We designed and stabilized edible plant-based gels by using homogenization technics, in which we dispersed soybean oil at different concentrations (10%-70%) and in the presence and not of surfactant (WP1). We systematically looked at the effect of the different component on the overall stability of the emulsion and on its shear rheology. The microstructure (MFC and dispersed phase) has been investigated with the help of fluorescence confocal microscopy.
To get better insights on fundamental aspect such as the stability of these emulsions towards realistic flows (WP2), we investigated as a first approach, model emulsion undergoing squeezing flow, similarly to what happens during a swallowing process. Our results show that these model o/w emulsions destabilize because of internal rearrangements of droplets (creeping) in addition to the drainage of the continuous phase due to the squeezing motion. These findings allow for a deeper understanding on how to prevent destabilization of more complex emulsions (e.g. MCF emulsions) in realistic situations such as transport of emulsion or human swallowing.
As part of the working package on the mouthfeel prediction of food products (WP3), we initiated our work by considering, in a first step, simple edible power law fluids such as polymer solutions. This system constitutes a first approximation, yet crucial, step towards the rheology of yield stress fluids (emulsion), since
All the results have been reported in internal meetings and internal reports (confidential according to the contract) within the host institute (Unilever R&D). Publishable results have been published in international peer-reviewed journals, as indicated on the online platform.