Colloidal Nanoparticles Isolated from Duck Soup Exhibit Antioxidant Effect on Macrophages and Enterocytes

Absorption and transport mechanism of colloidal nanoparticles (CNPs) in lamb soup based on Caco-2 cell

Soup is an important presence in diet, but its absorption and transport mechanism by the human body remains unclear. In this study, Caco-2 intact cell and monolayer cell models were constructed to simulate small intestine absorption on colloidal nanoparticles (CNPs) isolated from lamb soup. The intracellular localization of CNPs was viewed by laser confocal microscopy (LSCM). CNPs uptake and release pathways were explored by differences in CNPs concentrations in 5 endocytosis inhibitor models and 4 exocytosis inhibitor models. Results indicated that CNPs endocytosis by Caco-2 cells was restrained by Nystatin and Cytochalasin D, with exocytosis being inhibited by Nocodazole and Monensin. Therefore, the major absorption pathways for CNPs were caveolin-dependent endocytosis, macropinocytosis and phagocytosis. The major transport pathways were microtubule-vesicle-mediated protein transport to the membrane and transportation between the Golgi apparatus and membrane. This study may provide theoretical support for the transport mechanism of soup products in the small intestine.

Implementing a food first strategy can transform preventive healthcare

The Food-First Strategy advocates seeking a nutritional solution for the prevention and treatment of disease before resorting to supplements or therapeutic agents. Advances in knowledge of nutrition at the cellular level are providing information on how micronutrients are incorporated into cells and how they exert their actions. Micronutrients, in the form of naturally occurring nanoparticles, are more bioavailable and also act as antioxidants to tackle inflammation and promote cellular regeneration and repair. They are the new "superheroes of nutrition" and an understanding of their metabolic impact can explain and support associated health claims.

Why are clams steamed with wine in Mediterranean cuisine?

Wine is renowned for its rich content of polyphenols, including resveratrol (Res), known for their health promoting properties. Steamed clam with wine, a popular Mediterranean delicacy that highlights the role of wine as a key ingredient. However, despite these benefits, resveratrol's low bioavailability poses challenges. Could the process of steaming together with clam alter the digestive fate of resveratrol from wine? This study explores the potential of proteoglycan-based nanoparticles from freshwater clam (CFNPs) as a delivery vehicle for enhancing the stability and bioavailability of resveratrol, compared with wine and free Res' solution, aiming to elucidate mechanisms facilitating Res' absorption. The results demonstrated that CFNPs can effectively encapsulate Res with an efficiency over 70%, leading to a uniform particle size of 70.5±0.1 nm (PDI < 0.2). Resveratrol loaded in CFNPs (CFNPs-Res) exhibited an improved antioxidant stability under various conditions, retaining over 90% of antioxidant capacity after three-day storage at room temperature. The controlled-release profile of Res loaded in CFNPs fits both first and Higuchi order kinetics and was more desirable than that of wine and the free Res. Examined by the simulated gastrointestinal digestion, CFNPs-Res showed a significantly higher bioaccessibility and antioxidant retention compared to free Res and the wines. The discovery and use of food derived nanoparticles to carry micronutrients and antioxidants could lead to a shift in functional food design and nutritional advice, advocating much more attention on these entities over solely conventional molecules.

Changes in physicochemical properties and formation process of colloidal nanoparticles (CNPs) during the lamb soup stewing

Colloidal nanoparticles (CNPs), as carriers of nutrients, naturally exist in food or form during cooking. In this study, the colloidal properties, structures, rheological properties, and chemical composition location of CNPs were analyzed during 15 min to 5 h lamb soup stewing. With the increasing stewing time, the particle size and absolute value of the zeta potential of CNPs increased, indicating that CNPs became more stable. As the stewing time increased, the blue-shifted Fourier transform infrared spectroscopy absorption peaks and the red-shifted fluorescence spectroscopy absorption peaks certificated the structural changes in CNPs. And α-helix and β-turn content decreased, while β-sheet and random coil content increased in processing, potentially resulting in the opening CNPs structures. In addition, our findings revealed that proteins were encapsulated within the lipids in the inner part, while carbohydrates were dispersed in the outermost layers of the CNPs with a phospholipid bilayer.

Investigation into the characteristic volatile flavor of old duck

In order to explore the characteristic aroma flavor and its formation mechanism of old ducks, two ages (30 days and 60 days) of young ducks and three ages of old ducks (300 days, 900 days, and 1500 days) were selected and studied. An electronic nose was applied to evaluate the overall aroma flavor, and the result showed significant differences between the five duck samples. By gas chromatography-mass spectrometry (GC-MS), forty-eight volatile flavor compounds were detected, including seven aldehydes, six esters, five alcohols, five nitrogen compounds, twenty-one hydrocarbons, and four others. Among these compounds, twelve components, such as hexanal and dimethyl anthranilate, were considered as the characteristic flavor compounds along with duck aging. Furthermore, correlation analysis indicated that meat's unsaturated free fatty acids, especially linoleic acid (C18:2), were responsible for the duck's characteristic flavor formation. These data contribute to the flavor research and identification of old ducks.