409 research outputs found
Uptake and Digestion
Uptake relates to the term bioaccessibility, which is the fraction of a dose that is potentially available for absorption or uptake after digestion. Transcellular uptake can take place via two modes of transport: active and passive. The process of evaluation of digestion and uptake of bio-nanosystems in food containing bioactive compounds starts with the modeling of in vivo characteristics by using in vitro methods. Interactions within the food matrix before and after intake need further understanding to unravel the fate during digestion and absorption. The availability of the interior network for the incorporation of bioactive compounds can potentially increase uptake, absorption, and bioavailability. The rate and extent of lipid digestion also depends on other initial parameters, such as the emulsifier type, oil type and oil content used, and stability under gastrointestinal conditions. The emulsifier type can also have an impact on the interfacial stability upon digestion and permeability across the intestinal barrier
Permeability of the small intestinal mucus for physiologically relevant studies: Impact of mucus location and ex vivo treatment
The small intestinal mucus is a complex colloidal system that coats the intestinal mucosa. It allows passage on nutrients/pharmaceuticals from the gut lumen towards the epithelium, whilst preventing it from direct contact with luminal microorganisms. Mucus collected from intestinal tissue is often used in studies looking at inter-mucosal transport of food particulates, drug carriers, etc. However, detaching the highly hydrated native mucus from the tissue and storing it frozen prior to use may disrupt its physiological microstructure, and thus selective barrier properties. Multiple-particle tracking experiments showed that microstructural organisation of native, jejunal mucus depends on its spatial location in the intestinal mucosa. The inter-villus mucus was less heterogeneous than the mucus covering villi tips in the pig model used. Collecting mucus from tissue and subjecting it to freezing and thawing did not significantly affect (P > 0.05) its permeability to model, sub-micron sized particles, and the microviscosity profile of the mucus reflected the overall profiles recorded for the native mucus in the tissue. This implies the method of collecting and storing mucus is a reliable ex vivo treatment for the convenient planning and performing of mucus-permeability studies that aim to mimic physiological conditions of the transport of molecules/particles in native mucus
Almond Allergy: An Overview on Prevalence, Thresholds, Regulations and Allergen Detection
Food allergy has been on the increase for many years. The prevalence of allergy to different foods varies widely depending on type of food, frequency of consumption and geographic location. Data from the literature suggests that the prevalence of tree nut allergy is of the order of 1% in the general population. Almond is one such tree nut that is frequently eaten in many parts of the world and represents a potential allergenic hazard. Given the need to label products that contain allergens, a number of different methods of direct and indirect detection have been developed. However, in the absence of population-based threshold data, and given that almond allergy is rare, the sensitivity of the required detection is unknown and thus aims as low as possible. Typically, this is less than 1 ppm, which matches the thresholds that have been shown for other allergens. This review highlights the lack of quantitative data on prevalence and thresholds for almonds, which is limiting progress in consumer protection
In silico trials of food digestion and absorption: how far are we?
In recent years, experimental research on the mechanisms of food digestion in the gastrointestinal tract has strengthened our knowledge on the effect of food on human health. A number of mathematical models have been proposed to rationalize our understanding on the related mechanisms. One common suggestion is that in silico models could be interconnected and used in the future to predict the effect of food systems (liquid or solid, inner microstructure, state of nutrients…) on various metabolic responses. This paper aims to provide a brief overview of the latest developments in this young but promising field of research
Calcium Alters the Interfacial Organization of Hydrolyzed Lipids during Intestinal Digestion
Calcium plays an important dual role in lipid digestion: promoting removal of long-chain fatty acids from the oil–water interface by forming insoluble calcium soaps while also limiting their bioaccessibility. This becomes more significant in food containing high calcium concentration, such as dairy products. Nevertheless, scarce attention has been paid to the effect of calcium on the interfacial properties during lipid digestion, despite this being largely an interfacial reaction. This study focused on the dynamics of the formation of calcium soaps at the oil–water interface during lipolysis by pancreatic lipase in the absence and presence of the two primary human bile salts (sodium glycocholate or sodium glycochenodeoxycholate). The competitive adsorption of lipase, bile salts, and lipolysis products, as well as the formation of calcium soaps in the presence of increasing concentrations of calcium were mainly characterized by recording the interfacial tension and dilatational modulus in situ. In the absence of bile salts, calcium complexes with fatty acids at the oil–water interface forming a relatively strong viscoelastic network of calcium soaps over time. The dilatational modulus of the calcium soap network is directly related to the interfacial concentration of lipolysis products and the calcium bulk concentration. Calcium soaps are also visualized forming a continuous rough layer on the surface of oil droplets immersed in simulated intestinal aqueous phase. Despite bile salts having different surface activity, they play a similar role on the interfacial competition with lipase and lipolysis products although altering their kinetics. The presence of bile salts disrupts the network of calcium soaps, as suggested by the decrease in the dilatational modulus and the formation of calcium soap islands on the surface of the oil droplets. The accelerant effect of calcium on lipolysis is probably because of fatty acid complexation and subsequent removal from the interface rather than reduced electrostatic repulsion between lipase and bile salt molecules and promoted lipase adsorption. The work shown here has implications for the delivery of oil-soluble bioactives in the presence of calcium
Dairy structures and physiological responses: a matter of gastric digestion
Digestion and health properties of food do not solely rely on the sum of nutrients but are also influenced by food structure. Dairy products present an array of structures due to differences in the origin of milk components and the changes induced by processing. Some dairy structures have been observed to induce specific effects on digestion rates and physiological responses. However, the underlying mechanisms are not fully understood. Gastric digestion plays a key role in controlling digestion kinetics. The main objective of this review is to expose the relevance of gastric phase as the link between dairy structures and physiological responses. The focus is on human and animal studies, and physiological relevant in vitro digestion models. Data collected showed that the structure of dairy products have a profound impact on rate of nutrient bioavailability, absorption and physiological responses, suggesting gastric digestion as the main driver. Control of gastric digestion can be a tool for delivering specific rates of nutrient digestion. Therefore, the design of food structure targeting specific gastric behavior could be of great interest for particular population needs e.g. rapid nutrient digestion will benefit elderly, and slow nutrient digestion could help to enhance satiety
Protein-saliva interactions: a systematic review
Food industries are challenged to reformulate foods and beverages with higher protein contents to lower fat and sugar content. However, increasing protein concentration can reduce sensory acceptability due to astringency perception. Since the properties of food–saliva mixtures govern mouthfeel perception, understanding how saliva and protein interact is key to guide development of future protein-rich reformulations with optimal sensory attributes. Hence, this systematic review investigated protein–saliva interaction using both model and real human saliva, including a quality assessment. A literature search of five databases (Medline, Pubmed, Embase, Scopus and Web of Science) was undertaken covering the last 20 years, yielding 36 604 articles. Using pre-defined criteria, this was reduced to a set of 33 articles with bulk protein solutions (n = 17), protein-stabilized emulsions (n = 13) and protein-rich food systems (n = 4). Interaction of dairy proteins, lysozyme and gelatine with model or human saliva dominated the literature. The pH was shown to have a strong effect on electrostatic interaction of proteins with negatively-charged salivary mucins, with greater interactions occurring below the isoelectric point of proteins. The effect of protein concentration was unclear due to the limited range of concentrations being studied. Most studies employed a 1 : 1 w/w protein : saliva ratio, which is not representative of true oral conditions. The interaction between protein and saliva appears to affect mouthfeel through aggregation and increased friction. The searches identified a gap in research on plant proteins. Accurate simulation of in vivo oral conditions should clarify understanding of protein–saliva interaction and its influence on sensory perception
Microcalorimetry of the intestinal mucus: Hydrogen bonding and self-assembly of mucin
The effect of mucin hydrogen bonding on the structure of intestinal mucus has been studied with micro-differential scanning mirocalorimetry (μ-DSC), supported by spectroscopy. The experiments were performed in water–dimethyl sulfoxide (DMSO) solutions, using either water–DMSO mixtures of an appropriate DMSO content or water as blanks, as to isolate the effects of the solvent to hydrogen bonding. When using matched water–DMSO blanks, thermal events at low temperatures are linked to the negation of mucin–DMSO interactions, while events at higher temperatures are linked to the break-up of hydrogen bonds connecting the sugars of the individual macromolecules. When using a matched solvent as blank, alterations in Cp, such as increases at 10% and 15% DMSO, have been linked to the break-up and creation of quaternary structures. In the case of water as blank, a monotonic but not linear decrease in enthalpy, hence extent of hydrogen bonding, is observed. The above are complemented by UV spectroscopy: A blue shift of the conjugated aminoacids in the presence of DMSO suggests that the inherent stability of mucin is not only due to steric volume exclusions, but also due to extensive hydrogen bonding on behalf of the sugar moieties
In vitro digestibility of O/W emulsions co-ingested with complex meals: Influence of the food matrix
Oil-in-water (O/W) emulsions are promising delivery systems of lipophilic bioactive compounds into meals composed mainly of water. The colloidal stability of β-carotene-loaded O/W emulsion incorporated into whole milk, oatmeal and whole milk-oatmeal meals. Their subsequent gastric emptying rate, lipid digestibility and β-carotene retention during in vitro gastrointestinal digestion were evaluated using a semi-dynamic gastric model followed by a static small intestinal model. The dispersed particles within the meals, lipid droplets, casein micelles as well as protein and β-glucan aggregates, were responsible for the bigger average particle sizes of both O/W-oatmeal and O/W-whole milk-oatmeal (13.07 ± 1.81 and 7.60 ± 1.21 μm, respectively) compared to the O/W emulsions and O/W-whole milk (0.56 ± 0.03 and 0.44 ± 0.04 μm, respectively). Semi-dynamic in vitro gastric digestion of O/W-whole milk showed lipid droplets embedded into an insoluble protein network emptied earlier than the O/W emulsion. Conversely, O/W-oatmeal and O/W-whole milk-oatmeal had delayed lipid emptying, probably because of the gelation of the β-glucan from oats. During the in vitro small intestinal digestion, the rate of the FFA release was linked to the gastric emptying rate. Indeed, both O/W emulsion and O/W-whole milk presented an exponential increase in the FFA release, whereas the O/W-oatmeal and O/W-whole milk-oatmeal followed a stepwise trend. The β-carotene retention during in vitro gastrointestinal digestion depended on the lipid amount at each digestion time moment. Hence, this work provides valuable insight into the behaviour of O/W emulsions incorporated into meals and during their subsequent in vitro gastrointestinal digestion
Raspberry pomace alters cecal microbial activity and reduces secondary bile acids in rats fed a high-fat diet
The profile of bile acids (BA) largely depends on the enzymatic activity of the microbiota, but this can be modulated by the dietary addition of biologically active compounds, e.g., polyphenols and polyunsaturated fatty acids. The aim of this study was to examine the effect of dietary raspberry pomace as a rich source of biologically active compounds on microbial activity and the BA profile in the caecum of rats fed a high-fat diet. Wistar rats were fed the standard diet AIN-93, a high-fat diet or a modified high-fat diet enriched with 7% different types of processed raspberry pomaces produced by standard grinding and fine grinding, with or without seeds. Rats fed the high-fat diet for eight weeks showed some disorders in liver function and cecal BA, as manifested by an increased concentration of cholesterol, total BA in the liver and cholic, deoxycholic, and β-muricholic acids in the cecal digesta. In general, irrespective of the type of raspberry pomace, these dietary preparations decreased liver cholesterol, hepatic fibroblast growth factor receptor 4, peroxisome proliferator-activated receptor alpha, cecal ammonia and favorable changed BA profile in the cecum. However, among all dietary pomaces, the finely ground preparation containing seeds had the greatest beneficial effect on the caecum by modulating bacterial activity and reducing the levels of secondary BA
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