Milk whey from different animal species stimulates the in vitro release of CCK and GLP-1 through a whole simulated intestinal digestion.

Milk whey is effective in enhancing satiety mainly due to its protein composition. Peptides and amino acids derived from digestion of whey protein can act as suppressants of appetite by stimulation of receptors of satiety gut hormones. But, the protein fraction of whey can vary depending on species of animal, season, lactation period, etc. The aim of this study is to evaluate the satiety effect of milk whey from different species of ruminants (cow, sheep, goat and a mixture of them) through a simulated in vitro digestion, which performed the whole gastrointestinal process, from oral digestion to colonic fermentation. The satiety effect of each sample was measured by the production of satiating hormones (CCK and GLP-1) secreted by enteroendocrine cell line (STC-1) after 2 hours of incubation with non-digested, digested and fermented whey. Digested samples have shown to be potent CCK and GLP-1 secretagogues followed by fermented and non-digested samples, showing that the last one showed a weak hormone stimulation. Digested goat whey was the most efficient stimulator of GLP-1 (86.33 ± 4.55 pg mL-1) and fermented mixture whey produced the major release of CCK (80.78±1.81 pg mL-1). This study demonstrates that milk whey is a suitable ingredient to stimulate satiety through the effect of peptides, amino acids produced from digestion, and metabolites released by fermentation.

In vitro modulation of gut microbiota by whey protein to preserve intestinal health.

The effect of several types of whey milk - cow, sheep, goat and a mixture of them (60 : 20 : 20, respectively) - was assessed in the human gut microbiota. The prebiotic potential of these substrates was evaluated through in vitro gastrointestinal digestion following faecal batch culture fermentations (mimicking colonic fermentation) for 48 hours, using faeces from normal-weight (NW) and obese (OB) donors. Throughout the fermentation process, pH, gas production, short chain and branched fatty acids (SCFA-BCFA) were measured, as well as the changes of microbiota using qPCR. The pH decreased in all whey samples during the fermentation process. Gas production was higher in all whey samples than in controls, especially at 12 hours (p < 0.05). The diversity of SCFA and BCFA production was significantly different between the donors, in particular cow and mixed whey. Whey milk had a strong prebiotic effect on the gut microbiota of NW and OB donors, showing a significant increase of Bifidobacterium (p < 0.05) with cow, sheep and mixed whey and increase in the Lactobacillus group, particularly in OB donors. Bacteria associated with obesity did not show an increase in any of the groups of donors. Therefore, supplementing a diet with these types of whey can selectively stimulate the growth of probiotic bacteria, enhancing SCFA production, which could improve intestinal disorders. In addition, it may be an interesting approach to the prevention of overweight and obesity and related diseases. Whey milk has a potent prebiotic effect. It can selectively stimulate desirable bacteria and SCFA profile, in both OB and NW donors, contributing to improved intestinal health and reducing obesity.

Influence of the reformulation of ingredients in bakery products on healthy characteristics and acceptability of consumers.

Bakery products are highly consumed by children and adults and as cereal-derived foods are considered a fundamental part of a balanced diet, but they are usually high in sugar and saturated and trans fat and low in fibre. This study aimed to develop four different bakery products (cookies, croissants, Spanish muffins and Spanish sponge cake) with healthier properties, such as lower fat and sugar content, healthy fatty acid profile and higher fibre content. Margarine and sunflower oil were replaced with high oleic sunflower oil, and inulin was also added. After the modifications, a significant reduction of fat content and kilocalories in all cases, an increment of monounsaturated fat and a decrease in saturated fatty acids in three products were observed. The sensory analysis resulted similar results in both recipes for cookies and lower acceptability in sponge cake, croissants and muffins. Purchase intention only decreased in sponge cake.

Sodium alginate as feed additive in cultured sea bream (Sparus aurata): does it modify the quality of the flesh?

The objective of this study was to evaluate the effect of sodium alginate obtained from brown seaweed as a prebiotic supplement to the feed of reared sea bream (Sparus aurata). Addition of the alginate to a control diet was investigated at both concentrations 2% and 5%. Proximate composition in the flesh were not modified significantly by sodium alginate inclusion in the diet of the sea bream; however the fat and ash content in the specimens supplemented with 5% alginate were found to be significantly higher than those found in individuals who were fed the control diet. No significant differences in mineral content, fatty acid profiles, cholesterol content, texture parameters and sensory acceptability among the three studied groups. Results obtained in this study offer support for the use of alginate as a feed additive in sea bream diets since no significant effects were found in the flesh quality and characteristics of commercial size sea bream.

α-Lactoalbúmina como ingrediente de fórmulas infantiles

La α-lactoalbúmina es la principal proteína del lactosuero en la leche materna, alcanzando una concentración de 2,44 g/L en la leche madura. Su principal función es la síntesis de lactosa a partir de glucosa y galactosa en la glándula mamaria, aunque posee además otros efectos beneficiosos sobre la salud del lactante debido a su elevada proporción de aminoácidos esenciales (triptófano y cisteína). Según diversos estudios parece influir positivamente en la absorción de hierro en el intestino del niño, y en experimentos in vitro, unida al ácido oleico (complejo HAMLET), es efectiva frente a tumores celulares como el papiloma humano. El complejo HAMLET también presenta un claro efecto antimicrobiano frente a Streptococcus pneumoniae, Haemophilus influenzae, cepas enteropatógenas de Escherichia coli y Salmonella thypimurium, sin embargo no se ha demostrado que durante la digestión de la leche materna se forme dicho complejo en el tracto digestivo del lactante. El desarrollo de fórmulas infantiles destinadas a la alimentación del niño durante el primer año de vida ha mejorado considerablemente en las últimas décadas intentando no sólo adecuar la concentración de nutrientes a los requerimientos del lactante, sino también adicionando compuestos bioactivos de diferente naturaleza, como la α-lactoalbúmina, con el objetivo de alcanzar los efectos funcionales que se producen en los niños alimentados con leche materna.

α-Lactalbumin as an ingredient of infant formula. α-lactalbumin is the main whey protein in human milk rising 2,44 g/L in mature milk. It has a key function in the synthesis of lactose from glucose and galactose in the mammary gland although this compound has also other beneficial effects on the infant health due to the high proportion of essential aminoacids (tryptophan and cysteine). It seems also to increase iron absorption in the digestive track, and in in vitro experiments, linked to oleic acid (HAMLET complex), has shown anticarcinogenic effects against cellular tumor such as human papilloma. In addition, this complex has been reported to exhibit antimicrobial properties against Streptococcus pneumoniae,Haemophilus influenzae, enteropathogenic strains of Escherichia coli and Salmonella thypimurium. However, the in vivo synthesis of HAMLET complex during milk digestion has not been proved yet. Infant formula have been improved considerably during the last decades not only adapting nutrient concentrations to infants requirements but also by the addition of new bioactive ingredients such as α-lactalbumin, to have the same functional effect as in breast fed babies.

[Alpha-Lactalbumin as an ingredient of infant formula]. / Alpha-Lactoalbúmina como ingrediente de fórmulas infantiles.

Alpha-Lactalbumin is the main whey protein in human milk rising 2,44 g/L in mature milk. It has a key function in the synthesis of lactose from glucose and galactose in the mammary gland although this compound has also other beneficial effects on the infant health due to the high proportion of essential aminoacids (tryptophan and cysteine). It seems also to increase iron absorption in the digestive track, and in in vitro experiments, linked to oleic acid (HAMLET complex), has shown anticarcinogenic effects against cellular tumor such as human papilloma. In addition, this complex has been reported to exhibit antimicrobial properties against Streptococcus pneumoniae, Haemophilus influenzae, enteropathogenic strains of Escherichia coli and Salmonella thypimurium. However, the in vivo synthesis of HAMLET complex during milk digestion has not been proved yet. Infant formula have been improved considerably during the last decades not only adapting nutrient concentrations to infants requirements but also by the addition of new bioactive ingredients such as alpha-lactalbumin, to have the same functional effect as in breast fed babies.

Enriquecimiento en minerales y antioxidantes / No disponible

En esta ponencia se presenta, de modo general y con algunos ejemplos, la situación del enriquecimiento mineral y la optimización en el contenido en antioxidantes en los alimentos desde el punto de vista nutricional y de la salud de los consumidores, técnicas y de aseguramiento de la calidad (AU)

No disponible

Use of heme iron concentrate in the fortification of weaning foods.

The purpose of this study was to evaluate the technological feasibility of fortifying homogenized weaning food with a porcine heme concentrate. The stability of iron and the organoleptic qualities of two infant weaning foods (a commercial homogenized nonfortified weaning food, NFWF, and the same food fortified with 0.5% of porcine heme concentrate, FWF) were tested throughout 8 months of storage at room temperature and at 37 degrees C. Heme iron decreased with storage time; however, the proportion of this highly available iron was considerably higher in FWF than in NFWF. The addition of heme iron changed significantly the color of the weaning food measured instrumentally, although high temperatures and length of storage time, did not modify Lab, chroma, and hue angle values in both samples. Organoleptic attributes presented a marked stability even in NFWF stored at room temperature and 37 degrees C.