Summary
This project aims to develop a new consumer acceptable all plant based solutions for stabilisation of edible emulsions, whose design is based on the fundamental understanding of the structure-stabilisation-flow properties of cellulose microfibril (MFC)-containing hybrid systems that are naturally found in plant cells. While there is much empirical knowledge about emulsion rheology and stability, the microscopic physical mechanisms that govern emulsion behaviour are still poorly understood, and in this particular case, for emulsions with a complexity that goes beyond the standard oil/water/surfactant systems. This lack of understanding greatly hampers the rational design of all plant structured emulsion-based products. To bridge this gap, we bring together a team of industrial and academic research groups with different, complementary expertise. By using high energy density processes for efficient deagglomeration of the CMF and proposing a new structuring approach through the continuous phase of the plant based emulsion, we will control emulsion stability. By combining macroscopic rheology and tribology with novel microfluidic tools and imaging techniques, we will establish the relation between the macroscopic flow behaviour and stability of the emulsions and the microscopic structure and interactions, and thereby increase our understanding of flowing emulsions beyond the current empirical models. It will help us to move further and provide a special focus on the mouthfeel of all plant structured emulsions. The prediction of mouthfeel texture attributes from rheology is crucial for the food industry to take a more systematic approach towards product design and optimization in order to meet consumers' preference is for natural, simple and flexible diets and other plant-focused formulations as closely as possible. The results of the project are translatable to other industries where emulsion formulation is required.
Unfold all
/
Fold all
More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/798455 |
Start date: | 01-12-2018 |
End date: | 30-11-2020 |
Total budget - Public funding: | 165 598,80 Euro - 165 598,00 Euro |
Cordis data
Original description
This project aims to develop a new consumer acceptable all plant based solutions for stabilisation of edible emulsions, whose design is based on the fundamental understanding of the structure-stabilisation-flow properties of cellulose microfibril (MFC)-containing hybrid systems that are naturally found in plant cells. While there is much empirical knowledge about emulsion rheology and stability, the microscopic physical mechanisms that govern emulsion behaviour are still poorly understood, and in this particular case, for emulsions with a complexity that goes beyond the standard oil/water/surfactant systems. This lack of understanding greatly hampers the rational design of all plant structured emulsion-based products. To bridge this gap, we bring together a team of industrial and academic research groups with different, complementary expertise. By using high energy density processes for efficient deagglomeration of the CMF and proposing a new structuring approach through the continuous phase of the plant based emulsion, we will control emulsion stability. By combining macroscopic rheology and tribology with novel microfluidic tools and imaging techniques, we will establish the relation between the macroscopic flow behaviour and stability of the emulsions and the microscopic structure and interactions, and thereby increase our understanding of flowing emulsions beyond the current empirical models. It will help us to move further and provide a special focus on the mouthfeel of all plant structured emulsions. The prediction of mouthfeel texture attributes from rheology is crucial for the food industry to take a more systematic approach towards product design and optimization in order to meet consumers' preference is for natural, simple and flexible diets and other plant-focused formulations as closely as possible. The results of the project are translatable to other industries where emulsion formulation is required.Status
CLOSEDCall topic
MSCA-IF-2017Update Date
28-04-2024
Images
No images available.
Geographical location(s)