Wenchang Zhang, Shiyu Wang, Jianhua Lv, Rufei Zou, Mi Wu, Yan Zhao, Fanghao Zheng, Dongwen Liu
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引用次数: 0
Abstract
With the improvement of living standards, people are increasingly demanding a healthy diet. Some of the most popular foods with unique tastes, such as saturated and trans fatty acids, have been found to have negative effects on human health, prompting people to seek their alternatives. In this study, oleogels were prepared to replace these two kind of solid fat using chitin nanofibers, and the influence of nanofiber morphology on oleogels were systematically studied. Firstly, chitin nanofibers were prepared through dissolution, degradation and regeneration processes, and their morphology was adjusted by controlling their molecular weight. SEM and XRD showed that these regenerated nanofibers have damaged microstructure and rearranged network, exhibiting obvious larger lattice plane spacing and smaller crystallite size. Chitin nanofibers with high molecular weight (79.6 kDa) are prone to aggregating into bundles and even form membranes, while nanofibers with reduced molecular weight tend to form locally short-range networks and even aggregate into nanofiber microspheres. When these chitin nanofibers were transferred into camellia oil, they exhibited excellent gelation effects. The resulting oleogels show different rheological properties, among which the oleogel prepared by chitin nanofibers with the medium molecular weight (42.4 kDa) showed the most stable rheological properties. Even at a concentration of only 2.5%, its storage modulus (9072 Pa) and viscosity (7.98 × 105 mPa·s) were much higher than those of the 8% beeswax oleogel and the 13% stearic acid oleogel. In addition, the prepared oleogels all exhibit good thermal stability below 280 °C, and its structural transformation under shear force is independent of the concentration, and is only affected by the morphology of the nanofiber. Our study provides new opportunities for the application of solid fat substitutes in food industry.
期刊介绍:
The journal European Food Research and Technology publishes state-of-the-art research papers and review articles on fundamental and applied food research. The journal''s mission is the fast publication of high quality papers on front-line research, newest techniques and on developing trends in the following sections:
-chemistry and biochemistry-
technology and molecular biotechnology-
nutritional chemistry and toxicology-
analytical and sensory methodologies-
food physics.
Out of the scope of the journal are:
- contributions which are not of international interest or do not have a substantial impact on food sciences,
- submissions which comprise merely data collections, based on the use of routine analytical or bacteriological methods,
- contributions reporting biological or functional effects without profound chemical and/or physical structure characterization of the compound(s) under research.
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