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This book focuses on bioconversion of lignocellulosic residues into single-cell protein, which offers an alternative to conventional proteins (such as soybean meal, egg protein or meat protein in animal feed) that is not affected by the climate. It provides an overview of the general uses of lignocellulosic residues and their bioconversion into single-cell protein using microorganisms, as well as the recovery of the valuable by-products. It also explores the benefits and potential drawbacks of single-cell protein, with an emphasis on the economic advantages of such processes. Given its multidisciplinary scope, the book represents a valuable resource for academics and industry practitioners interested in the production of single-cell protein from lignocellulosic residues.
In early 1973, I returned to Israel from a post-doctoral fellowship at Harvard University, and was accepted as a lecturer in the Department of Applied Microbiology at the Hebrew University of Jerusalem. Shortly after my return, Professor Richard Mateles, who at that time was head of the Department, suggested that I purchase a good and comprehensive book on single cell protein (SCP) in order to expand my general knowledge in the subject I had started then to work on; that was microbial utilization of one-carbon (C ) compounds. l Naturally, I took his advice (after all, he was the Boss) and bought the book, which was the only general book published on this subject at that time, and was based on papers presented at the First International Conference on Single Cell Protein, held at the Massachussetts Institute of Technology (M.I.T.), on October 1967 (Mateles and Tannenbaum, editors) [1]. Through this book I became acquainted with the world's hunger problem that existed in the past, and ways in which it was to be solved by SCP products prepared from CO , fossil-based raw 2 materials, and from wastes.
ABSTRACT: Technical alternatives for the production ofSingle-Cell Protein (SCP), and the operational and economicaspects of these alternatives are discussed. Topics include:1) SCP for human and animal consumption; 2) cellcollection, fermentation, and protein extraction techniques;3) production and processing methods; 4) uses of carob,agricultural wastes, cane, coffee, whey, sulfite liquor,methane, and yeast in SCP production; 5) evaluation methods;6) marketing procedures; and 7) international applicationsand guidelines.
Pretreatment and degradation of lignocellulosis materials; Principles for pre-treatment of cellulose substances; Prospects in the United States for using lignocellulosic materials; Biodegradation of lignin by Phanerochaete chrysosporium; Progress and problems in the utilization of cellulosic materials; Strain improvement for the production of microbial enzymes for biomass conversion; Microbial delignification of ligno-cellulosic materials; Sulfur free pre-treatment of lignocellulosic materials; Production of SCP enriched substrates from cellulosic materials; Cellulases: delicate exoproteins - demonstratin of multienzyme complexes within the culture fluid of Trichoderma reesei; Lignin and lignocellulose; Factors determining lignin decomposition and in vitro degestibility of wheat straw during solid state fermentation with white rot fungi; Solid culture using alkali treated straw and cellulolytic fungi; Studies on the extracellular cellulotytic enzyme system of Chaetomium cellulotyticum; Process development; Pre-treatment and conversion of straw into protein in a solid-state culture; Pre-treatment of cereal straws and poor quality hays; Production of mycelial biomass on waste water in a rotating disc fermenter; Protein erichment of pretreated lignocellulosic materials by fungal fermentation; Carbohydrates; Protein enrichment of starchy materials by solid state fermentation; Solic state fermentation of cassava with Rhizopus oligosporus NRRL 2710; Utilisation de la bagasse traitee par la soude pour la production de proteines d'organismes unicellulaires; Conversion of agricultural and industrial wastes for cellulose hydrolysis; Cellulose hydrolosis of papermill sludge; Protein enrichment of sugar beet pulps by solid state fermentation; Single cell protein from whey; General aspects of production of biomass by yeast fermentation from whey and permeate; Utilisation of whey and ultrafiltration permeates; Upgrading of mild UF-permeate by yeast fermentation - semiindustrial trials and economy; Industrial production of S.C.P. from whey; Study of S.C.P. production from starch; Whey as a source for microorganisms / amino acid pattern; SCP production from whey: scale-up of a process; Nutrition and toxicology; The animal nutritionists' dream of a new SCP; Toxicological evaluation of SCP produced from whey; Milk ultrafiltration permeate fermented by yeast: nutritive value for growing pigs; Methods of evaluation of energy and protein values for pigs of three yeast grown on alcanes; Economic considerations regarding SCP in animal feeding; Community guidelines fro the assessment of non-traditional products obtained through the culture of microorganisms and used in animal nutrition.
Chaetomium genus was established by Gustav Kunze in 1817. According to Index Fungorum Partnership, there are 273 Chaetomium species accepted till now. Members of the genus Chaetomium are capable of colonizing various substrates and are well-known for their ability to degrade cellulose and to produce a variety of bioactive metabolites. More than 200 compounds have been reported from this genus. A huge number of new and bioactive secondary metabolites associated with unique and diverse structural types, such as chaetoglobosins, epipolythiodioxopiperazines, azaphilones, depsidones, xanthones, anthraquinones, chromones, and steroids, have been isolated and identified. Many of the compounds have been reported to possess significant biological activities, such as antitumor, antimalarial, cytotoxic, enzyme inhibitory, antimicrobial, phytotoxic, antirheumatoid and other activities. Chaetomium taxa are frequently reported to be cellulase and ligninase producers with the ability to degrade cellulosic and woody materials. This is the first, comprehensive volume covering Chaetomium genus in detail. It includes the latest research, methods, and applications, and was written by scholars working directly in the field. The book also contains informative illustrations and is fully referenced for further reading.
Biochemical Engineering and Biotechnology, 2nd Edition, outlines the principles of biochemical processes and explains their use in the manufacturing of every day products. The author uses a diirect approach that should be very useful for students in following the concepts and practical applications. This book is unique in having many solved problems, case studies, examples and demonstrations of detailed experiments, with simple design equations and required calculations. Covers major concepts of biochemical engineering and biotechnology, including applications in bioprocesses, fermentation technologies, enzymatic processes, and membrane separations, amongst others Accessible to chemical engineering students who need to both learn, and apply, biological knowledge in engineering principals Includes solved problems, examples, and demonstrations of detailed experiments with simple design equations and all required calculations Offers many graphs that present actual experimental data, figures, and tables, along with explanations
The agricultural and forestry processing wastes (lignocellulosics) are an important material resource and energy source. However, if untreated they can pose a danger to the environment and potentially valuable resources. Microorganisms contribute significantly to solving the problem of biomass degradation, its recycling and conservation. In the recent years, an increasing interest shown by the textile, food, feed & pulp, and paper industries in the microbial and enzymatic processes has triggered in-depth studies of lignocellulolytic microorganisms and their enzymes. Moreover, the advent of recombinant DNA technology in the late 1970s further paved the way for developing technologies based on lignocellulolytic microbes and enzymes. Lignocellulose Biotechnology presents a comprehensive review of the research directed towards environmentally friendly agricultural and forest by-products. The book comprises 22 chapters, divided in four sections. It deals with a wide range of topics including biodiversity of lignocellulose degrading microorganisms and their enzymes, molecular biology of biodegradation of lignin, characterization of lignocellulolytic enzymes, bioconversion of plant biomass to produce enzymes, animal feed, bioethanol and industrial applications of lignocellulolytic enzymes. The chapters dealing with industrial applications also address current biotechnological approaches in lignocellulose bioconversion to value added products. This book is essential for students, researchers, scientists, and engineers working in the fields of environmental microbiology, environmental biotechnology, life sciences, waste management, and biomaterials.
A text to the advances and development of novel technologies in the production of high-value products from economically viable raw materials Lignocellulosic Biorefining Technologiesis an essential guide to the most recent advances and developments of novel technologies in the production of various high-value products from economically viable raw materials. Written by a team of experts on the topic, the book covers important topics specifically on production of economical and sustainable products such as various biofuels, organic acids, enzymes, biopigments, biosurfactants, etc. The book highlights the important aspects of lignocellulosic biorefining including structure, function, and chemical composition of the plant cell wall and reviews the details about the various components present in the lignocellulosic biomass and their characterizations. The authors explore the various approaches available for processing lignocellulosic biomass into second generation sugars and focus on the possibilities of utilization of lignocellulosic feedstocks for the production of biofuels and biochemicals. Each chapter includes a range of clear, informative tables and figures, and contains relevant references of published articles. This important text: Provides cutting-edge information on the recent developments in lignocellulose biorefinery Reviews production of various economically important and sustainable products, such as biofuels, organic acids, biopigments, and biosurfactants Highlights several broad-ranging areas of recent advances in the utilization of a variety of lignocellulosic feedstocks Provides a valuable, authoritative reference for anyone interested in the topic Written for post-graduate students and researchers in disciplines such as biotechnology, bioengineering, forestry, agriculture, and chemical industry, Lignocellulosic Biorefining Technologies is an authoritative and updated guide to the knowledge about various biorefining technologies.
Dried biomass of microbes, better known as SCP can be served as alternative protein to human beings and can also be supplied to animals. In addition to approximately 60- 82% protein content, SCP biomass also comprise of vitamins, fats, minerals and carbohydrate. Most microbes and algae have about 1/3 of their biomass as protein. These microbes can be easily cultivated on a large scale to harvest protein. Single-cell proteins can be simply defined as proteins found in microbes that are used for protein supplementation. Multicellular molds and algae are also used to harvest protein. The most popular use of SCP yeast was during World War II, when food shortages plagued Germany. The emphasis on the Post World War on the continuation of SCP production has been encouraged to combat the problems of hunger and malnutrition . Microbes have since been widely used to supplement food. The benefits of single cell protein include less water, less land use, less biological threats and more environment friendly. One maJor benefit with this biomass is that amino acids particularly lysine and methionine are in abundance. Additionally, economical wastes can be utilized as substrate by microorganisms to produce protein and amino acid rich biomass. Besides fruit, vegetable and molasses wastes, petroleum by- product, ethanol, methanol, natural gas and lignocelluloses have been used as common substrates . Significant advances in SCP methods worldwide had a profound effect on the development of modern biotechnology. With the help of various fields including microbiology, biochemistry, genetics, chemical and process engineering, food technology, ecology, agriculture, medicine, animal nutrition, toxicology, veterinary technology and economics there have been huge benefits in research and SCP production process. For treatment of wastewater, alcohol manufacture, food science and enzyme technology SCP can act as innovative solution.