Container Molecules and Their Guests deals with the fundamental principles and objectives that govern this rapidly developing subject and illustrates the emergence of a new field of biomimetic chemistry. The book demonstrates how a number of techniques, such as molecular modelling, synthesis, crystal structure, NMR solution structure and mass spectral structure determinations can be combined to develop a new branch of organic chemistry. It discusses the chemistry of completely new families of complexes - the carceplexes, hemicarceplexes and velcraplexes - and reviews for the first time the uses of the interiors of hemicarceplexes as a new phase for carrying out chemical reactions and for protecting unstable species. Furthermore, it illustrates how complexation and decomplexation rates are measured to provide free energies of binding, discusses new phenomena such as constrictive binding, and shows how solvophobic forces drive complexation in a variety of organic solvents. It also covers catalysis through complexation and chiral recognition in catalysis, both secondary themes of this volume. Container Molecules and Their Guests will provide stimulating reading for researchers, post-graduate students and teachers involved in bio-organic chemistry, organic chemistry, materials science, and medicinal and pharmaceutical chemistry.
Organic Chemistry, Volume 4: Fundamentals of Carbanion Chemistry provides information pertinent to carbanion chemistry. This book explores several topics, including carbonium ions, carbanions, carbenes, and carbon radicals. Comprised of six chapters, this volume starts with an overview of the variation of the kinetic and thermodynamic acidities of carbon acids with substituents and environments. This text then explores the methods of carbanion stabilization by substituents and discusses the various types of stabilization. Other chapters explain the stereochemistry of hydrogen–deuterium exchange and examine the stereochemistry of substitution reactions of organometallic compounds. This book discusses as well the structure and immediate environment of reaction intermediates through the use of stereochemical techniques. The final chapter considers the unsaturated anionic rearrangements of carbanions, carbonium ions, as well as carbon radicals and other rearrangements. Chemists, organic chemists, researchers, and graduate students interested in the field of carbanion chemistry will find this book extremely useful.
Container Molecules and Their Guests deals with the fundamental principles and objectives that govern this rapidly developing subject and illustrates the emergence of a new field of biomimetic chemistry. The book demonstrates how a number of techniques, such as molecular modelling, synthesis, crystal structure, NMR solution structure and mass spectral structure determinations can be combined to develop a new branch of organic chemistry. It discusses the chemistry of completely new families of complexes - the carceplexes, hemicarceplexes and velcraplexes - and reviews for the first time the uses of the interiors of hemicarceplexes as a new phase for carrying out chemical reactions and for protecting unstable species. Furthermore, it illustrates how complexation and decomplexation rates are measured to provide free energies of binding, discusses new phenomena such as constrictive binding, and shows how solvophobic forces drive complexation in a variety of organic solvents. It also covers catalysis through complexation and chiral recognition in catalysis, both secondary themes of this volume. Container Molecules and Their Guests will provide stimulating reading for researchers, post-graduate students and teachers involved in bio-organic chemistry, organic chemistry, materials science, and medicinal and pharmaceutical chemistry.
Organic Chemistry, Volume 4: Fundamentals of Carbanion Chemistry provides information pertinent to carbanion chemistry. This book explores several topics, including carbonium ions, carbanions, carbenes, and carbon radicals. Comprised of six chapters, this volume starts with an overview of the variation of the kinetic and thermodynamic acidities of carbon acids with substituents and environments. This text then explores the methods of carbanion stabilization by substituents and discusses the various types of stabilization. Other chapters explain the stereochemistry of hydrogen–deuterium exchange and examine the stereochemistry of substitution reactions of organometallic compounds. This book discusses as well the structure and immediate environment of reaction intermediates through the use of stereochemical techniques. The final chapter considers the unsaturated anionic rearrangements of carbanions, carbonium ions, as well as carbon radicals and other rearrangements. Chemists, organic chemists, researchers, and graduate students interested in the field of carbanion chemistry will find this book extremely useful.
Over the last century, medicine has come out of the "black bag" and emerged as one of the most dynamic and advanced fields of development in science and technology. Today, biomedical engineering plays a critical role in patient diagnosis, care, and rehabilitation. As such, the field encompasses a wide range of disciplines, from biology and physiology to material science and nanotechnology. Reflecting the enormous growth and change in biomedical engineering during the infancy of the 21st century, The Biomedical Engineering Handbook enters its third edition as a set of three carefully focused and conveniently organized books. Reviewing applications at the leading edge of modern biomedical engineering, Tissue Engineering and Artificial Organs explores transport phenomena, biomimetics systems, biotechnology, prostheses, artificial organs, and ethical issues. The book features approximately 90% new material in the tissue engineering section, integrates coverage of life sciences with a new section on molecular biology, and includes a new section on bionanotechnology. Prominent leaders from around the world share their expertise in their respective fields with many new and updated chapters. New technologies and methods spawned by biomedical engineering have the potential to improve the quality of life for everyone, and Tissue Engineering and Artificial Organs sheds light on the tools that will enable these advances.
Biochemical kinetics refers to the rate at which a reaction takes place. Kinetic mechanisms have played a major role in defining the metabolic pathways, the mechanistic action of enzymes, and even the processing of genetic material. The Handbook of Biochemical Kinetics provides the "underlying scaffolding" of logic for kinetic approaches to distinguish rival models or mechanisms. The handbook also comments on techniques and their likely limitations and pitfalls, as well as derivations of fundamental rate equations that characterize biochemical processes. Key Features* Over 750 pages devoted to theory and techniques for studying enzymic and metabolic processes* Over 1,500 definitions of kinetic and mechanistic terminology, with key references* Practical advice on experimental design of kinetic experiments* Extended step-by-step methods for deriving rate equations* Over 1,000 enzymes, complete with EC numbers, reactions catalyzed, and references to reviews and/or assay methods* Over 5,000 selected references to kinetic methods appearing in the Methods in Enzymology series* 72-page Wordfinder that allows the reader to search by keywords* Summaries of mechanistic studies on key enzymes and protein systems* Over 250 diagrams, figures, tables, and structures
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