Cereal Chem. 84(3):207-213Wheat flours commercially produced at 74, 80, and 100% extraction rates made from hard white winter wheat (WWF) and hard red winter wheat (WRF) were used to produce tortillas at a commercial-scale level. Flour characteristics for moisture, dry gluten, protein, ash, sedimentation volume, falling number, starch damage, and particle-size distribution were obtained. Farinograms and alveograms were also obtained for flourwater dough. A typical northern Mexican formula was used in the laboratory to test the tortilla-making properties of the flours. Then commercialscale tortilla-baking trials were run on each flour. The baked tortillas were stored at room and refrigeration temperatures for 0, 1, 2, and 3 days. Maximum stress and rollability were measured every day. Tortilla moisture, color, diameter, weight, and thickness were measured for each treatment.Finally, tortilla acceptability was tested by an untrained sensory panel. Analyses of variance (ANOVA) were performed on the data. WWF had higher protein content, dry gluten, sedimentation volume, and water absorption than the WRF. The WWF was the strongest flour based on farinograph development time and alveograph deformation work. It also produced the most extensible dough measured with the alveograph (P/L). Flour protein and ash contents, water absorption, and tenacity increased directly with the flour extraction rate. Both WWF and WRF performed well in commercial-scale baking trials of tortillas. Tortillas made with both types of flours at 74 and 80% extraction rates had the best firmness and rollability. However, tortillas made with WWF 80% had the best color (highest L value). Tortillas prepared with 100% extraction rate flour were also well accepted by the sensory panel, had good textural characteristics, and became only slightly firm and slightly less rollable after three days of storage at room temperature.
Microbial transglutaminase (MTGase), a protein‐glutamine γ‐glutamyl transferase (E.C. 2.3.2.13), catalyzes acyl transfer reactions by introducing a covalent cross‐link between l‐lysine and l‐glutamine residues. The use of this enzyme has been proposed as an improver to increase dough strength. The objective of this study was to assess and compare the effect of MTGase on different fractions of dough proteins found in hard, soft, and durum wheat. Three different concentrations of the MTGase (0, 5, and 10U/g of gluten) were tested. Moisture, protein, and dry gluten contents were determined for each concentration in addition to rheological measurements done with the farinograph. Following each treatment, the dough proteins were extracted and analyzed by SE‐HPLC and RP‐HPLC. Soluble polymeric protein, gliadins, albumins, and globulins were quantified in addition to the gliadin subclasses and glutenin subunit types. The combustion procedure was used to determine the amount of insoluble polymeric protein. Differences were observed in susceptibility to MTGase catalysis among the dough proteins of the cultivars studied: the cultivar Cortazar (soft wheat) was the most susceptible. The proteins of this cultivar had a characteristically higher amount of ω and α+β gliadins when compared with the other cultivars. As reported earlier, solubility of high molecular weight glutenin subunits and ω‐gliadins was reduced because of the MTGase treatment. However, all gliadin subclasses, including the γ and α+β gliadins, also participated in cross‐linking. The proteins of the cultivar Altar (durum wheat) were the least susceptible to the effects of MTGase. Albumins and globulins did not show any reduction in solubility, implying that they did not participate in cross‐linking.
The extrusion process allows the production of nixtamalized corn flour rich in arabinoxylans, which help to prevent cardiovascular and intestinal diseases. During extrusion, physiochemical properties of nixtamalized corn flour are negatively modified. The use of enzymes such as xylanase in order to obtain nixtamalized corn flour using extrusion has been studied as an alternative to reduce these changes in corn flour tortilla. The aim of this research was to evaluate changes in protein solubility of extruded nixtamalized corn flour with and without different concentrations of xylanase enzyme (0.05, 0.075, and 0.1%, w/w). Soluble proteins of each corn flour were extracted and analyzed by SE-HPLC, while insoluble proteins were determined by the combustion method. In addition, each corn flour was analyzed by scanning electron microscopy (SEM). Results showed that the extruded nixtamalized corn flour, with and without xylanase, increased the protein solubility, and this effect was lower in extruded nixtamalized corn flour with xylanase. Insoluble protein diminished in corn flours either with or without xylanase enzyme. The addition of xylanase reduces the effect that the extrusion process has on the solubility proteins of extruded nixtamalized corn flour.
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