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This title represents a broad review of current research on LAB and their novel applications with contributions from a number of well-known leading scientists. The book encompasses a wide range of topics including both traditional and novel developing fields, and provides unparalleled, comprehensive information on new advances of genomics, proteomics, metabolism and biodiversity of LAB. Chapters contain state-of-the-art discussions of specific LAB applications such as their use as probiotics, live vaccines and starter cultures in old and new fermented products. The safety of these microorganisms and their interactions with diverse ecosystems natural biota are also covered as well as the new applications of well-known (bacteriocins) and novel (vitamins, low-calorie sugars, etc.) metabolites produced by LAB. This book is an essential reference for established researchers and scientists, doctoral and post-doctoral students, university professors and instructors, and food technologists working on food microbiology, physiology and biotechnology of lactic acid bacteria.
Two of the recent books in the Methods in Molecular Biology series, Yeast Protocols and Pichia Protocols, have been narrowly focused on yeasts and, in the latter case, particular species of yeasts. Food Microbiology Pro- cols, of necessity, covers a very wide range of microorganisms. Our book treats four categories of microorganisms affecting foods: (1) Spoilage organisms; (2) pathogens; (3) microorganisms in fermented foods; and (4) microorganisms p- ducing metabolites that affect the flavor or nutritive value of foods. Detailed information is given on each of these categories. There are several chapters devoted to the microorganisms associated with fermented foods: these are of increasing importance in food microbiology, and include one bacteriophage that kills the lactic acid bacteria involved in the manufacture of different foods—cottage cheese, yogurt, sauerkraut, and many others. The other nine chapters give procedures for the maintenance of lactic acid bacteria, the isolation of plasmid and genomic DNA from species of Lac- bacillus, determination of the proteolytic activity of lactic acid bacteria, det- mination of bacteriocins, and other important topics.
The latest volume in the Advanced Biotechnology series provides an overview of the main production hosts and platform organisms used today as well as promising future cell factories in a two volume book. Alongside describing tools for genetic and metabolic engineering for strain improvement, the authors also impart topical information on computational tools, safety aspects and industrial-scale production. Following an introduction to general concepts, historical developments and future technologies, the text goes on to cover multi-purpose bacterial cell factories, including those organisms that exploit anaerobic biosynthetic power. Further chapters deal with microbes used for the production of high-value natural compounds and those obtained from alternative raw material sources, concluding with eukaryotic workhorses.
High amounts of waste are generated daily in various food processing industries inclusing seed, pomace, pit, peel, germ, husk, broken pulses, sludge, skin, bones, blood, feathers, wash water, and spent residue, among others. Several tons of generated waste can be effectively used to manufacture or recover such value-added by-products as fibers, antioxidants, proteins, vitamins and minerals, biofilms, fertilizers, and animal feed. While food processing- generated waste may lead to health and environmental hazards, it is critical to identify proper protocols to recover valuable ingredients from waste, thereby creating wealth in the society. Wealth out of Food Processing Waste identifies and de...
Microbial polysaccharides represent an attractive alternative to those from plants or macro algae. They can be produced from renewable sources including lignocellulosic waste streams. Their production does not depend on geographical constraints and/or seasonal limitations. Additionally the manipulation of biosynthetic pathways to enhance productivity or to influence the chemical polysaccharide composition is comparatively easy in bacteria. Microbial exopolysaccharides represents a valuable resource of biogenic and biodegradable polymers, suitable to replace petro based polymers in various technical applications. Furthermore, biocompatible exopolysaccharides are very attractive in medical app...
This book focuses exclusively on the beneficial effects of microbes in food. The section on traditional and modern fermented foods covers the role of microbes and their diversity in fermented foods, interaction between the different microflora present in fermented food products, development of starter cultures to improve the nutritional and sensory quality of fermented foods, and factors and processes affecting the safety of various fermented foods. The second section focuses on microbes in and as functional foods: probiotics, prebiotics and synbiotics.
The aim of "Novel Approaches in Biopreservation for Food and Clinical Purposes" is to provide cutting-edge information on biopreservation methods for both food and medical applications. The book has one chapter dedicated to each major food category (milk and dairy, vegetables, meat, fish, bread, flours and beverages) and brief chapters covering preservation approaches for pharmaceuticals, embryos, gametes, cells and tissues. This book assumes a basic understanding of microbiology and food science, aiming to offer an overview of the most commonly and updated techniques currently used, including protective cultures and fermentation starters, bacterial metabolites, essential oils, bacteriophages or endolysins. By presenting this comprehensive overview, the book aims to advance knowledge in the field of biopreservation and foster its implementation in both food and clinical contexts.
Most ecosystem services and goods human populations use and consume are provided by microbial populations and communities. Indeed, numerous provisioning services (e.g. food and enzymes for industrial processes), regulating services (e.g. water quality, contamination alleviation and biological processes such as plant-microbial symbioses), and supporting services (e.g. nutrient cycling, agricultural production and biodiversity) are mediated by microbes. The fast development of metagenomics and other meta-omics technologies is expanding our understanding of microbial diversity, ecology, evolution and functioning. This enhanced knowledge directly translates into the emergence of new applications...