Gluten proteins, representing the major protein fraction of the starchy endosperm, are predominantly responsible for the unique position of wheat amongst cereals. These form a continuous proteinaceous matrix in the cells of the mature dry grain and form a continuous viscoelastic network during the mixing process of dough development. These viscoelastic properties underline the utilization of wheat to prepare bread and other wheat flour based foodstuffs. One group of gluten proteins is glutenin, which consists of high molecular weight (HMW) and low molecular weight (LMW) subunits. The HMW glutenin subunits (HMW-GS) are particularly important for determining dough elasticity. The common wheat possesses 3 to 5 HMW subunits encoded at the Glu-1 loci on the long arms of group 1 chromosomes (1A, 1B, and 1D). The presence of certain HMW subunits is positively correlated with good bread-making quality. Glutamine-rich repetitive sequences that comprise the central part of the HMW subunits are actually responsible for the elastic properties due to extensive arrays of interchain hydrogen bonds. Genetic engineering can be used to manipulate the amount and composition of the HMW subunits, leading to either increased dough strength or more drastic changes in gluten structure and properties.
Transesterification of palm olein with glycerol can increase the functionality by introducing additional hydroxyl groups to the triglyceride structure, an advantage compared to using palm olein directly as feedstock for producing palm-based polyol. The objective of this study was to synthesize transesterified palm olein-based polyol via a three-step reaction: (1) transesterification of palm olein, (2) epoxidation and (3) epoxide ring opening. Transesterification of palm olein yielded approximately 78 % monoglyceride and has an hydroxyl value of approximately 164 mg KOH g−1. The effect of formic acid and hydrogen peroxide concentrations on the epoxidation reaction was studied. The relationships between epoxide ring-opening reaction time and residual oxirane oxygen content and hydroxyl value were monitored. The synthesized transesterified palm olein-based polyol has hydroxyl value between 300 and 330 mg KOH g−1 and average molecular weight between 1,000 and 1,100 Da. On the basis of the hydroxyl value and average molecular weight of the polyol, the transesterified palm olein-based polyol is suitable for producing rigid polyurethane foam, which can be designed to exhibit desirable properties. Rigid polyurethane foams were synthesized by substituting a portion of petroleum-based polyol with the transesterified palm olein-based polyol. It was observed that by increasing the amount of transesterified palm olein-based polyol, the core density and compressive strength were reduced but at the same time the insulation properties of the rigid polyurethane foam were improved.
Pumpkin is an important vegetable, which has potential to be used as medicinal and functional food. Not only the pulp but also the peel and seeds of pumpkin are good sources of phytochemicals and minerals. Pumpkin peel, flesh, and seeds were dried to obtain powders, and 80% of methanolic extracts were prepared for further analyses. Among three fractions of pumpkin, higher content of total phenolics (224.61 ± 1.60‐mg GAE/100‐g powder) and total flavonoids (139.37 ± 1.07‐mg CE/100‐g powder) were recorded in pumpkin seeds as compared with peel and flesh, whereas higher carotenoids (35.2 ± 0.49 mg/100‐g powder) and β‐carotene (6.18 ± 0.04 mg/100‐g powder) were present in pumpkin flesh extract, when compared with peel and seeds. Pumpkin flesh, as compared with peel and seeds, contained higher values of Na, K, and Fe (17.87 ± 0.22, 1592 ± 20.3, and 41.50 ± 0.45 mg/100‐g powder, respectively). Valuable amount of Zn (15.21 ± 0.07 mg/100‐g powder) was present in pumpkin seeds powder. Practical applications Pumpkin parts (peel, flesh, and seeds) own high nutritional significance due to the presence of total phenolics, flavonoids, total carotenoids, and appreciable amount of macroelements and microelements. Organic waste generated as a result of pumpkin processing could effectively be utilized in different food products for the development of functional and medicinal foods. Notably, pumpkin seeds are high in zinc content, and in this situation of COVID‐19 pandemic, scientific community is well aware of oxidation and mediating role of zinc for activation of enzymes in the body. Phytochemicals present in pumpkin peel, flesh, and seeds can fight against antiaging and enhance immunity. These low‐cost powders from pumpkin parts can be used as a potential source of functional foods and nutraceuticals in food and medicinal industries.
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