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Enriching human food using new technology such as lipid nanocarriers is a simple and accessible tool. Accordingly, the present study aimed to evaluate the sensory and production of healthy and useful food products to evaluate the enrichment of milk with zeaxanthin lipid nanocapsules and to evaluate its cryoprotectants. During experimental-laboratory research, zeaxanthin extraction from Spirulina platensis, and nanocarriers produced for milk enrichment were used as a food model system. Three samples of milk, milk enriched with lipid nanocarriers containing zeaxanthin, and milk enriched with lipid nanocarriers were examined (at similar concentrations of nanocarriers). In order to check the efficiency of produced nanocarriers, cold protective compounds (glucose, sorbitol, glycerin, lactose, and sucrose) were added to milk. Sucrose was recognized as the best cryoprotectants. Sensory evaluation of enriched milk was performed on a five-degree hedonic scale and different sensory parameters were examined. Data were analyzed using Minitab (v. 2016). Results No significant difference was observed between the sensory characteristics of control milk and milk enriched with nanocarriers (P<0.05). The lowest particle size and dispersion index were obtained in the coating of nanocarriers with cold protective compounds, respectively, 320.82 and 0.26 to 0.31. Zeta potential was reported as -6.03. By enriching milk with zeaxanthin-containing nanocarriers, in addition to visual and skin health, problems related to the lack of useful natural additives and insolubility of food products can be eliminated.


 

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Abstract Solid lipid nanoparticles and nanostructure lipid carriers were used to entrap curcumin and broaden confined knowledge of application of nanocarriers as the functional ingredients in food sectors. The effect of lipids ratio (GDS /GMS), kind of nanocarrier (SLN and NLC) and curcumin concentration (0, 0.25 and 0. 5 % (w / w) of emulsion) on the qualitative characteristics of nanocarrier were evaluated. Based on the results the massive physical structure of Curcumin and also increases the viscosity of the material dispersed phase in the presence of active, loading Curcumin in the developed nanocarrier led to significant (p<0.05) increase in nanoparticles size. DSC analyses showed that the crystalline states of produced nanocarriers were less ordered than pure materials and indicated that the curcumin was well incorporated in lipid matrices. However, our pretest showed that concentration of 5% Glycerol distearate and 0.25% Curcumin was the optimum for the production of Solid lipid nanoparticles and nanostructure lipid carriers.