Physical and chemical stability under environmental stress of microemulsions formulated with fish oil.

Enrichment of food and beverages with bioactive lipids is an important initiative to improve consumer's health. Eicosapentaenoic (EPA) and docosahexaenoic (DHA) acids present in fish oil have been reported as those with the greatest bioactivity. Emulsions are an interesting alternative to incorporate functional oil; however, there are few studies on food microemulsions as a way to include this kind of compounds. The present work is intended to deepen the analysis of the Kolliphor RH40 emulsifier with potential application in food microemulsions, characterizing its micellar size and thermo-rheological properties, as well as analyzing the effect of environmental stress on physical and oxidative stability of a microemulsion containing fish oil. No significant changes in droplets size (<15 nm) or in their distribution was observed in a wide range of pH (3-9), ionic strength (0.1-10% CaCl2), centrifuging and different thermal treatments. During freezing, a slight increase in size (<21 nm) was detected, maintaining its optically transparent appearance. The high surface area of the microemulsion droplets led to the decrease in oxidative stability compared to fish oil in bulk. However, when microemulsions were stored at 4 °C, the EPA and DHA contents did not change during storage for 60 days.

Food grade microemulsion systems: Sunflower oil/castor oil derivative-ethanol/water. Rheological and physicochemical analysis.

Microemulsions are thermodynamically stable systems that have attracted considerable attention in the food industry as delivery systems for many hydrophobic nutrients. These spontaneous systems are highly dependent on ingredients and composition. In this work phase diagrams were constructed using two surfactants (Kolliphor RH40 and ELP), water, sunflower oil, and ethanol as cosurfactant, evaluating their physicochemical properties. Stability of the systems was studied at 25 and 60 °C, monitoring turbidity at 550 nm for over a month to identify the microemulsion region. Conductivity was measured to classify between water-in-oil and oil-in-water microemulsions. The phase diagram constructed with Kolliphor RH40 exhibited a larger microemulsion area than that formulated with Kolliphor ELP. All formulations showed a monomodal droplet size distribution with low polydispersity index (<0.30) and a mean droplet size below 20 nm. Systems with higher water content presented a Newtonian behavior; increasing the dispersed phase content produced a weak gel-like structure with pseudoplastic behavior under flow conditions that was satisfactorily modeled to obtain structural parameters.