沙棘果肉油微胶囊的制备、表征及模拟胃肠道消化:壁材和界面双层稳定化的影响
Fabrication, characterization and simulated gastrointestinal digestion of sea buckthorn pulp oil microcapsule: effect of wall material and interfacial bilayer stabilization.
作者信息
Bai Ge, Zhao Man, Chen Xiao-Wei, Ma Chuan-Guo, Ma Yan, Xianqing Huang
机构信息
College of Food Science and Technology, Henan Agricultural University, Zhengzhou, People's Republic of China.
Lipid Technology and Engineering, College of Food Science and Engineering, Henan University of Technology, Zhengzhou, People's Republic of China.
出版信息
J Sci Food Agric. 2025 Feb;105(3):1737-1744. doi: 10.1002/jsfa.13950. Epub 2024 Oct 10.
BACKGROUND
Sea buckthorn (Hippophae rhamnoides L.) pulp oil is rich in functional components; however, low water solubility and stability limit its applications. This study fabricated sea buckthorn pulp oil microcapsules using whey protein isolate (WPI), soy protein isolate (SPI), sodium caseinate (NaCN), gum arabic (GA), starch sodium octenylsuccinate (OSAS) and SPI mixed with chitosan (CHI). The influences of these wall materials on physicochemical properties, release behavior and digestibility were explored.
RESULTS
Protein-based wall materials (WPI, NaCN, SPI) demonstrated lower bulk densities due to their porous structures and larger particle sizes, while GA and OSAS produced denser microcapsules. Encapsulation efficiency was the highest for protein-based microcapsules (79.41-89.12%) and the lowest for GA and OSAS. The surface oil percentage of protein-based microcapsules (1.41-4.40%) was lower than that of the other microcapsules. Protein-based microcapsules showed concave and cracked surfaces, while GA and OSAS microcapsules were spherical and smooth. CHI improved reconstitution performance, leading to faster dissolution. During simulated gastrointestinal digestion, protein-based microcapsules released more free fatty acids (FFAs) in the intestinal phase, while CHI-modified SPI microcapsules showed a delayed release pattern due to thicker walls.
CONCLUSION
Protein-based wall materials were more effective for sea buckthorn pulp oil microencapsulation, providing higher encapsulation efficiency, better flow properties and releasing more FFAs. The addition of CHI led to the layer-by-layer self-assembly of the microcapsule wall and resulted in sustained release during in vitro intestinal digestion. These findings suggested the potential of protein-based microcapsules for targeted delivery and improved applications of bioactive oils in the food industry. © 2024 Society of Chemical Industry.
背景
沙棘(沙棘属)果肉油富含功能成分;然而,低水溶性和稳定性限制了其应用。本研究使用乳清蛋白分离物(WPI)、大豆蛋白分离物(SPI)、酪蛋白酸钠(NaCN)、阿拉伯胶(GA)、辛烯基琥珀酸淀粉钠(OSAS)以及与壳聚糖(CHI)混合的SPI制备了沙棘果肉油微胶囊。探讨了这些壁材对其理化性质、释放行为和消化率的影响。
结果
基于蛋白质的壁材(WPI、NaCN、SPI)由于其多孔结构和较大粒径,表现出较低的堆积密度,而GA和OSAS制备的微胶囊密度更高。基于蛋白质的微胶囊的包封效率最高(79.41 - 89.12%),而GA和OSAS的最低。基于蛋白质的微胶囊的表面油含量(1.41 - 4.40%)低于其他微胶囊。基于蛋白质的微胶囊表面呈凹陷和开裂状,而GA和OSAS微胶囊呈球形且表面光滑。CHI改善了复水性,导致溶解更快。在模拟胃肠道消化过程中,基于蛋白质的微胶囊在肠道阶段释放更多游离脂肪酸(FFA),而CHI改性的SPI微胶囊由于壁更厚呈现出延迟释放模式。
结论
基于蛋白质的壁材对沙棘果肉油微胶囊化更有效,具有更高的包封效率、更好的流动性能并释放更多FFA。CHI的添加导致微胶囊壁的逐层自组装,并在体外肠道消化过程中实现缓释。这些发现表明基于蛋白质的微胶囊在食品工业中用于生物活性油的靶向递送和改进应用方面具有潜力。© 2024化学工业协会
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