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Lactose-free products are more susceptible to chemical and physical modifications during heating and storage, due to the release of glucose and galactose during enzymatic processing, both more reactive than lactose. The present study demonstrates the effect of enzymatic lactose hydrolysis on 5-hydroxymethylfurfural (HMF), whey protein nitrogen index (WPNI) and lactulose used as thermal markers for UHT milk process monitoring. Six milk leading brands which provided regular and lactose-free UHT milk were selected, giving a total of 12 UHT milk samples analyzed in authentic duplicates. learn more All lactose-free samples showed high levels of HMF index (42.15 µmol L-1, against 13.11 µmol L-1 for regular samples) and low lactulose contents (13.03 mg 100 mL-1, against 35.59 mg 100 mL-1 of regular ones). High variations in HMF (55-85%) and lactulose (42-91%) intra-brand analysis indicated that both markers are influenced by the lactose hydrolysis process. The paired t test indicated there was no difference among WPNI indexes of regular and lactose-free milks suggesting that this thermal marker is suitable to infer about heat damage in lactose-free dairy matrices.Microencapsulated α-tocopherol and wheat germ oil (WGO) were incorporated as WGO (5.0 ml) in liquid WGO-L, encapsulated WGO-E, encapsulated α-tocopherol as E1, E2 and E3 at 2.0, 3.0 and 4.0 g respectively in cookies and evaluated for physical, sensory and shelf life parameters. Spread ratio was decreased, whereas hardness was increased with encapsulated formulations and observed least in WGO-L (40.52 N) formulated cookies. During storage moisture content was observed increased (2.51-4.78%), vitamin E was retained in all formulations except WGO-L and was found maximum in E3 (4.45 mg/100 g) formulated cookies. Formulations brought the peroxide value to nil, free fatty acid development was very less, better antioxidant activity (41.1% maximum), total plate count was observed least in E3 (25 × 102 cfu/g) and good sensory acceptance of cookies up to 4 months of storage. The study concluded that encapsulated vitamin E elevated the antioxidant activity and consequently shelf life and nutritive value of cookies.In this research, the dough rheological properties of wheat flour mixed with defatted edible J. curcas flour to improve protein content in cookies were study. The wheat and J. curcas mix proportions were 1000 (CT, control), 955% (T-5), 9010% (T-10), 8515% (T-15), 8020% (T-20). The dough variables responds were strength, toughness, extensibility, tenacity extensibility index, water adsorption, development time, weakening grade, and mix tolerance index. In cookies, the physicochemical and hedonic characteristic were quantified. As the addition of J. curcas flour increased, the dough force and extensibility decreased up to 200.5 W × 10-4 J and 60 mm, but tenacity increased up to 16.46 mm, which in consequence increased the tenacity extensibility index in 1.75, respect to the control. Dough water adsorption and development time increased 7.62% and 1.00% while the weakening grade, mix tolerance index and stability decreased 60.17 UB, 79.2 UB and 2.1 min, respectively, when J. curcas flour was added up to 20%. In cookies water adsorption, protein, lipids and ashes increased 1.18%, 6.98%, 0.42%, 2.26%, respectively, when 20% J. curcas flour was added. The fortify cookies factor decreased 0.4 that correspond to a very good quality. The sensory evaluation indicated no differences in acceptability of fortify cookies with J. curcas flour. It can be concluded that it is suitable to mix up to 8020% wheat and J. curcas flour because the alveographic and farinographic properties were in the require range to elaborate cookies, which increased 6.98% the protein content and maintained the physicochemical and hedonic acceptance.Effect of WPC and NaCl in internal aqueous phase (W1) of W1/O/W2 type double emulsions was studied. Pre-emulsion and final emulsion were prepared using microfluidizer and Ultra-Turrax high shear mixer, respectively. The emulsions prepared using salt exhibited uniform droplet size distribution and structural integrity. WPC at 6% and NaCl at 2 or 4% levels demonstrated better sedimentation stability (> 99%) and encapsulation stability (> 95%) during preparation and storage of double emulsions. Samples without added NaCl showed poor emulsion stability and structural integrity. Higher level of WPC i.e. 8% resulted in poor stability and encapsulation efficiency of double emulsions at all salt levels. Combined use of optimum levels of WPC and NaCl along with processing interventions resulted in stable double emulsions even after storage at room temperature for 10 days. This study highlights the fact that structural integrity of internal aqueous phase (W1) depends upon presence of osmotic agent i.e. salt and stabilising proteins i.e. WPC.This study evaluated the effect of phytase treatment on the bioavailability of iron (Fe), calcium (Ca), zinc (Zn), and myo-inositol phosphate fractions in sorghum flour; and characterized its macronutrients and minerals. The proximate composition and mineral content indicated that, sorghum flour has a nutritional potential superior to wheat and maize. The results obtained in the solubility and dialysis assays indicated that, naturally occurring minerals (without phytase treatment) in sorghum flour, presented considerable bioaccessibility; reaching 32, 47 and 67% of dialyzable Fe, Zn, and Ca respectively. The use of phytase had a positive influence on the reduction of myo-inositol phosphates, mainly the IP6 fraction, present in sorghum flour samples, and an increase in the soluble percentage (Fe 52% for one sample, for Zn higher than 266%) and dialyzed minerals (Fe 7.8-150%; Zn 19.7 for one sample; and Ca 5-205%) for most samples. Therefore, the essential minerals naturally occurring in sorghum have an absorption potential; and the use of phytase reduced the IP6 fraction and improved the availability of the minerals evaluated.Pearl millet, a nutritionally remarkable cereal with a sustainable yield in the grey regions of India, is not consumed much. Consumption of Nutrition bars has gained momentum in recent years and considering this, in the present study pearl millet-based protein bars are formulated to increase its consumption rate and establish it as a reliable source of protein and other nutrients. The proximate and mineral composition of the three variants of pearl millet incorporated (25, 27.5, 30%) protein bars were analyzed using standard protocols. The acceptability of the bars was assessed using the 9-point hedonic scale among twenty panelists. The textural parameters were measured by Perten TVT 6700 Texture Analyzer. The in-vitro digestibility of protein (IVPD) and starch (IVSD) of the best variant was also estimated. The bars provide 15.74-18.32 g of protein, 332-379 kcal energy, 74.53-83.87 mg calcium, and 555.93-603.80 mg phosphorous per 100 g. The results showed that the organoleptic parameters of the bars were not affected by the proportion of ingredients.