological applications will be presented with focus on the use of integral membrane protein mediated transport for sensing and separation. It describes the fundamentals of biosensing as well as separation and shows how the two processes are working in a cooperative manner in biological systems. Biomimetics is a truly cross-disciplinary approach and this is exemplified using the process of forward osmosis will be presented as an illustration of how advances in membrane technology may be directly stimulated by an increased understanding of biological membrane transport. In the development of a biomimetic sensor/separation technology, both channels (ion and water channels) and carriers (transporters) are important. An ideal sensor/separation device requires the supporting biomimetic matrix to be virtually impermeable to anything but the solute in question. In practice, however, a biomimetic support matrix will generally have finite permeabilities to water, electrolytes, and non-electrolytes. These non-protein mediated membrane transport contributions will be presented and the implications for biomimetic device construction will be discussed. New developments in our understanding of the reciprocal coupling between the material properties of the biomimetic matrix and the embedded proteins will be presented and strategies for inducing biomimetic matrix stability will be discussed. Once reconstituted in its final host biomimetic matrix the protein stability also needs to be maintained and controlled. Beta-barrel proteins exemplified by the E. Coli outer membrane channels or small peptides are inherently more stable than alpha-helical bundle proteins which may require additional stabilizing modifications. The challenges associated with insertion and stabilization of alpha-helical bundle proteins including many carriers and ligand and voltage gated ion (and water) channels will be discussed and exemplified using the aquaporin protein. Many biomimetic membrane applications require that the final device can be used in the macroscopic realm. Thus a biomimetic separation device must have the ability to process hundred of liters of permeate in hours – effectively demanding square-meter size membranes. Scalability is a general issue for all nano-inspired technology developments and will be addressed here in the context biomimetic membrane array fabrication. Finally a robust working biomimetic device based on membrane transport must be encapsulated and protected yet allowing massive transport though the encapsulation material. This challenge will be discussed using microfluidic design strategies as examples of how to use microfluidic systems to create and encapsulate biomimetic membranes. The book provides an overview of what is known in the field, where additional research is needed, and where the field is heading.

Biomimetic Microengineering

This book will examine the relevant biological subjects involved in biomimetic microengineering as well as the design and implementation methods of such engineered microdevices. Physiological topics covered include regeneration of complex responses of our body on a cellular, tissue, organ, and inter-organ level. Technological concepts in cell and tissue engineering, stem cell biology, microbiology, biomechanics, materials science, micro- and nanotechnology, and synthetic biology are highlighted to increase understanding of the transdisciplinary methods used to create the more complex, robust biomimetic engineered models. The effectiveness of the new bioinspired microphysiological systems as replacements for existing in vitro or in vivo models is explained through sections that include the protocols to reconstitute three-dimensional (3D) structures, recapitulate physiological functions, and emulate the pathophysiology of human diseases. This book will also discuss how researchers can discover bridge technologies for disease modeling and personalized precision medicine. Features Focuses on cutting edge technologies that enable manipulation of living systems in a spatiotemporal manner. Incorporates research on reverse engineering of comples microenvironmental factors in human diseases. Highlights technologies related to patient-specific personalized medicine and their potential uses. Written by chapter authors who are highly respected researchers in science and engineering. Includes extensive references at the end of each chapter to enhance further study. Hyun Jung Kim is an Assistant Professor in the Department of Biomedical Engineering at The University of Texas at Austin. After receiving hois Ph.D. degree at Yonsei University in the Republic of Korea, he did extensive postdctoral research at both the University of Chicago and the Wyss Institute at Harvard University. These efforts resulted in cutting-edge breakthroughs in synthetic microbial community research and organomimetic human Gut-on-a-Chip microsystem. His research on Gut-on-a-Chip technology leads to the creation of a microfluidic device that mimics the physiology and pathology of the living human intestine. Since 2015, he has explored novel human host-microbiome ecosystems to discover the disease mechanism and new therapeutics in inflammatory bowel disease and colorectal cancers at UT Austin. In collaboration with clinicians, his lab is currently developing disease-oriented, patient-specific models for the advancement in pharmaceutical and clinical fields.

Biomimetic Microengineering

This book will examine the relevant biological subjects involved in biomimetic microengineering as well as the design and implementation methods of such engineered microdevices. Physiological topics covered include regeneration of complex responses of our body on a cellular, tissue, organ, and inter-organ level. Technological concepts in cell and tissue engineering, stem cell biology, microbiology, biomechanics, materials science, micro- and nanotechnology, and synthetic biology are highlighted to increase understanding of the transdisciplinary methods used to create the more complex, robust biomimetic engineered models. The effectiveness of the new bioinspired microphysiological systems as replacements for existing in vitro or in vivo models is explained through sections that include the protocols to reconstitute three-dimensional (3D) structures, recapitulate physiological functions, and emulate the pathophysiology of human diseases. This book will also discuss how researchers can discover bridge technologies for disease modeling and personalized precision medicine. Features Focuses on cutting edge technologies that enable manipulation of living systems in a spatiotemporal manner. Incorporates research on reverse engineering of comples microenvironmental factors in human diseases. Highlights technologies related to patient-specific personalized medicine and their potential uses. Written by chapter authors who are highly respected researchers in science and engineering. Includes extensive references at the end of each chapter to enhance further study. Hyun Jung Kim is an Assistant Professor in the Department of Biomedical Engineering at The University of Texas at Austin. After receiving hois Ph.D. degree at Yonsei University in the Republic of Korea, he did extensive postdctoral research at both the University of Chicago and the Wyss Institute at Harvard University. These efforts resulted in cutting-edge breakthroughs in synthetic microbial community research and organomimetic human Gut-on-a-Chip microsystem. His research on Gut-on-a-Chip technology leads to the creation of a microfluidic device that mimics the physiology and pathology of the living human intestine. Since 2015, he has explored novel human host-microbiome ecosystems to discover the disease mechanism and new therapeutics in inflammatory bowel disease and colorectal cancers at UT Austin. In collaboration with clinicians, his lab is currently developing disease-oriented, patient-specific models for the advancement in pharmaceutical and clinical fields.

Biomimetic Microsensors Inspired by Marine Life

This book narrates the development of various biomimetic microelectromechanical systems (MEMS) sensors, such as pressure, flow, acceleration, chemical, and tactile sensors, that are inspired by sensing phenomena that exist in marine life. The research described in this book is multi-faceted and combines the expertise and understanding from diverse fields, including biomimetics, microfabrication, sensor engineering, MEMS design, nanotechnology, and material science. A series of chapters examine the design and fabrication of MEMS sensors that function on piezoresistive, piezoelectric, strain gauge, and chemical sensing principles. By translating nature-based engineering solutions to artificial man-made technology, we can find innovative solutions to critical problems.

Biomimetic Neural Learning for Intelligent Robots: Intelligent Systems, Cognitive Robotics, and Neuroscience (Lecture Notes in Computer Science #3575)

Biomimetic Polymers

The term biomimetic is comparatively new on the chemical scene, but the concept has been utilized by chemists for many years. Furthermore, the basic idea of making a synthetic material that can imitate the func­ tions of natural materials probably could be traced back into antiquity. From the dawn of creation, people have probably attempted to duplicate or modify the activities of the natural world. (One can even find allusions to these attempts in the Bible; e. g. , Genesis 30. ) The term "mimetic" means to imitate or mimic. The word "mimic" means to copy closely, or to imitate accurately. Biomimetic, which has not yet entered most dictionaries, means to imitate or mimic some specific bio­ logical function. Usually, the objective of biomimetics is to form some useful material without the need of utilizing living systems. In a simi­ lar manner, the term biomimetic polymers means creating synthetic poly­ mers which imitate the activity of natural bioactive polymers. This is a major advance in polymer chemistry because the natural bioactive polymers are the basis of life itself. Thus, biomimetic polymers imitate the life process in many ways. This present volume delineates some of the recent progress being made in this vast field of biomimetic polymers. Chemists have been making biomimetic polymers for more than fifty years, although this term wasn't used in the early investigations.

Biomimetic Principles and Design of Advanced Engineering Materials

This book explores the structure-property-process relationship of biomaterials from engineering and biomedical perspectives, and the potential of bio-inspired materials and their applications. A large variety of natural materials with outstanding physical and mechanical properties have appeared in the course of evolution. From a bio-inspired viewpoint, materials design requires a novel and highly cross disciplinary approach. Considerable benefits can be gained by providing an integrated approach using bio-inspiration with materials science and engineering. The book is divided into three parts; Part One focuses on mechanical aspects, dealing with conventional material properties: strength, toughness, hardness, wear resistance, impact resistance, self-healing, adhesion, and adaptation and morphing. Part Two focuses on functional materials with unique capabilities, such as self-cleaning, stimuli-response, structural color, anti-reflective materials, catalytic materials for clean energy conversion and storage, and other related topics. Part Three describes how to mimic natural materials processes to synthesize materials with low cost, efficient and environmentally friendly approaches. For each chapter, the approach is to describe situations in nature first and then biomimetic materials, fulfilling the need for an interdisciplinary approach which overlaps both engineering and materials science.

Biomimetic Principles and Design of Advanced Engineering Materials

This book explores the structure-property-process relationship of biomaterials from engineering and biomedical perspectives, and the potential of bio-inspired materials and their applications. A large variety of natural materials with outstanding physical and mechanical properties have appeared in the course of evolution. From a bio-inspired viewpoint, materials design requires a novel and highly cross disciplinary approach. Considerable benefits can be gained by providing an integrated approach using bio-inspiration with materials science and engineering. The book is divided into three parts; Part One focuses on mechanical aspects, dealing with conventional material properties: strength, toughness, hardness, wear resistance, impact resistance, self-healing, adhesion, and adaptation and morphing. Part Two focuses on functional materials with unique capabilities, such as self-cleaning, stimuli-response, structural color, anti-reflective materials, catalytic materials for clean energy conversion and storage, and other related topics. Part Three describes how to mimic natural materials processes to synthesize materials with low cost, efficient and environmentally friendly approaches. For each chapter, the approach is to describe situations in nature first and then biomimetic materials, fulfilling the need for an interdisciplinary approach which overlaps both engineering and materials science.

Biomimetics: Nature-Based Innovation (Biomimetics Series)

Mimicking nature - from science fiction to engineering realityHumans have always looked to nature's inventions as a source of inspiration. The observation of flying birds and insects leads to innovations in aeronautics. Collision avoidance sensors mimic the whiskers of rodents. Optimization algorithms are based on survival of the fittest, the seed-

Biomimetics: Biologically Inspired Technologies

Nature is the world's foremost designer. With billions of years of experience and boasting the most extensive laboratory available, it conducts research in every branch of engineering and science. Nature's designs and capabilities have always inspired technology, from the use of tongs and tweezers to genetic algorithms and autonomous legged robots.

Biomimetics: Nature-Based Innovation (Biomimetics Series)

Mimicking nature - from science fiction to engineering realityHumans have always looked to nature's inventions as a source of inspiration. The observation of flying birds and insects leads to innovations in aeronautics. Collision avoidance sensors mimic the whiskers of rodents. Optimization algorithms are based on survival of the fittest, the seed-

Biomimetics: Bioinspired Hierarchical-structured Surfaces For Green Science And Technology (Biological and Medical Physics, Biomedical Engineering)

This book presents an overview of the general field of biomimetics and biologically inspired, hierarchically structured surfaces. It deals with various examples of biomimetics, which include surfaces with roughness-induced super-phobicity/philicity, self-cleaning, antifouling, low drag, low/high/reversible adhesion, drag reduction in fluid flow, reversible adhesion, surfaces with high hardness and mechanical toughness, vivid colors produced structurally without color pigments, self-healing, water harvesting and purification, and insect locomotion and stinging. The focus in the book is on the Lotus Effect, Salvinia Effect, Rose Petal Effect, Superoleophobic/philic Surfaces, Shark Skin and Skimmer Bird Effect, Rice Leaf and Butterfly Wing Effect, Gecko Adhesion, Insects Locomotion and Stinging, Self-healing Materials, Nacre, Structural Coloration, and Nanofabrication. This is the first book of this kind on bioinspired surfaces, and the third edition represents a significant expansion from the previous two editions.

Biomimetics: Bioinspired Hierarchical-Structured Surfaces for Green Science and Technology (Biological and Medical Physics, Biomedical Engineering #279)

This revised, updated and expanded new edition presents an overview of biomimetics and biologically inspired structured surfaces. It deals with various examples of biomimetics which include surfaces with roughness-induced superomniphobicity, self-cleaning, antifouling, and controlled adhesion. The focus in the book is on the Lotus Effect, Salvinia Effect, Rose Petal Effect, Oleophobic/philic Surfaces, Shark Skin Effect, and Gecko Adhesion. This new edition also contains new chapters on the butterfly wing effect, bio- and inorganic fouling and structure and Properties of Nacre and structural coloration.

Biomimetics: Bioinspired Hierarchical-Structured Surfaces for Green Science and Technology (Biological and Medical Physics, Biomedical Engineering)

This book presents an overview of the general field of biomimetics - lessons from nature. It presents various examples of biomimetics, including roughness-induced superomniphobic surfaces which provide functionality of commercial interest. The major focus in the book is on lotus effect, rose petal effect, shark skin effect, and gecko adhesion. For each example, the book first presents characterization of an object to understand how a natural object provides functionality, followed by modeling and then fabrication of structures in the lab using nature’s route to verify one’s understanding of nature and provide guidance for development of optimum structures. Once it is understood how nature does it, examples of fabrication of optimum structures using smart materials and fabrication techniques, are presented. Examples of nature inspired objects are also presented throughout.

Biomimetics: Connecting Ecology and Engineering by Informatics

Biomimetics is based on nature, while technology is based on economy. One of the solutions for a sustainable society is to learn a grand design of technology from nature. Methods that mimic nature have a long history in various fields. Now is the time to use biomimetics as a starting technology design. Biomimetics is gaining a great deal of attention not only in materials and mechanical engineering but also in the ecosystem that comprises city planning, agriculture, and forestry. Informatics is being added to biomimetics to support its diversity and cross-disciplinarity. This book will inspire the undergraduate and graduate students, researchers, and general readers who aim to develop technology for sustainability. Edited by Profs Akihiro Miyauchi and Masatsugu Shimomura, two prominent nanotechnology researchers, the book is their second volume on biomimetics. The first volume, Industrial Biomimetics, also published by Jenny Stanford Publishing, focused on the engineering aspect of biomimetics.

Biomimetics: Connecting Ecology and Engineering by Informatics

Biomimetics is based on nature, while technology is based on economy. One of the solutions for a sustainable society is to learn a grand design of technology from nature. Methods that mimic nature have a long history in various fields. Now is the time to use biomimetics as a starting technology design. Biomimetics is gaining a great deal of attention not only in materials and mechanical engineering but also in the ecosystem that comprises city planning, agriculture, and forestry. Informatics is being added to biomimetics to support its diversity and cross-disciplinarity. This book will inspire the undergraduate and graduate students, researchers, and general readers who aim to develop technology for sustainability. Edited by Profs Akihiro Miyauchi and Masatsugu Shimomura, two prominent nanotechnology researchers, the book is their second volume on biomimetics. The first volume, Industrial Biomimetics, also published by Jenny Stanford Publishing, focused on the engineering aspect of biomimetics.