Microbiological Examination Methods of Food and Water (2nd edition) is an illustrated laboratory manual that provides an overview of current standard microbiological culture methods for the examination of food and water, adhered to by renowned international organizations, such as ISO, AOAC, APHA, FDA and FSIS/USDA. It includes methods for the enumeration of indicator microorganisms of general contamination, indicators of hygiene and sanitary conditions, sporeforming, spoilage fungi and pathogenic bacteria. Every chapter begins with a comprehensive, in-depth and updated bibliographic reference on the microorganism(s) dealt with in that particular section of the book. The latest facts on the taxonomic position of each group, genus or species are given, as well as clear guidelines on how to deal with changes in nomenclature on the internet. All chapters provide schematic comparisons between the methods presented, highlighting the main differences and similarities. This allows the user to choose the method that best meets his/her needs. Moreover, each chapter lists validated alternative quick methods, which, though not described in the book, may and can be used for the analysis of the microorganism(s) dealt with in that particular chapter. The didactic setup and the visualization of procedures in step-by-step schemes allow the user to quickly perceive and execute the procedure intended. Support material such as drawings, procedure schemes and laboratory sheets are available for downloading and customization. This compendium will serve as an up-to-date practical companion for laboratory professionals, technicians and research scientists, instructors, teachers and food and water analysts. Alimentary engineering, chemistry, biotechnology and biology (under)graduate students specializing in food sciences will also find the book beneficial. It is furthermore suited for use as a practical/laboratory manual for graduate courses in Food Engineering and Food Microbiology.

This article discusses the basic ways of water-preparation in food industry. Water-preparation plan with elements of disinfecting for production of drinking water and drinks is given. The analysis shows that water should meet definite microbiological requirements. In order to reduce its fatal influence on the health of people the clearing and preparation of water are necessary. Development of techniques and means of clearing without chemical technologies, including ozone treatment technologies, allows one to lower and to get rid of application of chemical compounds and reagents. At the moment the ozone treatment water technologies with consequent treatment on filling filters are the most rational. Ozone is the strong oxidant and disinfects water faster than chlorine in some times. With activated carbon use both the flavouring qualities and smell become better. Technology of mutual ozone processing with absorption is the most perspective for water purification and disinfection, possessives a high efficiency in comparison with attitude to pathogen microorganisms, does not lead to the formation of harmful collateral products. Therefore, the questions of development of safe technologies and means for water preparation and treatment are actual and well timed

Fuer die Beschreibung von Trocknungsprozessen ist die Kenntnis einer Reihe von Stoffdaten, insbesondere des Wasserdampf-Sorptionsverhaltens der Trocknungsprodukte, erforderlich, da diese es gestatten, Verpackungs-, Lager-und Stabilitaetsprobleme richtig einzuschaetzen bzw. loesen zu koennen. Anhand einer umfangreichen Literaturrecherche wurde eine tabellarische Zusammenfassung der fuer den Temperaturbereich von 40 bis 80 Grad C gueltigen publizierten Sorptionsisothermen erstellt. Darueber hinaus werden zwei unterschiedliche Methoden beschrieben, die es gestatten, mit relativ einfachen Labormitteln die Wasserdampfisorptionsisothermen bei hoeherer Temperatur mit hinreichender Genauigkeit experimentell zu ermitteln.

CGIAR Research Program on Water, Land and Ecosystems (WLE) | Ringler Claudia et al., 'Research guide for water-energy-food nexus analysis', , IFPRI, 2018

Protozoan parasites can survive under ambient and refrigerated storage conditions when associated with a range of substrates. Consequently, various treatments have been used to inactivate protozoan parasites (Giardia, Cryptosporidium, and Cyclospora) in food, water, and environmental systems. Physical treatments that affect survival or removal of protozoan parasites include freezing, heating, filtration, sedimentation, UV light, irradiation, high pressure, and ultrasound. Ozone is a more effective chemical disinfectant than chlorine or chlorine dioxide for inactivation of protozoan parasites in water systems. However, sequential inactivation treatments can optimize existing treatments through synergistic effects. Careful selection of methods to evaluate inactivation treatments is needed because many studies that have employed vital dye stains and in vitro excystation have produced underestimations of the effectiveness of these treatments.

For the first time, alginate polymer has been applied to prevent dyes from leaching out of colorimetric oxygen indicator films, which enable people to notice the presence of oxygen in the package in an economic and simple manner. The dye-based oxygen indicator film suffers from dye leaching upon contact with water. In this work, UV-activated visual oxygen indicator films were fabricated using thionine, glycerol, P25 TiO2, and zein as a redox dye, a sacrificial electron donor, UV-absorbing semiconducting photocatalyst, and an encapsulation polymer, respectively. When this zein-coated film was immersed in water for 24h, the dye leakage was as high as 80.80±0.45%. However, introduction of alginate (1.25%) as the coating polymer considerably diminished the dye leaching to only 5.80±0.06%. This is because the ion-binding ability of alginate could prevent the cation dye from leaching into water. This novel water-resistant UV-activated oxygen indicator was also successfully photo-bleached and regained colour fast in the presence of oxygen.

Paper described the method of measuring water content in food products, based on microwave heating and drying of the foodstuff samples. Power supplied to material is controlled as a function of sample mass and features, thus the sample is dried in a short time without overheating. Water content is automatically calculated from the mass losses during drying. The experiments conducted with yoghurt confirmed agreement of the results with a reference method

While investigating certain aspects of animal physiology, neurology or behavior, research scientists sometimes must limit the amount of food or water provided to animals used in a study. Such limitations can negatively impact the health and welfare of laboratory animals by, for example, causing them to experience distress or pain. The author discusses the veterinary and regulatory concerns that laboratory personnel should consider when limiting food or water given to research animals. He concludes that by adequately addressing the needs of animals receiving less food or water than required by regulation, researchers will improve both animal care and scientific study results.