Modulating aroma release of flavour oil emulsion based on mucoadhesive property of tannic acid

Construction and controlled flavor release of high internal phase emulsion stabilized by pH-driven-assembled soy peptide nanoparticles

This study aimed to evaluate the potential of pH-driven assembled soy peptide nanoparticle (SPN) to prepare high internal phase emulsions (HIPEs) containing sweet orange essential oil (SOEO), and the effects of SPN concentration and oil phase fraction on the formation, stability and flavor release characteristics were investigated. Results showed that stable HIPEs with excellent self-supporting state were successfully fabricated at relative high SPN concentrations (0.5-3.0 wt%). And the increase in SPN concentration could cause smaller droplet size, better viscoelastic properties and stability. The flavor release of SOEO in SPN-stabilized HIPEs could be slowed down and modulated by regulating SPN concentration, and the retention of key flavor compound (d-limonene) in SOEO encapsulated in HIPEs could be reached to higher than 70 % after 120 days of storage. All these indicated the effective encapsulation and delivery of SOEO in SPN-stabilized HIPEs and their prospective application as fat substitutes in plant-based food systems.

A high molecular mass emulsifier derived from lentil seeds: The role of polysaccharide and protein in its stabilization behavior

A water-soluble lentil polysaccharide (SLPS) extract was obtained from lentil fiber, at pH 10, after heating at 120 °C for 90 min, with a recovery as high as 16.5 %. SLPS had a weight average molecular mass of 1975 kg/mol, and contained 47 % glucose, 42 % arabinose, and 7 % uronic acid. Objective of this work was to evaluate the potential of SLPS to be employed as a natural emulsifier, by measuring its interfacial properties, as well as emulsifying capacity on a model emulsion system. Acidic emulsions were prepared with 5 % oil and 5 % SLPS and their particle size distribution was evaluated by light scattering and complementary microscopy, to determine their stability. SLPS showed the ability to reduce interfacial tension at oil/water interfaces, and the emulsions were stable under acidic conditions. Two different molecular weight fractions (SLPS-H and -L were investigated), and while the high molecular weight fraction (SLPS-H; 1567 kg/mol) was effective at stabilizing interfaces, emulsions prepared with low molecular weight fraction (SLPS-L; 2.3 kg/mol) showed aggregation and coalescence of oil droplets. Addition of pectinase caused aggregation of the droplets as measured by dynamic light scattering, demonstrating that adsorbs on the surface of oil droplets, and prevents aggregation of the oil droplets.

Mucoadhesion and Mucins in Oral Processing: Their Role in Food Interaction, Texture, and Sensory Perception

This is a review of mucus, and its principal component, mucins, in oral processing; it examines oral processing from the viewpoint of mucins being integral functional constituents of the food after the latter's insertion into the mouth. Under this light, mucins are treated as an omni-present functional ingredient. The chemical physics of the bolus formation is examined, focused on the role of mucins in the process. The colloidal and rheological aspects of hydrocolloids-mucin systems are subsequently examined, highlighting the role of the oral glycoproteins in complex food models and complex foods. Following the physicochemical and mechanical description of the topic, mucus is examined as a determinant of a food's sensory attributes. Its role in oral sensations such as astringency is reviewed, with a special focus on phenol-mucin interactions. The effect of mucus on the perception of saltiness is then reviewed, and the ensuing strategies for structurally-based reduction of salt are considered. The review critically discusses the challenges and opportunities that emerge from the above, highlighting the role of mucins and their effect on food function.

Thiamine, cysteine and xylose added to the Maillard reaction of goat protein hydrolysate potentiates the formation of meat flavoring compounds

A protein hydrolysate of goat viscera added with xylose, cysteine, and thiamine under different pH was used to prepare a meat flavoring. Goat viscera hydrolysate and flavoring were subjected to analysis of physicochemical characteristics, amino acid profile, sugars, fatty acids, and volatile profile. Meat aroma characteristics were initiated in the hydrolysate, in which Strecker's pyrazines and aldehydes were identified, which also had fatty acids and amino acids available for the formation of 96 volatile compounds in the flavorings via lipid manipulation, Maillard occurrence, Strecker manipulation and interactions among these means. Maillard reaction products with intense meat aroma, such as 2-methyl-3-furanthiol, 2-furfurylthiol and, bis(2-methyl-3-furyl) disulfide were isolated only in the flavoring at pH 4. In contrast, the flavoring at pH 6 showed a higher concentration than all the other compounds, providing a lower meat characteristic, but an intense sweet, fatty and goat aroma.

Effects of steam explosion-modified rice bran dietary fiber on volatile flavor compounds retention and release of red date-flavored naan (ethnic specialty food of Xinjiang) during storage

This study explored the effects of steam explosion-modified rice bran dietary fiber (S-RBDF) on red date-flavored naan quality and flavor characteristics. The results revealed that the rheological properties of the dough were improved with the incremental addition of S-RBDF (0-5%). The microstructure revealed that adding an appropriate amount of S-RBDF (1-5%) enabled more starch granules to be embedded in the dough network. Notably, the addition of 5% S-RBDF resulted in naan with an optimum specific volume and texture, which consumers preferred. Additionally, gas chromatography-mass spectrometry analysis showed that adding S-RBDF to naan contributed to the retention and sustained release of pleasant volatile compounds (e.g. red date flavor, etc.), while inhibiting the development of unpleasant volatile compounds by delaying the oxidation and decomposition of lipids and preserving the antioxidant phenolic compounds, thus contributing to flavor maintenance of naan during storage. Overall, these results provided a foundation for developing high-quality flavored naan.

The application of encapsulation technology in the food Industry: Classifications, recent Advances, and perspectives

Encapsulation technology has been extensively used to enhance the stability, specificity, and bioavailability of essential food ingredients. Additionally, it plays a vital role in improving product quality and reducing production costs. This study presents a comprehensive classification of encapsulation techniques based on the state of different cores (solid, liquid, and gaseous) and offers a detailed description and analysis of these encapsulation methods. Specifically, it introduces the diverse applications of encapsulation technology in food, encompassing areas such as antioxidant, protein activity, physical stability, controlled release, delivery, antibacterial, and probiotics. The potential impact of encapsulation technology is expected to make encapsulation technology a major process and research hotspot in the food industry. Future research directions include applications of encapsulation for enzymes, microencapsulation of biosensors, and novel technologies such as self-assembly. This study provides a valuable theoretical reference for the in-depth research and wide application of encapsulation technology in the food industry.

Evaluation of the Long-Lasting Flavour Perception after the Consumption of Wines Treated with Different Types of Oenological Additives Considering Individual 6-n-Propylthiouracil Taster Status

Due to the limited scientific knowledge on the impact of commercial oenological additives on flavour perception, the aim of this work was to evaluate the effect of different types of oenological additives on the long-lasting flavour perception (flavour persistence) during wine tasting, also considering the effect of the individual PROP (6-n-propylthiouracil) taster status (PTS). To do so, white and red wines with two oenotannins (ellagitannin and gallotannin) and a commercial yeast mannoprotein were prepared. A control wine of each type was also made without additives. All the wines were spiked with a mixture of aromatic compounds responsible for the "fruity" and "woody" notes. Retronasal aroma and astringency were evaluated at the same time using time-intensity (TI) methodology and a trained panel (n = 40), including PROP non-tasters (NTs) and tasters (Ts). The results showed a significant effect of PTS on the long-lasting perception of astringency, being Ts who showed higher values than NTs for most TI parameters. However, PTS did not affect aroma persistence. In addition, the three oenological additives had an effect on astringency and retronasal aroma perception. They significantly increased the long-lasting perception of astringency compared to the control, while gallotannin also increased the persistence of the woody aroma.