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.

Regenerative engineering is the convergence of developmental biology, stem cell science and engineering, materials science, and clinical translation to provide tissue patches or constructs for diseased or damaged organs. Various methods have been introduced to create tissue constructs with clinically relevant dimensions. Among such methods, 3D bioprinting provides the versatility, speed and control over location and dimensions of the deposited structures. Three-dimensional bioprinting has leveraged the momentum in printing and tissue engineering technologies and has emerged as a versatile method of fabricating tissue blocks and patches. The flexibility of the system lies in the fact that numerous biomaterials encapsulated with living cells can be printed. This book contains an extensive collection of papers by world-renowned experts in 3D bioprinting. In addition to providing entry-level knowledge about bioprinting, the authors delve into the latest advances in this technology. Furthermore, details are included about the different technologies used in bioprinting. In addition to the equipment for bioprinting, the book also describes the different biomaterials and cells used in these approaches. This text: Presents the principles and applications of bioprinting Discusses bioinks for 3D printing Explores applications of extrusion bioprinting, including past, present, and future challenges Includes discussion on 4D Bioprinting in terms of mechanisms and applications

Conjugation of synthetic materials with cell-responsive biologically-active molecules, in addition to providing structural support and release of biomolecules in the regenerating region, can provide the signaling factors required to initiate the cascade of cell migration, adhesion, differentiation, maturation, growth factor modulation, maintenance of matrix integrity, and tissue morphogenesis. Nanoparticles conjugated with ligands that preferentially interact with cell surface receptors in the tumor environment have the potential to drastically improve bioavailability, selectivity and residence time of the chemotherapeutic agent in the tumor microenvironment, while limiting their peripheral toxicity. Multivalent presentation of tumor-associated antigens on a targeted delivery system containing T and B cell epitopes can result in strong, long-lasting, self-adjuvant immunity against cancer and other diseases in vaccination. These examples demonstrate that cell-responsive conjugate biomaterials have profoundly impacted the medical field.This book is divided into three sections. In the first section, synthesis and characterization, conformation, structure-activity, self-assembly, and host response of conjugate hybrid biomaterials are covered. The second section is dedicated to the applications of conjugate biomaterials in drug delivery and vaccination while the last section is devoted to tissue engineering applications including cell adhesion, control of the stem cell niche, cartilage regeneration, neural and vascular tissue engineering, and dynamic cell culture systems for functionalized biomaterials.There is no doubt that biologically-responsive conjugate biomaterials play a key role in the design of biologics and medical devices, and this pioneering reference book provides a comprehensive review on synthesis, characterization, structure-activity, 3D assembly/fabrication, host response and the emerging applications of conjugate hybrid biomaterials.

Recent developments in microarray technology have changed the landscape of biology and biomedical research, and they have revolutionized RNA and DNA research. In Biological Microarrays: Methods and Protocols, expert researchers explore exciting new developments in the field, providing a comprehensive approach to biological microarrays that conveys not only the state-of-the-art fundamentals, but also includes applications of the most innovative methods. Chapters address both the application of biological microarrays, including DNA/RNA, apatmer, proteins, tissues, oligonucleotides, carbohydrates, biomaterials, cells, bacteria, and virus microarrays, and also explore the different techniques used for generating microarray platforms. Composed in the highly successful Methods in Molecular Biology (TM) series format, each chapter contains a brief introduction, step-by-step methods, a list of necessary materials, and a Notes section which shares tips on troubleshooting and avoiding known pitfalls. Wide-ranging and revolutionary, Biological Microarrays: Methods and Protocols serves as a primary source for academics, practitioners, and professionals in related fields, including biologists, biotechnologists, biochemists, analytical chemists, and biomedical, physical, and microsystems engineers, to name a few, appealing to all of those interested in the present and future state of biological microarray research.

Recent developments in microarray technology have changed the landscape of biology and biomedical research, and they have revolutionized RNA and DNA research. In Biological Microarrays: Methods and Protocols, expert researchers explore exciting new developments in the field, providing a comprehensive approach to biological microarrays that conveys not only the state-of-the-art fundamentals, but also includes applications of the most innovative methods. Chapters address both the application of biological microarrays, including DNA/RNA, apatmer, proteins, tissues, oligonucleotides, carbohydrates, biomaterials, cells, bacteria, and virus microarrays, and also explore the different techniques used for generating microarray platforms. Composed in the highly successful Methods in Molecular Biology (TM) series format, each chapter contains a brief introduction, step-by-step methods, a list of necessary materials, and a Notes section which shares tips on troubleshooting and avoiding known pitfalls. Wide-ranging and revolutionary, Biological Microarrays: Methods and Protocols serves as a primary source for academics, practitioners, and professionals in related fields, including biologists, biotechnologists, biochemists, analytical chemists, and biomedical, physical, and microsystems engineers, to name a few, appealing to all of those interested in the present and future state of biological microarray research.

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.

Tissue engineering aims to develop biological substitutes that restore, maintain, or improve damaged tissue and organ functionality. To date, numerous stem cells and biomaterials have been explored for a variety of tissue and organ regeneration. The challenge for existing stem cell based techniques is that current therapies lack controlled environments that are crucial for regulating stem cell engraftment and differentiation "in vivo," because stem cells are rather sensitive to even minute changes in their environment. Micro- and nanotechnology hold great potential to fabricate biomimetic spatiotemporally controlled scaffolds as well as control stem cell behavior and fate by micro- and nanoscale cues.

This book presents the latest micro- and nanotechnologies used to manipulate stem cell behaviors, which is a critical area for regenerative medicine. Moreover, it covers and details cutting-edge research in nano- and microfabrication techniques and biomaterials for the regeneration of various tissues and organs, such as bone, cartilage, craniofacial, osteochondral, muscle, bladder, cardiac, and vascular tissues."