This book provides a detailed and up-to-date overview of all aspects of yeast cell surface engineering, including fundamental principles, practical strategies for the construction of engineered yeasts, as well as medical and industrial applications. The technique makes it possible to add eukaryotic modifications to the surface-displayed proteins/peptides, which is of significant value in basic and applied research. Generally referred to as an arming (molecular display) technology, it allows yeast to be used as a whole-cell biocatalyst for a range of purposes, including bio-energy production, pollutant removal, recovery of rare metal ions, and preparation of functional cells, all of which are comprehensively covered in the book. Among the medical applications discussed are in vitro antibody preparation and the production of oral vaccines. In addition, it presents the latest advances in protein engineering and high-throughput screening for directed evolution of enzymes. The book enables graduate students and researchers to gain a deeper, comprehensive understanding of the technology, and offers further inspiration for researchers and industrial experts in this rapidly evolving field.
Cell surface engineering is an emerging field concerning cell surface modifications to enhance its functionalities. The book introduces the reader to the area of surface-functionalized cells and summarizes recent developments in the area including fabrication, characterization, applications and nanotoxicity. Topics covered include recent approaches for the functionalization of cells with nanomaterials (polymer nanofilms and nanoparticles), fabrication of functional biomimetic devices and assemblies based on nanoparticle-modified microbial cells and artificial spores (the bioinspired encapsulation of living cells with inorganic nanoshells). The book provides an interdisciplinary approach to the topic with authors from both biological and chemical backgrounds. This multidisciplinary view makes the book suitable for those interested in biomaterials, biochemistry, microbiology and colloid chemistry, providing both an introduction for postgraduate students as well as a comprehensive summary for those already working in the area. biomaterials, biochemistry, microbiology and colloid chemistry.
Research on applications of polymers for biomedical applications has increased dramatically to find improved medical plastics for this rapidly evolving field. This book brings together various aspects of recent research and developments within academia and industry related to polymers for biomedical applications.
A one-stop reference that reviews protein design strategies to applications in industrial and medical biotechnology Protein Engineering: Tools and Applications is a comprehensive resource that offers a systematic and comprehensive review of the most recent advances in the field, and contains detailed information on the methodologies and strategies behind these approaches. The authors—noted experts on the topic—explore the distinctive advantages and disadvantages of the presented methodologies and strategies in a targeted and focused manner that allows for the adaptation and implementation of the strategies for new applications. The book contains information on the directed evolution, rational design, and semi-rational design of proteins and offers a review of the most recent applications in industrial and medical biotechnology. This important book: Covers technologies and methodologies used in protein engineering Includes the strategies behind the approaches, designed to help with the adaptation and implementation of these strategies for new applications Offers a comprehensive and thorough treatment of protein engineering from primary strategies to applications in industrial and medical biotechnology Presents cutting edge advances in the continuously evolving field of protein engineering Written for students and professionals of bioengineering, biotechnology, biochemistry, Protein Engineering: Tools and Applications offers an essential resource to the design strategies in protein engineering and reviews recent applications.
Provides timely, comprehensive coverage of in vivo chemical reactions within live animals This handbook summarizes the interdisciplinary expertise of both chemists and biologists performing in vivo chemical reactions within live animals. By comparing and contrasting currently available chemical and biological techniques, it serves not just as a collection of the pioneering work done in animal-based studies, but also as a technical guide to help readers decide which tools are suitable and best for their experimental needs. The Handbook of In Vivo Chemistry in Mice: From Lab to Living System introduces readers to general information about live animal experiments and detection methods commonly used for these animal models. It focuses on chemistry-based techniques to develop selective in vivo targeting methodologies, as well as strategies for in vivo chemistry and drug release. Topics include: currently available mouse models; biocompatible fluorophores; radionuclides for radiodiagnosis/radiotherapy; live animal imaging techniques such as positron emission tomography (PET) imaging; magnetic resonance imaging (MRI); ultrasound imaging; hybrid imaging; biocompatible chemical reactions; ligand-directed nucleophilic substitution chemistry; biorthogonal prodrug release strategies; and various selective targeting strategies for live animals. -Completely covers current techniques of in vivo chemistry performed in live animals -Describes general information about commonly used live animal experiments and detection methods -Focuses on chemistry-based techniques to develop selective in vivo targeting methodologies, as well as strategies for in vivo chemistry and drug release -Places emphasis on material properties required for the development of appropriate compounds to be used for imaging and therapeutic purposes in preclinical applications Handbook of In Vivo Chemistry in Mice: From Lab to Living System will be of great interest to pharmaceutical chemists, life scientists, and organic chemists. It will also appeal to those working in the pharmaceutical and biotechnology industries.
This book provides detailed information on the surface and surface chemistry of various biointerfaces for the understanding and development of biosensors, biocompatible devices, and drug delivery systems. It highlights the role of interfacial phenomena towards the behaviour of biomolecules on different surfaces and their significance in recent applications. The book also addresses various surface engineering techniques for the modification of biomaterials that are implemented for improving biocompatibility. It provides an updated scientific concept of various interactions of biological systems with surfaces/modified surfaces at the molecular and cellular level. The chapters include various in-vitro, in-vivo, ex-vivo models to illustrate various aspects of Biointerface Engineering. Finally, the book elucidates troubleshooting strategies and future prospects of Biointerface Engineering in Medical Diagnostics and Drug Delivery.
The Cell-Surface Interaction, by J. S. Hayes, E. M. Czekanska and R. G. Richards. Studying Cell-Surface Interactions In Vitro: A Survey of Experimental Approaches and Techniques, by Stefanie Michaelis, Rudolf Robelek and Joachim Wegener. Harnessing Cell-Biomaterial Interactions for Osteochondral Tissue Regeneration, by Kyobum Kim, Diana M. Yoon, Antonios G. Mikos and F. Kurtis Kasper. Interaction of Cells with Decellularized Biological Materials, by Mathias Wilhelmi, Bettina Giere and Michael Harder. Evaluation of Biocompatibility Using In Vitro Methods: Interpretation and Limitations, by Arie Bruinink and Reto Luginbuehl. Artificial Scaffolds and Mesenchymal Stem Cells for Hard Tissues, by Margit Schulze and Edda Tobiasch. Bioactive Glass-Based Scaffolds for Bone Tissue Engineering, by Julia Will, Lutz-Christian Gerhardt and Aldo R. Boccaccini. Microenvironment Design for Stem Cell Fate Determination, by Tali Re’em and Smadar Cohen. Stem Cell Differentiation Depending on Different Surfaces, by Sonja Kress, Anne Neumann, Birgit Weyand and Cornelia Kasper. Designing the Biocompatibility of Biohybrids, by Frank Witte, Ivonne Bartsch and Elmar Willbold. Interaction of Cartilage and Ceramic Matrix, by K. Wiegandt, C. Goepfert, R. Pörtner and R. Janssen. Bioresorption and Degradation of Biomaterials, by Debarun Das, Ziyang Zhang, Thomas Winkler, Meenakshi Mour, Christina I. Günter, Michael M. Morlock, Hans-Günther Machens and Arndt F. Schilling.
Cell Surface GRP78, a New Paradigm in Signal Transduction Biology presents a new paradigm that has emerged in the past decade with the discovery that various intracellular proteins may acquire new functions as cell surface receptors. Two very prominent examples are ATP synthase and GRP78. While the role of cell surface ATP synthase has been reviewed in various books, this book directs its attention to the story of cell surface GRP78. - Edited by the researcher who identified cell surface expression of the molecular chaperone GRP78 as a major factor in prostate cancer and other malignancies - Presents an in-depth treatment of the biological underpinnings of GRP78 and its connection to disease - Provides four-color illustrations that facilitate the narrative