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Biosurfactants: Research and Development provides a thorough overview of biosurfactant research and development across a range of settings and industries, highlighting the novel use of enzymes, metabolic and genetic engineering in biosurfactant production and showcasing diverse experimental models and approaches. Sections discuss fundamental characteristics of biosurfactants, their physio-chemical properties, and their differences from chemically synthesize surfactants, different research approaches for the study of known biosurfactants, and the genetic manipulation of microorganisms to increase biosurfactant productivity, or to produce molecules with improved characteristics. Throughout the book, methods and approaches are discussed in easy-to-digest formats, with methods discussed, ranging from in silico approaches to classical biocatalysis omics analysis and metabolic engineering.

The transformation of polysaccharides into valuable compounds for health and industry requires the careful application of enzyme protocols and controlled biocatalysis. Polysaccharide-Degrading Biocatalysts provides a thorough grounding in these biocatalytic processes and their growing role in the depolymerization of polysaccharides, empowering researchers to discover and develop new enzyme-based approaches across pharmaceuticals, fuels, and food engineering. Here, over a dozen leading experts offer a close examination of structural polysaccharides, genetic modification of polysaccharides, polysaccharide degradation routes, pretreatments for enzymatic hydrolysis, hemicellulose-degrading enzymes, biomass valorization processes, oligosaccharide production, and enzyme immobilization for the hydrolysis of polysaccharides, among other topics and related research protocols. A final chapter considers perspectives and challenges in an evolving, carbohydrate-based economy.

Biocatalyst Immobilization: Foundations and Applications provides a comprehensive overview of biocatalytic immobilization processes, as well as methods for study, characterization and application. Early chapters discuss current progress in enzyme immobilization and methods for selecting and pretreating enzymes prior to immobilization, with an emphasis on navigating common challenges and employing enzyme supports and post immobilization treatments to impact enzymatic activity. Process-based chapters instruct on measuring and reporting on enzyme immobilization efficiency, protein final content, quantification of reaction products, and the use of nanomaterials to characterize immobilized enzymes. Later chapters examine recent advances, including novel enzymatic reactors, multi-enzymatic biocatalysts, enzymatic biosensors, whole cell immobilization, the industrial application of immobilized enzymes, and perspectives on future trends.

Glycoside Hydrolases provides a detailed overview of the biochemical, biophysical, and protein engineering properties of glycoside hydrolases, a class of enzymes in growing use across various applications. Here, more than a dozen global experts discuss the structural and catalytic mechanisms of specific glycoside hydrolases, followed by their implications in biotechnological applications of different industrial sectors such as the food and feed industry, paper and pulp industry, the bioenergy sector and the pharmaceutical industry. Authors consider how the application of glycoside hydrolases may boost industrial production of valued products, and the broader environmental and sustainability goals of converting agrowaste into valued products. This book helps researchers and students across industry and academia gain deep knowledge of glycoside hydrolases, to advance new experimental research and applications from biofuel to drug discovery.

Ureases: Foundations, Classes, and Applications provides a thorough, practical analysis of ureases-enzymes of growing relevance across a range of biotechnological applications and drug discovery. Unique in many aspects, ureases are one of the few enzymes to have nickel in their active sites. This book covers all aspects of this enzymatic class starting with foundational overview and then providing historical urease research and current state, from basic biochemistry to the use of ureases as hallmarks in enzymology, crystallography, and bioinorganic chemistry. The different classes of ureases, structurally diverse but chemically equivalent, are individually discussed. The multi-protein, multi-step activation of ureases (with chemical modification of residues, transport, and transfer of nickel ions) are examined in-depth, along with the catalytic mechanisms of ureolysis and its inhibitors. The final two sections of the book address multiple applications of ureases in health and biotechnology, respectively, going from gastric ulcer treatment to architectural uses in buildings and engineering. Future applications and next steps in research are also considered.

Transglutaminase: Fundamentals and Applications, a new volume in the Foundations and Frontiers in Enzymology series, stands as a comprehensive resource on this increasingly important class of enzymes. Following an introduction to the field, international experts discuss basic biology and structure - function relationships of transglutaminases, ongoing fundamental research, and new application areas, including food processing, material synthesis, biomedicine, disease treatment, and biotechnology. Approaches for sourcing transglutaminases from animals, plants, and microorganisms are considered, followed by chapters on applied uses in biomedicine, skin, bone biology, medicine, drug development, tissue engineering, seafood bioprocessing, dairy bioprocessing, synthesis of materials and polymers, and as an immobilization agent.Research protocols are also provided, including research rationale, design, substrates, assays, and microassay steps for studying transglutaminases.