Florence Barbe

The heat treatment and the gelation are strong determinants of the kinetics of milk proteins digestion and of the peripheral availability of amino acids

This study aimed to determine the kinetics of milk protein digestion and amino acid absorption after ingestion of four dairy matrices by six minipigs: unheated or heated skim milk and corresponding rennet gels. Digestive contents and plasma samples were collected over a 7 h-period after meal ingestion. Gelation of milk slowed down the outflow of the meal from the stomach and the subsequent absorption of amino acids, and decreased their bioavailability in peripheral blood. The gelled rennet matrices also led to low levels of milk proteins at the duodenum. Caseins and β-lactoglobulin, respectively, were sensitive and resistant to hydrolysis in the stomach with the unheated matrices, but showed similar digestion with the heated matrices, with a heat-induced susceptibility to hydrolysis for β-lactoglobulin. These results suggest a significant influence of the meal microstructure (resulting from heat treatment) and macrostructure (resulting from gelation process) on the different steps of milk proteins digestion.

Acid and rennet gels exhibit strong differences in the kinetics of milk protein digestion and amino acid bioavailability

This study aimed at determining the kinetics of milk protein digestion and amino acid absorption after ingestion by six multi-canulated mini-pigs of two gelled dairy matrices having the same composition, similar rheological and structural properties, but differing by their mode of coagulation (acidification/renneting). Duodenal, mid-jejunal effluents and plasma samples were collected at different times during 7h after meal ingestion. Ingestion of the acid gel induced a peak of caseins and β-lactoglobulin in duodenal effluents after 20min of digestion and a peak of amino acids in the plasma after 60min. The rennet gel induced lower levels of both proteins in the duodenum (with no defined peak) as well as much lower levels of amino acids in the plasma than the acid gel. Plasma ghrelin concentrations suggested a potentially more satiating effect of the rennet gel compared to the acid gel. This study clearly evidences that the gelation process can significantly impact on the nutritive value of dairy products.

Impact of the Dairy Matrix Structure on Milk Protein Digestion Kinetics: Mechanistic Modelling Based on Mini-pig In Vivo Data

Beyond the individual content in nutrients, it is now established that the matrix structure is also to consider when evaluating the nutritional properties and possible health effects of a food material. The objective of this study was to gain knowledge on the effect of the structure of dairy products on the digestion of milk proteins as inferred from a mathematical modelling of mini-pig in vivo data. Six dairy matrices of the same composition but differing by their physicochemical and structural properties were investigated. They were manufactured using technological processes commonly used in the industry (heat treatment, rennet gelation, acid gelation and mixing). The experimental results cover a 7-h postprandial period and consist of plasmatic amino acid concentrations as well as dry matter contents and chromium concentrations (a marker of the liquid phase of the meal) of samples collected at the stomach exit. The model developed not only accounts for the main digestive events but also for phenomena that can occur within the stomach (milk clotting and aggregate syneresis). It provides a good fitting of all the experimental data and allows estimating parameter values that can be explained by considering the properties of the matrices investigated. The model has also been used to estimate quantities that cannot be observed experimentally (stomach volumes, endogenous secretions, gastric emptying half-time, etc.) in order to recover a better picture of all the results and validate the model predictions against the literature. It even appears that our simulations of gastric emptying and aminoacidemia superimpose very well with previously published data obtained using similar matrices and the same mini-pig species. This study shows that the great differences in the kinetics of amino acid absorption that were observed experimentally can be fully understood by considering the behaviour of the dairy matrices within the stomach. It therefore offers interesting perspectives for the integration of food structure parameters, and more particularly for dairy products, in the comprehensive view of the nutritional quality of food products.

Mathematical modelling of milk proteins digestion dynamics

Abstract The objective of this study is to better understand and model the effect of dairy matrix structure on the hydrolysis and transit rates of milk proteins during digestion. 2 dairy matrices having a similar composition but differing by their internal structure were manufactured: one solution and one acid gel which both contained a small amount of Cr-EDTA complex, a non-absorbable and non-hydrolysable water soluble marker. These matrices were given to six adult mini-pigs and, for each experiment, 9 samples were collected after the pylori, i.e. at the stomach exit. The first sample was collected before the meal and the 8 others at different times after the meal ingestion. Effluents were analysed to determine their residual concentration in milk proteins (β-lactoglobulin and caseins) and the Cr2+ concentration. A mathematical model describing the gastric emptying of Cr-EDTA and these proteins, as well as hydrolysis for proteins, is presented. This model provides a good fitting of the Cr-EDTA and proteins concentrations and allows estimating several unknown digestion parameters with a good accuracy.