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Examining the chemical modification of biological polymers and the emerging applications of this technology, Chemical Modification of Biological Polymers reflects the change in emphasis in this subsection of biotechnology from the study of protein structure and function toward applications in therapeutics and diagnostics. Highlights
This book covers the basics on the organic chemistry underlying the chemical modification of biopolymers, including updates on the use of various chemical reagents. It describes the current status of chemical modification of biological polymers and emerging applications of this technology in biotechnology. These technologies are important for the manufacture of conjugate proteins used in drug delivery, for the preparation of nucleic acid microarrays, and for the preparation of hydrogels and other materials used in tissue engineering.
This book is a comprehensive review of thrombin, especially as regulatory protease. The ready availability of highly purified thrombin has stimulated rapid advances in the cell biology of this important macromolecule. The text focuses on research findings from the discovery of thrombin by Andrew Buchanan in 1842 to the present. A substantial amount of this work was conducted by the author and his colleagues. His work on the purification of thrombin was seminal to much subsequent work on thrombin. This volume provides a framework for future studies now made possible by the discovery of the importance of exosites in the physiology of thrombin function. The current work describes the process of the development of an oral inhibitor of thrombin used in the prevention of thrombosis. Key Features Reviews the history of Thrombin (Fibrin Ferment) Documents the relation of protein engineering and chemical modification in the study of thrombin Summarizes the interaction of thrombin with fibrinogen and fibrin Outlines the role of exosites in thrombin function Describes the development of an oral inhibitor for thrombin
This book is a comprehensive review of thrombin, especially as regulatory protease. The ready availability of highly purified thrombin has stimulated rapid advances in the cell biology of this important macromolecule. The text focuses on research findings from the discovery of thrombin by Andrew Buchanan in 1842 to the present. A substantial amount of this work was conducted by the author and his colleagues. His work on the purification of thrombin was seminal to much subsequent work on thrombin. This volume provides a framework for future studies now made possible by the discovery of the importance of exosites in the physiology of thrombin function. The current work describes the process of the development of an oral inhibitor of thrombin used in the prevention of thrombosis. Key Features Reviews the history of Thrombin (Fibrin Ferment) Documents the relation of protein engineering and chemical modification in the study of thrombin Summarizes the interaction of thrombin with fibrinogen and fibrin Outlines the role of exosites in thrombin function Describes the development of an oral inhibitor for thrombin
The use of the chemical modification of proteins has evolved over the past 80 years, benefiting from advances in analytical, physical, and organic chemistry. Over the past 30 years, the use of chemical reagents to modify proteins has been crucial in determining the function and structure of purified proteins. This groundbreaking work is part of the foundation of emerging disciplines of proteomics, chemical biology, structure biology, and chemical proteomics. Chemical Reagents for Protein Modification, Fourth Edition provides a comprehensive review of reagents used for the chemical modification of proteins, representing a major revision of the work presented in previous editions. The completely updated Fourth Edition is substantially larger and includes five new chapters: Alkylating Agents Acylating Agents Nitration and Nitrosylation Oxidation Modification of Proteins with Reducing Agents There is greatly increased coverage of the chemical modification of cysteine, which is critical for bioconjugate synthesis. The chapter on reduction also provides information necessary for bioconjugate synthesis as well as for the processing of inclusion bodies. The book places emphasis on conditions that affect the specificity of the chemical modification of proteins, such as solvent and temperature. The format has been markedly revised, presenting information based on the chemical nature of the modifying material and on the amino acid residue modified. This new version has increased significance to biopharmaceuticals. Much of the information is in tabular form, which enables the rapid location of cited material.
Edited by renowned protein scientist and bestselling author Roger L. Lundblad, with the assistance of Fiona M. Macdonald of CRC Press, this fifth edition of the Handbook of Biochemistry and Molecular Biology gathers a wealth of information not easily obtained, including information not found on the web. Presented in an organized, concise, and simple-to-use format, this popular reference allows quick access to the most frequently used data. Covering a wide range of topics, from classical biochemistry to proteomics and genomics, it also details the properties of commonly used biochemicals, laboratory solvents, and reagents. An entirely new section on Chemical Biology and Drug Design gathers data on amino acid antagonists, click chemistry, plus glossaries for computational drug design and medicinal chemistry. Each table is exhaustively referenced, giving the user a quick entry point into the primary literature. New tables for this edition: Chromatographic methods and solvents Protein spectroscopy Partial volumes of amino acids Matrix Metalloproteinases Gene Editing Click Chemistry
First published in 1991, Chemical Reagents for Protein Modification, 2nd Edition provides a unique combination of theoretical and practical considerations for the use of chemical reagents for site-specific modification of proteins. The book is divided into three sections, with the first section describing general techniques, including information on the organic chemistry of the various modification reactions; the separation and characterization of site-specific modified proteins, including applications to proteins separated by electrophoresis followed by blotting; the specific chemical cleavage of peptide bonds in proteins; the separation of peptides by high-performance liquid chromatography and electrophoresis; and the use of chemical reagents to assess conformational change in proteins. The second section provides an encyclopedic description of reagents and reactions for the site-specific modification of individual amino acid residues in proteins. The final section presents descriptions of the use of chemical reagents to label biologically significant sites in proteins, including enzyme active sites and the use of covalent cross-linking to measure protein-protein interactions. Particular emphasis is placed on the use of photoaffinity reagents. The book will be an extremely useful research tool for all investigators interested in the solution chemistry of proteins.
Largely driven by major improvements in the analytical capability of mass spectrometry, proteomics is being applied to broader areas of experimental biology, ranging from oncology research to plant biology to environmental health. However, while it has already eclipsed solution protein chemistry as a discipline, it is still essentially an extension of classical protein chemistry, owing much of its maturation to prior contributions. Unfortunately, this debt is not always evident in current literature. The Evolution from Protein Chemistry to Proteomics: Basic Science to Clinical Application, in providing a different perspective than other reviews, strengthens the connection between solution protein chemistry and proteomic technology. Towards this end, Roger Lundblad, a long-time leader in protein chemistry and a scientist who has worked in both academics and industry, brings together some seemingly disparate areas into a single volume. Discussing analytical proteomics, expression proteomics, and clinical proteomics (biomarker identification), he provides coverage that is uniquely rich in detail. Lundblad applies this detail to sample preparation for proteomic analysis, including preparation from blood and tissues. He also presents specifics on the prefractionation of samples used to identify specific subproteomes such as phosphoproteomes and glycoproteomes. Comprehensive reviews are provided covering the chemical modification of proteins, including its use for chemical proteomics. Special attention is given to challenges that impede the identification, validation, and development of biomarkers into clinically useful diagnostic analytes. A bestselling author, Lundblad utilizes classical protein chemistry literature in providing an intellectual basis for proteomics that merges current concepts with the existing literature, while providing the technical detail necessary for the effective commercialization of proteomics.
The activity of many biopharmaceutical polymers is dependent on conformation, and the next several years will see increased interest in the conformational analysis of these polymers resulting from the development of biosimilar or "follow-on" biological products. While a wide variety of approaches to analysis exists, finding the most viable ones would be much easier with a consolidated reference that details the benefits and cost of each approach, with an emphasis on real results and real products. Explores the Growing Role of Conformational Analysis in Comparing Generic Biopharmaceuticals Approaches to the Conformational Analysis of Biopharmaceuticals gathers the most useful techniques and methods into a single volume, putting the greatest emphasis on those approaches that have proven the most fruitful. Rather than cover specific uses of techniques in detail, this book provides commercial biotechnologists and researchers with the information and references they need to make good choices about the technology they choose to use. With a large number of references that direct readers to primary source material, it includes studies drawn from the gamut of current literature, covering physical methods, such as differential scanning calorimetry, light scanning, and analytical ultracentrifugation. It also addresses chemical methods, such as hydrogen-deuterium exchange and trace labeling, along with infrared, ultraviolet, and Raman spectroscopy. Written by Roger Lundblad, a true pioneer in protein science, this volume supplies the necessary information researchers need to access when deciding on the most cost-effective approach, including: Comparability of biopharmaceuticals Characterization of follow-on biologics Quality attributes of protein biopharmaceuticals Confrontational analysis of biopharmaceutical products With a clear focus on relevant commercial biotechnology, this book belongs on the shelves of those serious researchers who are paving the way for the next generation of biopharmaceutical polymers.
Most clinical laboratory tests utilize interstitial and extravascular such as blood, urine, cerebral spinal fluid (CSF), and saliva. For example, CSF is monitored in the context of cancer for both diagnostic and therapeutic reasons. And yet, our understanding of the makeup of interstitial fluids, their relationships to disease, as well as their commercial importance in therapeutics and diagnostics remains rudimentary. Although sometimes perceived as static, interstitial and extravascular fluids are surprisingly dynamic. More than half of serum albumin is in the extravascular space. These fluids move rapidly between the intravascular and extravascular spaces - one entire plasma volume is exchanged very nine hours. In the first half of the book, the authors cover fundamental concepts of interstitial fluids, including their composition and function. They then further review the mechanisms by which interstitial fluids are regulated, characterizing the importance of hyaluronan - a major constituent of interstitial spaces and an a component of synovial fluid; and, outlining the regulation of proteolysis in the interstitial space. In the second half of the book, the authors focus on the coagulation system. This system has been studied extensively in the context of vascular spaces. But many of its components exist in the interstitial spaces. Chapters are devoted to the fibrinolytic system, kallikrein, matrix metalloproteinases, coagulation factors, and protease inhibitors - all are interstitial. By covering a unique array of topics with broad application to biomedical scientists, this book expands our understanding of the importance of interstitial spaces and the fluids that move through and reside in this extravascular environment.
The activity of many biopharmaceutical polymers is dependent on conformation, and the next several years will see increased interest in the conformational analysis of these polymers resulting from the development of biosimilar or "follow-on" biological products. While a wide variety of approaches to analysis exists, finding the most viable ones would be much easier with a consolidated reference that details the benefits and cost of each approach, with an emphasis on real results and real products. Explores the Growing Role of Conformational Analysis in Comparing Generic Biopharmaceuticals Approaches to the Conformational Analysis of Biopharmaceuticals gathers the most useful techniques and methods into a single volume, putting the greatest emphasis on those approaches that have proven the most fruitful. Rather than cover specific uses of techniques in detail, this book provides commercial biotechnologists and researchers with the information and references they need to make good choices about the technology they choose to use. With a large number of references that direct readers to primary source material, it includes studies drawn from the gamut of current literature, covering physical methods, such as differential scanning calorimetry, light scanning, and analytical ultracentrifugation. It also addresses chemical methods, such as hydrogen deuterium exchange and trace labeling, along with infrared, ultraviolet, and Raman spectroscopy. Written by Roger Lundblad, a true pioneer in protein science, this volume supplies the necessary information researchers need to access when deciding on the most cost-effective approach, including:
With a clear focus on relevant commercial biotechnology, this book belongs on the shelves of those serious researchers who are paving the way for the next generation of biopharmaceutical polymers.
This book is an accessible resource offering practical information not found in more database-oriented resources. The first chapter lists acronyms with definitions, and a glossary of terms and subjects used in biochemistry, molecular biology, biotechnology, proteomics, genomics, and systems biology. There follows chapters on chemicals employed in biochemistry and molecular biology, complete with properties and structure drawings. Researchers will find this book to be a valuable tool that will save them time, as well as provide essential links to the roots of their science. Key selling features: Contains an extensive list of commonly used acronyms with definitions Offers a highly readable glossary for systems and techniques Provides comprehensive information for the validation of biotechnology assays and manufacturing processes Includes a list of Log P values, water solubility, and molecular weight for selected chemicals Gives a detailed listing of protease inhibitors and cocktails, as well as a list of buffers
Most clinical laboratory tests utilize interstitial and extravascular such as blood, urine, cerebral spinal fluid (CSF), and saliva. For example, CSF is monitored in the context of cancer for both diagnostic and therapeutic reasons. And yet, our understanding of the makeup of interstitial fluids, their relationships to disease, as well as their commercial importance in therapeutics and diagnostics remains rudimentary. Although sometimes perceived as static, interstitial and extravascular fluids are surprisingly dynamic. More than half of serum albumin is in the extravascular space. These fluids move rapidly between the intravascular and extravascular spaces - one entire plasma volume is exchanged very nine hours. In the first half of the book, the authors cover fundamental concepts of interstitial fluids, including their composition and function. They then further review the mechanisms by which interstitial fluids are regulated, characterizing the importance of hyaluronan - a major constituent of interstitial spaces and an a component of synovial fluid; and, outlining the regulation of proteolysis in the interstitial space. In the second half of the book, the authors focus on the coagulation system. This system has been studied extensively in the context of vascular spaces. But many of its components exist in the interstitial spaces. Chapters are devoted to the fibrinolytic system, kallikrein, matrix metalloproteinases, coagulation factors, and protease inhibitors - all are interstitial. By covering a unique array of topics with broad application to biomedical scientists, this book expands our understanding of the importance of interstitial spaces and the fluids that move through and reside in this extravascular environment.
This book is an accessible resource offering practical information not found in more database-oriented resources. The first chapter lists acronyms with definitions, and a glossary of terms and subjects used in biochemistry, molecular biology, biotechnology, proteomics, genomics, and systems biology. There follows chapters on chemicals employed in biochemistry and molecular biology, complete with properties and structure drawings. Researchers will find this book to be a valuable tool that will save them time, as well as provide essential links to the roots of their science. Key selling features: Contains an extensive list of commonly used acronyms with definitions Offers a highly readable glossary for systems and techniques Provides comprehensive information for the validation of biotechnology assays and manufacturing processes Includes a list of Log P values, water solubility, and molecular weight for selected chemicals Gives a detailed listing of protease inhibitors and cocktails, as well as a list of buffers
First introduced to biomedical research in 1980, the term biomarker has taken on a life of its own in recent years and has come to mean a number of things. In biomedical science, biomarker has evolved to most commonly mean a characteristic that can be used either as a diagnostic or a prognostic, but most significantly as a screening indicator for pathologies that tend to be somewhat silent prior to overt clinical display. Applying scientific rigor, as well as a disciplined approach to nomenclature, Roger Lundblad's Development and Application of Biomarkers rationalizes the current enthusiasm for biomarkers with the use of well-established clinical laboratory analytes in clinical medicine. Highly respected for his work as both a classical protein scientist and as a pioneer in proteomics, Dr. Lundblad catalogs various biomarkers recognized in clinical medicine and, where possible, matches the expectations for advances in screening technologies with the realities of statistical analysis. More specifically, this important reference: Details an extensive list of biomarkers for various stages of a number of cancer types including ovarian, pancreatic, prostate, and breast cancer Looks at how proteomics is used for the discovery and validation of biomarkers Explores the use of microarray technology, ultra-high performance liquid chromatography, and computational bioinformatic approaches for the discovery and use of biomarkers Examines the use of cells and cell fragments as more complex biomarkers Organizes a host of significant biomarkers and essential research by type and use in a series of readily accessible tables Throughout this volume, Dr. Lundblad encourages consideration of biomarkers more as a concept than as laboratory analytes, emphasizing the relation between the discovery of a biomarker and the biology underlying its production. Ultimately, it is a thorough understanding of that underlying biology that will lead to the development of assays that are robust and reproducible, as well as clinically significant.
First introduced to biomedical research in 1980, the term biomarker has taken on a life of its own in recent years and has come to mean a number of things. In biomedical science, biomarker has evolved to most commonly mean a characteristic that can be used either as a diagnostic or a prognostic, but most significantly as a screening indicator for pathologies that tend to be somewhat silent prior to overt clinical display. Applying scientific rigor, as well as a disciplined approach to nomenclature, Roger Lundblad's Development and Application of Biomarkers rationalizes the current enthusiasm for biomarkers with the use of well-established clinical laboratory analytes in clinical medicine. Highly respected for his work as both a classical protein scientist and as a pioneer in proteomics, Dr. Lundblad catalogs various biomarkers recognized in clinical medicine and, where possible, matches the expectations for advances in screening technologies with the realities of statistical analysis. More specifically, this important reference: Details an extensive list of biomarkers for various stages of a number of cancer types including ovarian, pancreatic, prostate, and breast cancer Looks at how proteomics is used for the discovery and validation of biomarkers Explores the use of microarray technology, ultra-high performance liquid chromatography, and computational bioinformatic approaches for the discovery and use of biomarkers Examines the use of cells and cell fragments as more complex biomarkers Organizes a host of significant biomarkers and essential research by type and use in a series of readily accessible tables Throughout this volume, Dr. Lundblad encourages consideration of biomarkers more as a concept than as laboratory analytes, emphasizing the relation between the discovery of a biomarker and the biology underlying its production. Ultimately, it is a thorough understanding of that underlying biology that will lead to the development of assays that are robust and reproducible, as well as clinically significant.
Edited by renowned protein scientist and bestselling author Roger L. Lundblad, with the assistance of Fiona M. Macdonald of CRC Press, this fifth edition of the Handbook of Biochemistry and Molecular Biology gathers a wealth of information not easily obtained, including information not found on the web. Presented in an organized, concise, and simple-to-use format, this popular reference allows quick access to the most frequently used data. Covering a wide range of topics, from classical biochemistry to proteomics and genomics, it also details the properties of commonly used biochemicals, laboratory solvents, and reagents. An entirely new section on Chemical Biology and Drug Design gathers data on amino acid antagonists, click chemistry, plus glossaries for computational drug design and medicinal chemistry. Each table is exhaustively referenced, giving the user a quick entry point into the primary literature. New tables for this edition: Chromatographic methods and solvents Protein spectroscopy Partial volumes of amino acids Matrix Metalloproteinases Gene Editing Click Chemistry
Examining the chemical modification of biological polymers and the emerging applications of this technology, Chemical Modification of Biological Polymers reflects the change in emphasis in this subsection of biotechnology from the study of protein structure and function toward applications in therapeutics and diagnostics. Highlights The basic organic chemistry of the modification proteins, nucleic acids, oligosaccharides, polysaccharides, and their applications New analytical technologies used to characterize the chemical modification of biological polymers Identification of in vivo, non-enzymatic chemical modification of biological polymers Specific chemical modifications to generate biopharmaceutical products This book covers the basics on the organic chemistry underlying the chemical modification of biopolymers, including updates on the use of various chemical reagents. It describes the current status of chemical modification of biological polymers and emerging applications of this technology in biotechnology. These technologies are important for the manufacture of conjugate proteins used in drug delivery, for the preparation of nucleic acid microarrays, and for the preparation of hydrogels and other materials used in tissue engineering.
The fractionation of human blood plasma can be considered to be a mature industry, with the basic technology, alcohol fractionation, dating back at least to the 1940s. Many of the products described in the current work have been approved biologics since the 1950s. The information gathered from the development of plasma proteins has proved vital to the development of recombinant therapeutic proteins. Discussing the role of plasma proteins in current biotechnology, Biotechnology of Plasma Proteins describes the protein composition of human plasma, the fractionation of plasma to obtain therapeutic proteins, and the analysis of these products. It delineates the path from plasma products to recombinant products, and highlights products from albumin, intravenous immunoglobins, and coagulation. It offers a comprehensive review of current techniques for the analysis of proteins including electrophoresis, chromatography, spectrophotometry, mass spectrometry, and updates not published since 1975. Key Topics Protein Composition of Plasma Proteomic methods for plasma protein analysis Plasma protein biomarkers Validation of biomarkers Assays for plasma biomarkers Methods for the Analysis of Protein Products Assay development and validation Electrophoresis Chromatography Immunoassay Mass spectrometry Raman spectroscopy Plasma Fractionation: Historical and Modern Methods Development of Cohn alcohol fractionation Industrial methods Development of chromatographic methods Plasma Protein Products of Therapeutic Value Albumin Intravenous immunoglobulin Coagulation products Growth factors Wound management
The use of the chemical modification of proteins has evolved over the past 80 years, benefiting from advances in analytical, physical, and organic chemistry. Over the past 30 years, the use of chemical reagents to modify proteins has been crucial in determining the function and structure of purified proteins. This groundbreaking work is part of the foundation of emerging disciplines of proteomics, chemical biology, structure biology, and chemical proteomics. Chemical Reagents for Protein Modification, Fourth Edition provides a comprehensive review of reagents used for the chemical modification of proteins, representing a major revision of the work presented in previous editions. The completely updated Fourth Edition is substantially larger and includes five new chapters: Alkylating Agents Acylating Agents Nitration and Nitrosylation Oxidation Modification of Proteins with Reducing Agents There is greatly increased coverage of the chemical modification of cysteine, which is critical for bioconjugate synthesis. The chapter on reduction also provides information necessary for bioconjugate synthesis as well as for the processing of inclusion bodies. The book places emphasis on conditions that affect the specificity of the chemical modification of proteins, such as solvent and temperature. The format has been markedly revised, presenting information based on the chemical nature of the modifying material and on the amino acid residue modified. This new version has increased significance to biopharmaceuticals. Much of the information is in tabular form, which enables the rapid location of cited material.
Reflecting the versatility of the author's science and the depth of his experience, Application of Solution Protein Chemistry to Biotechnology explores key contributions that protein scientists can make in the development of products that are both important and commercially viable, and provides them with tools and information required for successful participation. One of the of the world's most respected protein researchers, Roger Lundblad does not succumb to the notion that new is always better. The application of protein science to the practice of commercial biotechnology is traced to the underlying basic solution protein chemistry. It is only by achieving this understanding that the full potential of protein science may be obtained in the development and characterization of the diverse products of modern biotechnology. Dr. Lundblad also goes far beyond the biopharmaceutical applications that are often equated with protein science today to demonstrate the field's unique versatility. From the making of bread and the invention of adhesives to the production of pharmaceuticals and the development of recombinant DNA products- in each of these products, the role of the protein chemist remains prominent. The important point is that classical protein chemistry is a critical part of the practice of biotechnology in the marketplace. Providing the direction and the foundational work needed by students as well as the details and hundreds of references needed by designers and developers, this remarkable work- Delves into the application of protein science for producing products as diverse as adhesives, drug delivery systems, and quality food products Explores chemistry of attachment of proteins and peptides to solid surfaces with regard to applications both for the improvement of steel and titanium and in DNA and protein microarrays Describes the development of bioconjugates used in antibodies Offers essential advice on guidelines required for producing licensed biopharmaceutical products While he does include a great deal of material not found in other sources, Dr. Lundblad makes a point to separate what is truly new from that which has merely been renamed. A reference unlike most, scientists and students eager to learn will find a text that is as practical as it is purposeful.
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