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Folic acid is one of the essential vitamins that deficiency of it causes congenital malformations in pregnant, especially neural tube disorders. Since the human body cannot synthesize this vitamin, enrichment process on bread that is known as one of the most widely consumed foods in the diet of our people, can be on an effective step for eliminating defects caused by vitamin’s deficiency in people. Considering the health effects of wheat bran and and the presence of folic acid in it, in this study attempts to fortify flour (with 7% wheat bran) by 100% RDI folic acid and then measuring the stability of folic acid in bread making process by HPLC method and microbiological assay. The results indicated that the microbiological assay showed higher amount than the high performance liquid chromatography method because of the ability to measure the natural folate in the samples. Also, during the bread making process, the folic acid and folate content increased during the fermentation process and then decreased by the thermal baking process. The remaining amount of folic acid and folate in the final bread showed the relatively high resistance of this vitamin in the process of Barbariʼs bread, and thus the ability of the bread fortification process to provide folic acid requirements in adults.

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Co-encapsulation of Lactobacillus acidophilus and Tuna oil rich in omega-3 fatty acids using Soy protein isolate (SPI) and Arabic gum (GA) as wall materials was studied through the complex coacervation method. The microcapsules were dried separately by freeze and spray drying. The optimal conditions for the coacervation between soybean protein isolate and gum Arabic as functions of pH, SPI/GA ratio and total concentration of biopolymers were investigated using zeta potential, turbidity, and coacervation yield assays. The highest coacervate yield was achieved in the total concentration of biopolymers 2% (w/v), SPI/GA ratio 60:40 and pH=4, and the highest coacervation yield was 79.22±1.75%. Lactobacillus acidophilus (La-5) viability was significantly (p˂0.05) higher in freeze-dried microcapsules in comparison with spray-dried microcapsules. Omega-3 fatty oil improved significantly (p˂0.05) the viability of probiotic bacteria during 60 days storage in ambient temperature and gastrointestinal conditions. The size of L. acidophilius containing microcapsules and co-microcapsules (SPI-P-O-GA) were 1.19±0.19 and 4.42±0.14 µm, respectively.