RESUMO
The need to improve the physicochemical properties of sea buckthorn juice and the bioavailability of carotenoids is a major challenge for the field. The effects of different natural emulsifiers, such as medium-chain triglycerides (MCTs), tea saponins (TSs) and rhamnolipids (Rha), on the physical and chemical indexes of sea buckthorn juice were studied. The particle size of sea buckthorn juice and the carotenoids content were used as indicators for evaluation. The effects of different addition levels of MCT, Rha and TS on the bioavailability of carotenoids in sea buckthorn juice were investigated by simulating human in vitro digestion tests. The results showed that those emulsifiers, MCT, Rha and TS, can significantly reduce the particle size and particle size distribution of sea buckthorn juice, improve the color, increase the soluble solids content, turbidity and physical stability and protect the carotenoids from degradation. When the addition amount of Rha was 1.5%, the total carotenoids content (TCC) of sea buckthorn juice increased by 45.20%; when the addition amount of TS was 1.5%, the total carotenoids content (TCC) of sea buckthorn juice increased by 37.95%. Furthermore, the bioaccessibility of carotenoids was increased from 36.90 ± 2.57% to 54.23 ± 4.17% and 61.51 ± 4.65% through in vitro digestion by Rha and TS addition, respectively. However, the total carotenoids content (TCC) of sea buckthorn juice and bioaccessibility were not significantly different with the addition of MCT. In conclusion, the findings of this study demonstrate the potential of natural emulsifiers, such as MCT, Rha and TS, to significantly enhance the physicochemical properties and bioavailability of carotenoids in sea buckthorn juice, offering promising opportunities for the development of functional beverages with improved nutritional benefits.
RESUMO
Zein and hyaluronic acid (HA) composite nanoparticles were self-assembly fabricated using antisolvent coprecipitation (ASCP) method to deliver quercetagetin (Que). FTIR, CD, and FS results revealed that electrostatic attraction, hydrogen bonding, and hydrophobic effect were the dominant driving forces among zein, Que, and HA. With the increasing of HA level, the morphological structure of zein-Que-HA complex was changed from nanoparticle (from 100:5:5 to 100:5:20) to microgel (from 100:5:25 to 100:5:30). The encapsulation efficiency of Que has significantly increased from 55.66% (zein-Que, 100:5) to 93.22% (zein-Que-HA, 100:5:20), and Que in the zein-Que-HA composite nanoparticles exhibited obviously enhanced photochemical, thermal, and physical stability. After 8 months of storage (4 °C), the retention rate of Que also up to 77.93%. These findings interpreted that zein-HA composite nanoparticle would be an efficient delivery system for encapsulating and protecting bioactive compounds.
