Fabrication of flavour oil high internal phase emulsions by casein/pectin hybrid particles: 3D printing performance.

In this study, three-dimensional (3D) printable oil/water (O/W) high-internal-phase emulsions (HIPEs) (internal phase fraction = 75%) were fabricated using casein (3% w/v)/pectin (1-5% w/v) hybrid particles with flavour oil. The morphologies of the HIPEs, revealed by confocal laser scanning microscopy (CLSM) and cryo-scanning electron microscopy (cryo-SEM), indicated that the casein/pectin hybrid particles were mainly distributed on the interface of oil droplets. Additionally, the results of rheological and gel-strength measurements indicated that the viscosity (ranging from 1316.51-0.21 to 4301.84-0.79 Pa.s) of HIPEs increased with increasing pectin content (from 0% to 4% w/v), and the gel strength of printed HIPEs increased (from 10.37 to 21.19 g) with increasing pectin (from 1% to 5% w/v). The developed HIPEs were applied for 3D printing and the thus-printed objects could adequately maintain the designed shape and structure. The developed 3D printable HIPEs have excellent potential applications in the food, medical, and cosmetic industries.

Dispersive solid-phase extraction and dispersive liquid-liquid microextraction for the determination of flavor enhancers in ready-to-eat seafood by HPLC-PDA.

The dispersion solid-phase microextraction (DSPE) combined with dispersion liquid-liquid microextraction (DLLME) was developed as a rapid, simple and effective pretreatment method for the determination of flavor enhancers (maltol, ethyl maltol, vanillin, methyl vanillin, ethyl vanillin) of ready-to-eat seafood products (dried squid, baked squid, fried fish, steamed abalone). Under the optimized DSPE-DLLME method, the developed method exhibited low limits of quantitation (0.20-0.50 µg g-1) and excellent linearity (R2 ≥ 0.995). The recoveries of flavor enhancers in the actual samples were 83.7%-114.9%. Compared with traditional pretreatment methods, the developed DSPE-DLLME method was rapid (17 min) and easy to determine the flavor enhancers by high performance liquid chromatography with photodiode array detector (HPLC-PDA). In the actual samples, creamy compounds such as vanillin, methyl vanillin and ethyl vanillin were hardly found. However, the flavor compounds produced by thermal reactions such as maltol (except for dried squid 3) and ethyl maltol were present in all samples.

Ultrasound pre-fractured casein and in-situ formation of high internal phase emulsions.

Traditional preparation of protein particles is usually complex and tedious, which is a major issue in the development of Pickering high internal phase emulsions (HIPEs). In this study, a facile and in-situ method for the preparation of food-grade Pickering HIPEs was developed using ultrasound pre-fractured casein flocs. The ultrasonic-treated casein protein and resulting Pickering HIPEs were characterised using particle size distribution, confocal laser scanning microscopy (CLSM), cryo-SEM, and rheological measurement. The results indicated that pH values of casein and ultrasonic power level were key parameters for casein protein dispersion into nanoparticles to form o/w Pickering HIPEs. In optimal conditions, the hexagons of emulsion droplets were close together, and the emulsions formed with ultrasonic caseins exhibited gel-like behaviour. Additionally, ultrasonic microscale-sized caseins (about 25 µm) disappeared upon the use of high speed homogenisation during the formation of HIPEs, while the chemical distribution revealed by confocal laser scanning microscopy indicated that the dispersive nanoparticles from casein proteins were evidently absorbed on the interface of HIPEs (cryo-SEM). These findings prove that ultrasound is an effective tool to loosen casein flocs to induce the in-situ formation of stabilised Pickering HIPEs. Overall, this work provides a green and facile route to convert edible oil into a soft solid, which has great potential for applications in biomedical materials, 3D printing technology, and various cosmetics.