Abstract
Different forces play key roles in the stability of food colloid dispersions. The focus here is on those controlling attraction and/or repulsion, which concur to stabilization, phase separation, coagulation and are quite evident in water-based systems. The combination of attractive and repulsive forces favors or hinders the association of colloid entities; such processes are often met in food technology. The above processes depend on the forces at work and colloid concentration in the medium (i.e., on interparticle distance). Worked examples deal with milk manipulation procedures, ending in cheese formation. The whole milk sequence is controlled by the combination of forces leading to aggregation and phase separation of casein and other milk components. Thereafter, one gets either fresh, for prompt consumption, or aged cheeses. The combination of attractive (van der Waals, vdW, and depletion) with repulsive (double layer, DL, but also steric) forces results in the dominance of aggregation versus dispersion modes in the milk transformation chain, which depends on the distance among colloid particles, on the amplitude of the mentioned forces, and on their decay. The combined role of double layer and van der Waals (vdW) forces is at the basis of the DLVO theory on colloid stability, which is properly modified when these forces overlap with steric stabilization and, eventually, with depletion. Steric effects are dispersive, and depletion ones favor colloid nucleation in a single phase. The milk manipulation chain is a worked example of the intriguing association features controlled by the mentioned forces (and of ancillary ones, as well), and indicates which forces favor the formation of products such as parmesan or mozzarella cheese but are not alien to the preparation of many other dairy products.
Highlights
The cohesive forces occurring among entities in any physical body become less relevant on passing from solid to liquid and, to gaseous form
The focus here is on those controlling attraction and/or repulsion, which concur to stabilization, phase separation, coagulation and are quite evident in water-based systems
The combination of attractive with repulsive forces results in the dominance of aggregation versus dispersion modes in the milk transformation chain, which depends on the distance among colloid particles, on the amplitude of the mentioned forces, and on their decay
Summary
The cohesive forces occurring among entities in any physical body become less relevant on passing from solid to liquid and, to gaseous form. The 2nd Component is a Gas (Dispersed) foams bubbles no Stabilized colloid particles behave as planets and sense different forces. We try to clarify below some quintessential points of colloid stability by the same methodological approach, i.e., considering the action of different forces concurring to these processes; in words, we deal with the same mental approach that is used to account for the motion of planets. Cooking, drying, salting, smoking, and storage procedures have belonged to human knowledge since many thousand years [5,6,7] Preparations such as anchovies in paste [8], stock cubes, and cheese [9,10] are pertinent examples; many of these products use stabilizers during the manipulation stages, and all are colloidal in nature, or are as such, at least, during some manipulation steps. Data reported in the table refer to average values inferred from different sources
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