This study aimed to develop texture-modified Dongchimi (TMD) that is safe, well-shaped, and easy to chew and swallow. As the fermentation proceeded, the pH decreased, and the total acidity and total number of lactic acid bacteria increased. The hardness of the TMD decreased significantly by more than 96% (p \ 0.05) as compared to that of the control. Significant differences in the hardness and shape were observed between two TMD samples-TMD 1 and TMD 2. Sensory evaluation showed that TMD 1 and TMD 2 were adequate for the elderly people suffering from difficulties in mastication and deglutition. Compared to TMD 1, TMD 2 showed higher values of hardness and swallowness and was more preferred by the elderly. Thus, TMD that is easy to chew and swallow has sufficient competitiveness in food safety, food taste, and food preference.
Cholecalciferol, also known as vitamin D3, is a recognized therapeutic agent for treatment of bone diseases and cancer. However, instability and poor bioavailability have been major challenges for delivering Vitamin D3. The objective of this study was to formulate improved nanostructured lipid carrier (NLC) vitamin D3 emulsions. We tested the effect of different carrier oils and the use of a solid lipid nanoparticle emulsifier, polyglycerol polyricinoleate (PGPR) on the stability of the vitamin D3 emulsions. In contrast to the control that used glyceryl monostearate (GMS) the PGPR substitution resulted in relatively small particle sizes (0.30 to 0.43 μm), with high absolute value of zeta potentials (39.5 to 67.8 mV) and high encapsulation efficiency (85.2% to 90.4%). The stability of the NLC emulsions against environmental stresses was evaluated under varying conditions of ionic strength, pH, freeze–thaw cycles, and storage at different temperatures. Although NLC emulsions were stable at high ionic strengths, they were found to be unstable at low pH (<3), which led to aggregation and coalescence of emulsion droplets. In case of freeze–thaw stress, although relatively stable compared to control NLC, the PGPR substituted groups exhibited a slight increase in particle size and a decrease in zeta potential when the cycle was repeated five times. Additionally, we found that PGPR‐substituted emulsions showed higher liquid dispersion stability than controls at 25 and 65 °C. Thus, we have formulated a modified NLC vitamin D3 emulsion that can be widely used in the food industry. Practical Application Vitamin D3, an essential micronutrient, is often added as supplements in food products and beverages for added health benefits. However, the stability of vitamin D3 emulsions that are used in the preparation of such products has been a major concern. We have developed a modified emulsion that has improved stability against environmental stresses. We believe, in future, this formulation can be efficiently used in the food industry.
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