Enables advanced tissue regeneration approaches via expertise from the fields of materials science and biology Stimuli-Responsive Materials for Tissue Engineering comprehensively reviews the use of stimuli-responsive materials in the context of advanced tissue engineering approaches, highlighting applications, challenges, and solutions and reporting on the current state of the art of smart and multifunctional materials being used for tissue engineering, focusing on material types and their properties. The progress that has already been achieved in the field is put into perspective by covering the remaining challenges in the research field of tissue engineering, and solutions are outlined to overcome those. By addressing challenges and ways to overcome them, Stimuli-Responsive Materials for Tissue Engineering is a highly practical resource on advanced tissue regeneration. Smart and multifunctional materials for tissue engineering, covering electroactive and magnetoactive materials Shape memory, photo-responsive, and controlled degradation of stimuli-responsive materials Tissue regeneration strategies based on smart and active biomaterials, covering bone, heart, and neural tissue regeneration Main applications where these biomaterials can be applied, such as in bone, muscle, and skin regeneration Other potential areas where the covered biomaterials are expected to make a major impact in the next decade With comprehensive coverage of the subject, Stimuli-Responsive Materials for Tissue Engineering is an essential resource for materials scientists, bioengineers, engineering scientists, and biotechnologists seeking to understand advanced tissue regeneration approaches, current challenges, and potential solutions to advance progress in the field.

Surface modification of biomaterials can ultimately determine whether a material is accepted or rejected from the human body, and a responsive surface can further make the material "smart" and "intelligent". Switchable and Responsive Surfaces and Materials for Biomedical Applications outlines synthetic and biological materials that are responsive under different stimuli, their surface design and modification techniques, and applicability in regenerative medicine/tissue engineering, drug delivery, medical devices, and biomedical diagnostics. Part one provides a detailed overview of switchable and responsive materials and surfaces, exploring thermo-responsive polymers, environmentally responsive polyelectrolytes and zwitterionic polymers, as well as peptide-based and photonic sensitive switchable materials. Further chapters include a detailed overview of the preparation and analysis of switchable polymer brushes and copolymers for biomedical application. Part two explores the biological interactions and biomedical applications of switchable surfaces, where expert analysis is provided on the interaction of switchable surfaces with proteins and cells. The interaction of stimuli-sensitive polymers for tissue engineering and drug delivery with biosurfaces is critiqued, whilst the editor provides a skillful study into the application of responsive polymers in implantable medical devices and biosensors. - A comprehensive overview of switchable and responsive materials and surfaces - Includes in depth analysis of thermo-responsive polymers, photonic sensitive materials and peptide-based surfaces - Detailed exploration of biological interactions of responsive and switchable surfaces, covering stimuli-sensitive polymers for drug delivery, surfaces with proteins/cells and application of polymers in medical devices

Covers the scientific principles, developments and recent technological advances of stimuli responsive materials for those new to and active in the field.

Stimuli-responsive polymer systems can be defined as functional materials that show physical or chemical property changes in response to external stimuli such as temperature, radiation, chemical agents, pH, mechanical stress, and electric and magnetic fields. Recent developments in manufacturing techniques have facilitated the production of a wide range of stimuli-responsive polymer systems, such as micro- and nanoscale structures, with potential applications in soft sensors and actuators, smart textiles, soft robots, and artificial muscles. This book brings together the recent progress in manufacturing techniques, with particular emphasis on 3D and 4D printing and applications of stimuli-responsive polymer systems in biomedicine and soft robotics.

This book reviews the current knowledge on tunable hydrogels, including the range of different materials and applications, as well as the existing challenges and limitations in the field. It covers various aspects of the material design, particularly highlighting biological responsiveness, degradability and responsiveness to external stimuli. In this book, readers will discover original research data and state-of-the-art reviews in the area of hydrogel technology, with a specific focus on biotechnology and medicine. Written by leading experts, the contributions outline strategies for designing tunable hydrogels and offer a detailed evaluation of the physical and synthetic methods currently employed to achieve specific hydrogel properties and responsiveness. This highly informative book provides important theoretical and practical insights for scholars and researchers working with hydrogels for biomedical and biotechnological applications.

This book provides comprehensive coverage of smart biomaterials and their potential applications, a field that is developing at a very rapid pace. Because smart biomaterials are an emerging class of biomaterials that respond to small changes in external stimuli with large discontinuous changes in their physical properties, they have been designed to act as an “on–off” switch for, among others, bio separation, immunoanalysis, drug delivery technologies, gene therapy, diagnostics, bio sensors and artificial muscles. After an introduction to the topic and the history of smart biomaterials, the author gives the reader an in-depth look at the properties, mechanics, and characterization of smart biomaterials including hydrogels, particles, assemblies, surfaces, fibers and conjugates. Information on the wide range of applications for these materials follows, including drug delivery, tissue engineering, diagnostics, biosensors, bio separation and actuators. In addition, recent advances in shape memory biomaterials as active components of medical devices are also presented.