The use of light-emitting proteins for the detection of biomolecules provides fast and sensitive methods which overcome the disadvantages of radioactive labels and the high cost of fluorescent dyes. This reference work summarizes modern advanced techniques and their applications and includes practical examples of assays based on photoproteins. The book presents contemporary key topics like luminescent marine organisms, DNA probes, reporter gene assays and photoproteins, ratiometric sensing, use of photoproteins for in vivo functional imaging and luminescent proteins in binding assays, to name just a few, and is complemented by recent advances in instrumentation. Includes an introductory chapter by 2008 Chemistry Nobel laureate Osamu Shimomura.
The use of light-emitting proteins for the detection of biomolecules provides fast and sensitive methods which overcome the disadvantages of radioactive labels and the high cost of fluorescent dyes. This reference work summarizes modern advanced techniques and their applications and includes practical examples of assays based on photoproteins. The book presents contemporary key topics like luminescent marine organisms, DNA probes, reporter gene assays and photoproteins, ratiometric sensing, use of photoproteins for in vivo functional imaging and luminescent proteins in binding assays, to name just a few, and is complemented by recent advances in instrumentation. Includes an introductory chapter by 2008 Chemistry Nobel laureate Osamu Shimomura.
The only combined organic photochemistry and photobiology handbookAs spectroscopic, synthetic and biological tools become more and more sophisticated, photochemistry and photobiology are merging-making interdisciplinary research essential. Following in the footsteps of its bestselling predecessors, the CRC Handbook of Organic Photochemistry and Pho
This book review series presents current trends in modern biotechnology. The aim is to cover all aspects of this interdisciplinary technology where knowledge, methods and expertise are required from chemistry, biochemistry, microbiology, genetics, chemical engineering and computer science. Volumes are organized topically and provide a comprehensive discussion of developments in the respective field over the past 3-5 years. The series also discusses new discoveries and applications. Special volumes are dedicated to selected topics which focus on new biotechnological products and new processes for their synthesis and purification. In general, special volumes are edited by well-known guest editors. The series editor and publisher will however always be pleased to receive suggestions and supplementary information. Manuscripts are accepted in English. /div
Table of Contents Reporter cells: - Yeast Based Sensors by Mifumi Shimomura-Shimizu and Isao Karube - Mammalian Cell-Based Sensor Systems by Pratik Banerjee, Briana Franz, and Arun K. Bhunia - Fluorescent and Bioluminescent Cell-Based Sensors: Strategies for Their Preservation by Amol Date, Patrizia Pasini, and Sylvia Daunert - Electrochemical Cell-Based Sensors by Eliora Z. Ron and Judith Rishpon - Microbial Cell Arrays by Tal Elad, Jin Hyung Lee, Man Bock Gu, and Shimshon Belkin Devices: - Surface Functionalization for Protein and Cell Patterning by Pascal Colpo , Ana Ruiz , Laura Ceriotti , and François Rossi - Fiber-Optic Based Cell Sensors by Evgeni Eltzov and Robert S. Marks - Electronic Interfacing with Living Cells by James T. Fleming - On-Chip Detection of Cellular Activity by R. Almog , R. Daniel , S. Vernick , A. Ron , H. Ben-Yoav, and Y. Shacham-Diamand
This volume combines the chemistry and materials science of nanomaterials and biomolecules with their detection strategies, sensor physics and device engineering. In so doing, it covers the important types of nanomaterials for sensory applications, namely carbon nanotubes, fullerenes, fluorescent and biological molecules, nanorods, nanowires and nanoparticles, dendrimers, and nanostructured silicon. It also illustrates a wide range of sensing principles, including fluorescence, nanocantilever oscillators, electrochemical detection, antibody-antigen interactions, and magnetic detection.
In this first comprehensive resource to cover the application of single molecule techniques to biological measurements, the pioneers in the field show how to both set up and interpret a single molecule experiment. Following an introduction to single molecule measurements and enzymology, the expert authors consider molecular motors and mechanical properties before moving on to the applications themselves. Detailed discussions of studies on protein enzymes, ribozymes and nucleic acids are also included.
This complete and well-organized overview of chemiluminescence and bioluminescence is divided into two parts. The first covers historical developments and the fundamental principles of these phenomena before going on to review recent advances and instrumentation. The second part deals with the applications in a variety of research fields including life sciences, drug discovery, diagnostics, environment, agrofood, and forensics. The book is suitable not only for researchers currently employing detection techniques in their research activity, but also for those approaching the subject for the first time. Particular emphasis is placed on the use of chemiluminescence and bioluminescence for the development of a variety of (bio)analytical methods, such as flow-assisted methods, enzyme-, antibody-or gene probe-based assays also in multiplexed formats, miniaturized analytical devices, biosensors, BRET and protein complementation assays, whole-cell biosensors, and bioluminescence molecular imaging. Individual chapters are devoted to the most important and rapidly developing fields including: Instrumentation for Chemiluminescence and Bioluminescence; In vivo, Molecular Imaging; Biotechnological Improvements of Bioluminescent Systems; Cell-based Bioluminescent Biosensors, and Miniaturized Analytical Devices Based on Chemiluminescence, Bioluminescence and Electrochemiluminescence. The book also includes a comprehensive collection of recent bibliographic references.
With contributions by more than 30 expert researchers, this handbook covers the whole spectrum from chemistry to cell biology and from theory to application. In so doing, it deals with a broad range of topics from the chemistry and biophysics of caged compounds to their application in time-resolved studies, comparing the properties of different caging groups. The authors describe in detail light-activation of proteins as well as nucleic acids, while a special section is devoted to multiphoton phototriggers. A must-have for every biochemist, biophysicist and molecular biologist developing and working with these novel methods.
Leading scientists from different countries around the world contributed valuable essays on the basic applications and safety, as well as the ethical and moral considerations, of the powerful genetic engineering tools now available for modifying the molecules, pathways, and phenotypes of species of agricultural, industrial and even medical importance. After three decades of perfecting such tools, we now see a refined technology, surprisingly unexpected applications, and matured guidelines to avoid unintentional damage to our and other species, as well as the environment, while trying to contribute to solve the biological, medical and technical challenges of society and industry. Chapters on thermo-stabilization of luciferase, engineering of the phenylpropanoid pathway in a species of high demand for the paper industry, more efficient regeneration of transgenic soybean, viral resistant plants, and a novel approach for rapidly screening properties of newly discovered animal growth hormones, illustrate the state-of-the-art science and technology of genetic engineering, but also serve to raise public awareness of the pros and cons that this young scientific discipline has to offer to mankind.
The only resource to systematically review current experimental methods, this handy reference enables researchers to select the best solution for their experimental problems. For each method covered, the book provides step-by-step protocols, illustrated by typical research applications. After an initial section on probing the lipid bilayer, the text moves on to discuss probing proteins -- including membrane proteins -- and nucleic acids. The first single publication to incorporate chemical markers, fluorescent probes and genetic tags allows a well-informed comparison of different solutions for the same problem in molecular analytics.
