En esta Monografia se trata el tema de la utilizacion del cloro y sus compuestos como medio de alcanzar los requisitos sanitarios que deben cumplir las aguas utilizadas en la industria alimentaria. Se explica la terminologia empleada en cloracion asi como la quimica del cloro en el agua y su comportamiento en funcion de Ph y temperatura. Se ejemplifican distintos sistemas de cloracion y finalmente se hace referencia a un posible programa de control de la cloracion en planta y a metodos analiticos para la evaluacion del cloro activo.

The impact of water on food thermodynamics and physics and, therefore, on its quality is more important than the one of any other food chemical component. When fundamentals of chemical kinetics are applied, the rates of the reactions responsible of food quality decay can be described as a function of food composition and of other external elements interacting with foods. Among them, water activity and water content have been widely used to determine the role of water in the kinetic reactions of deterioration. Recently, researchers have found limitations in using the water activity parameter. According to them, the role of water in foods can be better described by evaluating the role, in stability of the quality attributes, of the non-equilibrium states of amorphous food products. Following this approach, the dynamics of changes are described in kinetics terms and can be more efficiently predicted by the glass transition temperature more than by the water activity. The glass transition, which is a second order transition in amorphous materials from the glassy to the rubbery state, is primarily dependent on water, which is a plasticizer and is responsible for the physical state of multiphase systems (as foods are) together with temperature. The subject of the role of water in the decay of food quality is presented in this paper, according to the principles of food material science | L'impatto dell'acqua sulla termodinamica e sulla fisica dell'alimento e, quindi, sulla sua qualità è maggiore di quello di ogni altro componente chimico. Applicando principi fondamentali di cinetica chimica, le velocità delle reazioni responsabili del decadimento della qualità possono essere espresse in funzione della composizione e di fattori esterni al prodotto. L'attività dell'acqua o il contenuto in umidità sono stati ampiamente utilizzati per determinare il ruolo dell'acqua nelle reazioni cinetiche di degradazione. Scuole più recenti attribuiscono al concetto di attività dell'acqua alcune limitazioni: il ruolo dell'acqua negli alimenti è discusso in relazione allo stato di non-equilibrio dei prodotti alimentari amorfi nella stabilità degli attributi di qualità. Secondo questo approccio la dinamica dei cambiamenti è descritta in termini cinetici e può essere efficacemente predetta dalla temperatura di transizione vetrosa, più che dall'attività dell'acqua. La transizione vetrosa, transizione di secondo ordine da uno stato vetroso allo stato gommoso dei materiali amorfi, è innanzitutto influenzata dall'acqua quale plasticizzante del sistema, che, quindi, insieme alla temperatura, determina lo stato fisico delle fasi di sistemi multifase quali sono gli alimenti. Il tema del ruolo dell'acqua nel decadimento della qualità degli alimenti viene presentato in questo lavoro secondo i principi della scienza dei materiali alimentari

The structured food systems (i.e. cellular tissues) are dissipative structures whose functionality mainly concerns their properties (physico-chemical properties, chemical and biochemical reactions), external interactions with surroundings (interactions with micro-organisms, heat and mass transport pathway) and especially, their interactions with consumers (nutritional value, quality, taste and flavour, texture, appearance: size, shape, colour). Dehydration or rehydration processes concern heat and mass transport phenomena (water, solutes) coupled with micro and macrostructure changes both producing important effects on food functionality. Control of these changes is the major concern in food product development. This control must be applied not only to the changes in physico-chemical properties but also to those related with consumers' issues. Food matrixengineering is a branch of food engineering which aims to apply the knowledge of the food matrixcomposition, structure and properties to promote and control adequate changes which can improve some sensorial and/or functional properties in the food. These changes, which are caused by some basic operations, are related to the phenomena of heat and mass transfer, vaporization-condensation, internal gas or liquid release, structure deformation-relaxation and phase transitions in matrixcomponents, and are usually coupled throughout the operation's progress. The final product may be a new product with improved composition and sensorial properties and/or more stability. All these concepts are discussed in this paper using several examples related to the application of combined food dehydration techniques.

This study has deduced a correlation between points of inflection of water activity and loss factor with respect to moisture content. A point of inflection in loss factor with respect to moisture content was found to coincide with the sorption isotherm point of inflection that defines the transition from multilayer to solution in every instance analysed, with an average difference of just 0.01 kg kg−1. Food can support microbial growth and chemical reactions in water activity levels above this critical transition. This correlation was discovered using published dielectric and sorption data for specific foods at similar temperatures. It was found that low sugar foods containing high levels of hydrocolloids generally exhibited different behaviour from fruits. This shows that microwave heating behaviour will be different in fruits compared to low sugar foods with high hydrocolloid content when drying to achieve a certain water activity and therefore shelf life.

En esta Monografia se trata el tema de la utilizacion del cloro y sus compuestos como medio de alcanzar los requisitos sanitarios que deben cumplir las aguas utilizadas en la industria alimentaria. Se explica la terminologia empleada en cloracion asi como la quimica del cloro en el agua y su comportamiento en funcion de Ph y temperatura. Se ejemplifican distintos sistemas de cloracion y finalmente se hace referencia a un posible programa de control de la cloracion en planta y a metodos analiticos para la evaluacion del cloro activo.

A turn-on fluorescent chemosensor (H-1) for cyanide anions based on dihydroxy phenazine was designed and synthesised. The sensor H-1 exhibits high sensitivity and good selectivity for cyanide in pure water. The CN− response mechanism involves a hydrogen bonding and deprotonation process in the sensor, which induced prominent fluorescence enhancement. The detection limit of the sensor toward CN− is 5.65×10−7M, and other anions had nearly no influence on the probing behavior. In addition, test strips based on the sensor were fabricated, which also exhibit a good selectivity to CN− in water. Notably, this sensor was successfully applied to detect CN− in food samples, which proves a very simple and selective platform for on-site monitoring of CN− in agriculture samples.

The objective of this research was to study the effect of water activity and glass transition temperature on the fat hydrolysis in a food model system. The model system was prepared with tapioca starch, casein, palm oil and sugar as 58, 14, 16 and 12 g/100 g model matrix, respectively. Hydrolysis reaction was accelerated bycommercial lipase at six levels of water content and water activity. Moisture sorption isotherm was obtained using isopiestic method while monolayer value was determined by BET equations. Glass transition temperature was determined from amorphous ingredients of starch and casein. Hydrolysis reaction showed a significantincrease above the monolayer value at 3.55 g water/100 g solid and aw 0.19. Hydrolysis occurred even at the glassy state of the model system. The role of water in the hydrolysis reaction is more related to the water activity concept rather than glass transition concept.

The state of water in foodstuffs is a guiding principle in food design, and the equilibrium concept of water activity (Aw) is ubiquitous. It is regarded as a primary variable or “hurdle” in preservation technology, and a key variable influencing chemical reaction during storage. However, the amount of water in any system differs as function of water activity depending whether it is determined by water sorption or desorption. Even though this hysteresis behaviour has already been described in the literature, no physical interpretation of its origin has yet been proposed with respect to detailed molecular organisation. This work shows, for two different food powders, gluten and a milk-based product that the hysteresis disappears when either go through their glass transition. A more complete DSC analysis for gluten during different sorption/desorption cycles demonstrates that the hysteresis is dependent on the ageing of the material, which evolves in the glassy state and is induced by structural relaxation.

The susceptibility of lipids to oxidation is a major cause of quality deterioration in food emulsions. The reaction mechanism and factors that influence oxidation are appreciably different for emulsified lipids than for bulk lipids. This article reviews the current understanding of the lipid oxidation mechanism in oil-in-water emulsions. It also discusses the major factors that influence the rate of lipid oxidation in emulsions, such as antioxidants, chelating agents, ingredient purity, ingredient partitioning, interfacial characteristics, droplet characteristics, and ingredient interactions. This knowledge is then used to define effective strategies for controlling lipid oxidation in food emulsions.

In the meat industry there are some processes like drying or storage of salted meat products in which the knowledge of water sorption phenomena in salted proteins could be very useful. The sorption and desorption of most salted products is a singular process with three differentiated steps: a(w) < 0.75, a(w) = 0.75 and a(w) > 0.75. SAFES methodology allows the analysis of different elements in a system: the components, phases and states of aggregation in the food during the process to understand the process stages with a suitable level of complexity. It also analyzes the transport functions, chemical reactions and the phenomena occurring during the processing of the product. The aim of this paper is to analyze the sorption phenomena of water in salted proteins using the SAFES methodology for the three different steps of the water desorption process. Salted pork meat isotherms at different three different salt concentrations and three various temperatures were analyzed in order to observe differences between them, in terms of mass transport, reactions, etc. With SAFES methodology, differences in the behaviour of the system, depending on the amount of NaCl added to the pork meat were observed. Differences in mass fluxes were found in relation to temperature and NaCl concentration.