A Food Matrix Triggers a Similar Allergic Immune Response in BALB/c Mice Sensitized with Native, Denatured, and Digested Ovalbumin.

The search for an animal model to evaluate the allergenic potential of processed food products is still ongoing. Both the sensitization to ovalbumin (OVA) in different structural states and the allergic response triggered after intragastric or food challenges were assessed. BALB/c mice were sensitized intraperitoneally to OVA (50 µg) in different structural states (native OVA, N-OVA; denatured OVA, D-OVA; formaldehyde- and lysine-treated OVA, FK-OVA; denatured OVA-FK, OVA-DFK; peptides from pepsin digestion, Pep-OVA). Anti-OVA-specific IgE responses were evaluated using ELISA. Anaphylactic signs and mMCP-1 serum levels were evaluated after intragastric (2.0 mg/OVA) and food (0.41 mg/OVA) challenges. IgE reactivities to N-OVA and D-OVA were similar among groups (p > 0.05). After the challenges, all OVA-sensitized mice developed mild to severe anaphylactic signs (p < 0.05 vs. control). Mice sensitized to N-OVA and D-OVA had the highest mMCP-1 serum levels after challenges (p < 0.05 vs. control). Allergic responses were similar despite the different OVA doses used for the challenges. The N-OVA-sensitized murine model of egg allergy proposed in the present study holds the potential for evaluating the impact of food matrix composition and processing on the threshold of egg-allergic responses.

Removal of Cadmium from Aqueous Solutions by Saccharomyces cerevisiae-Alginate System.

The aim of this study was to determine the Cd2+ removal capacity of a biosorbent system formed by Saccharomyces cerevisiae in calcium alginate beads. The adsorption of Cd2+ by a S. cerevisiae-alginate system was tested either by batch or fixed-bed column experiments. The S. cerevisiae-alginate system was characterized using dynamic light scattering (DLS, zeta potential), size, hardness, scanning electron microscopy (SEM), and Fourier-transform infrared spectroscopy. Beads of the S. cerevisiae-alginate system showed a spherical-elliptical morphology, diameter of 1.62 ± 0.02 mm, 96% moisture, negative surface charge (-29.3 ± 2.57 mV), and texture stability during storage at 4 °C for 20 days. In batch conditions, the system adsorbed 4.3 µg of Cd2+/g of yeast-alginate beads, using a Cd2+ initial concentration of 5 mg/L. Adsorption capacity increased to 15.4 µg/g in a fixed-bed column system, removing 83% of total Cd2+. In conclusion, the yeast-alginate system is an efficient option for the removal of cadmium at low concentrations in drinking water.

Pasta Enrichment with an Amaranth Hydrolysate Affects the Overall Acceptability while Maintaining Antihypertensive Properties.

BACKGROUND: Alcalase-treated amaranth proteins generate angiotensin-1-converting enzyme (ACE-1) inhibitory peptides, which could be useful for functional foods development. Our aim was to evaluate the technological, sensory, and antihypertensive properties of pasta enriched with an amaranth hydrolysate. METHODS: Pasta with 11% (A; control), 15% (B), and 20% (C) of protein content were formulated. Pastas B and C were supplemented with an alcalase-treated amaranth protein concentrate. Cooking time, cooking lost, color, and texture were assessed. An untrained panel (n = 30) evaluated sensory attributes. The antihypertensive effect was evaluated in hypertensive rats. RESULTS: The hydrolysate IC50 was 0.014 mg/mL. Optimum cooking time and cooking loss decreased in products B and C vs. A (p < 0.05). The L* values decreased in pasta C. Firmness increased in pasta C vs. A (p < 0.05). Adhesiveness was different among groups (p < 0.05). Pasta A had the highest acceptability (p < 0.05). The products B and C, and captopril (positive control) showed antihypertensive properties after 3 h of supplementation (p < 0.05). This effect remained after 7 h, 8 h, or 9 h. CONCLUSIONS: The addition of amaranth hydrolysates to pasta negatively impacts on the overall acceptability and, to a lesser extent, on pasta taste. However, it is possible to maintain the antihypertensive properties of the supplemented pasta under physiological conditions.

Mechanical, physical and microstructural properties of acetylated starch-based biocomposites reinforced with acetylated sugarcane fiber.

Fiber-reinforced starch-based biocomposites provide an environmentally friendly alternative to replace petroleum-based plastics. Nevertheless, these materials present structural stability problems owing to their hydrophilicity. Therefore, a chemical modification is usually necessary. Hence, the aim of this research is to obtain biocomposites based on acetylated corn starch (AS), acetylated sugarcane fiber (AcSF) and glycerol. Also, to assess the AcSF content (FC, 0.0-20.0%) and glycerol content (GC, 20.0-30.0%) on their physical, mechanical and microstructural properties. A single-screw extruder and central composite rotatable design were employed. Due to acetylation and possible interaction between matrix-fiber, there was an improvement in water resistance; while the mechanical properties were enhanced by increasing FC up to 12.0%. Biodegradability recorded a range of 24.2-39.3%. Microstructural analysis evidenced the extrusion process effect, chemical modification and new interactions formation. It was found that an optimum blend was of FC = 12.0% and GC = 24.0%. The acetylation of both sugarcane fiber and corn starch allowed us to obtain eco-friendly materials with good mechanical properties and water resistance.

Effect of Malting and Nixtamalization Processes on the Physicochemical Properties of Instant Extruded Corn Flour and Tortilla Quality.

This research aimed to prepare instant flour from malted and raw (un-malted) corn flours nixtamalized by the extrusion process and evaluate the effect on the physicochemical properties of tortillas prepared using these flours. White maize was malted for 24 h, dried at 50 ± 1 °C, and ground. Subsequently, 0.3 % lime and 25 or 30 % water were added to ground malted or un-malted corn, and the mixture was refrigerated (4 °C) for 12 h. These samples were nixtamalized by an extrusion process in a single screw extruder at two temperature profiles within four heating zones, TP1 (60, 60, 70, and 80 °C) and TP2 (60, 70, 80, and 90 °C), to obtain corn flour. Water was added to the extruded corn flours to make a dough, or masa, and the masa was then molded and baked to obtain tortillas. The corn flours were characterized according to their ability to absorb water and viscosity profile (RVA). The firmness and rollability after 2 and 24 h of storage were determined, and a sensory evaluation was conducted. The malted corn flour extruded with a 25 % moisture content and TP2 temperature profile yielded tortillas with the best firmness and rollability. In conclusion, the changes during the malting of corn grain and the nixtamalization by the extrusion process improved the water absorption capacity of flours and textural properties of the tortilla and produced a product with acceptable sensory properties.

Transamidation of gluten proteins during the bread-making process of wheat flour to produce breads with less immunoreactive gluten.

Due to an increasing incidence of celiac disease (CD) and other gluten-related disorders, different gluten-free breads have been developed using starches and additives as a substitute for gluten. Thus, patients miss not only the taste and aroma of wheat bread but also risk their sensitive intestines. Therefore, modifying gluten to avoid an immune response in CD and its application to baking is in progress. The aim of the study was to enzymatically modify gluten on wheat flour, during bread-making avoiding the use of additives, to reduce immunoreactivity, preserving its properties. Microbial transglutaminase (mTG) or chymotrypsin (ChT) was used to bind lysine or valine to gluten proteins in a model system. The best conditions were directly applied to wheat flour for bread-making with and without punching at 45 min. Subsequently, the rheological properties of the doughs, specific volume of the loaves, immunoreactive gluten content and modification of the extracted proteins were evaluated. ChT-treated breads presented a better appearance with a more homogeneous crumb, higher specific volume values (3.34-4.25 cm(3) g(-1)) and higher reactive gluten reduction (up to 71%) than the mTG-treated ones (1.23-2.66 cm(3) g(-1)) with only a 42% reactive gluten reduction. Thus, transpeptidation during bread-making is a promising technology, although it is necessary to improve the modification process to obtain the reactive gluten reduction required in breads for the treatment of CD patients and other gluten-related disorders.

Development and evaluation of a nutritionally enhanced multigrain tortilla snack.

An increased consumption of healthy foods to reduce chronic diseases risks is needed. We developed and evaluated a multigrain snack as a nutritive alternative to the highly consumed corn tortilla chips. Corn, wheat, and chickpea grains were boiled in 1% calcium oxide solution, steeped, washed, and ground before being mixed with soy protein isolate and oat flour to prepare the multigrain masa. Multigrain tortillas were moulded, baked, dried, and fried. Proximate composition, dietary fiber, protein quality, sensorial, and textural properties were evaluated. A commercial tortilla chip was used as control. The multigrain snack contained 153% more protein, 53% more dietary fiber, and 43 % less fat than commercial tortilla chips. Its lysine and isoleucine contents helped to increase the corrected-net protein utilization by 10%, while digestibility increased from 83.5 to 91.8% as compared to commercial tortilla chips. The mean breaking force was 6,082 g for the multigrain snack and 4,780 g for the commercial tortilla chips. The mean acceptability score for the multigrain snack was 12.1 (unstructured line scale 0-15 cm), and 82% of the panelists rated the snack as acceptable. In conclusion, a nutritionally enhanced multigrain tortilla snack was developed which provides significantly more dietary fiber and protein and less fat than traditional commercial corn tortilla chips, but with comparable appearance and high acceptability.

Estimated glycemic index and dietary fiber content of cookies elaborated with extruded wheat bran.

The increasing demand for high-fiber products has favored the design of numerous bakery products rich in fiber such as bread, cookies, and cakes. The objective of this study was to evaluate the dietary fiber and estimated glycemic index of cookies containing extruded wheat bran. Wheat bran was subjected to extrusion process under three temperature profiles: TP1;(60, 75, 85 and 100 °C), TP2;(60, 80, 100 and 120 °C), and TP3;(60, 80, 110 and 140 °C) and three moisture contents: (15, 23, and 31 %). Cookies were elaborated using extruded wheat bran (30 %), separated into two fractions (coarse and fine). The dietary fiber content of cookies elaborated with extruded wheat bran was higher than the controls; C0 (100 % wheat flour) and C1 (30 % of no extruded bran coarse fraction) and C2 (30 % of no extruded bran fine fraction). The higher values of dietary fiber were observed on cookies from treatments 5 (TP1, 31 % moisture content and coarse fraction) and 11 (TP2, 31 % moisture content and coarse fraction). The estimated glycemic index of cookies ranged from 68.54 to 80.16. The dietary fiber content of cookies was increased and the lowest glycemic index corresponded to the cookies elaborated with extruded wheat bran. Cookie made with the treatment 11 had a better dietary fiber content and lower estimated glycemic index.

Formulación y elaboración de pastelillos tipo brownies con más fibra y menos calorías que los convencionales

Se prepararon distintas formulaciones para pastelillos de chocolate (brownies) sustituyendo 15, 20 y 25% de la harina de trigo con inulina. Se evaluaron las características del batido de cada una de las formulaciones y se sometieron al proceso de horneado a 175 oC por 45 min. Después del horneado, los brownies se dejaron enfriar por 1 h y posteriormente se empacaron en charolas de poliestireno cristal y se les evaluó textura a los 1, 3, 7 y 15 días de almacenamiento a temperatura ambiente (25 oC) y 65% de humedad relativa. En base a las evaluaciones del batido y a las propiedades texturales de los brownies durante el almacenamiento, se seleccionó la formulación con 20% inulina como la mejor. Se analizó composición proximal y cuantificó fibra dietética total, soluble e insoluble, tanto al brownie control y al de 20% de inulina, como a un brownie comercial. El brownie con 20% de inulina presentó menor firmeza, gomosidad y masticabilidad que el control, mayor contenido de proteína y menor contenido de grasa (6,3 vs 26,3%) y aporte calórico (331,4 vs 467,9 kcal/100 g) con respecto al brownie comercial. El brownie con 20% de inulina mostró el doble de fibra dietética total y 22 veces más fibra soluble que el brownie control. La aceptabilidad del brownie con 20% inulina fue similar a la del brownie control. La incorporación de inulina en la elaboración de brownies permitió reducir el aporte calórico y aumentar el contenido de fibra soluble, sin afectar adversamente la textura de los pastelillos.

Formulation and elaboration of lowenergy and high fiber-containing brownies. Different formulations for chocolate pastries making (brownies) were prepared by substituting 15, 20, and 25% of the wheat flour by inulin. The batter characteristics of each formulation were evaluated and the batters were baked at 175 oC for 15 min. After baking, the brownies were allowed to cool, put into crystal polystyrene trays, and their texture after 1, 3, 7, and 15 days of storage at room temperature (25 oC) and 65% of relative humidity, was evaluated. Based on the evaluations of batter characteristics and brownies textural properties during storage, the formulation containing 20% of inulin was the best. Proximate analysis was determined, and total, soluble and insoluble dietary fiber were quantified for brownies control and 20% inulin ones, as well as commercial brownies. The brownies containing 20% inulin showed lower firmness, gumminess, and masticability than the control and higher protein and lower fat content (6,3 vs 26,3%) and caloric value (331,4 vs 467.9 kcal/100 g) in comparison to the commercial brownies. The brownie with 20% inulin had twice the total dietary fiber and 22 times more soluble fiber than the brownie control. The acceptability of the brownie with 20% inulin was similar to that of the control. The incorporation of inulin in the production of brownies allowed to reduce the caloric value and to increase the soluble fiber content without adverse effects in texture of the pastries.

[Formulation and elaboration of low-energy and high fiber-containing brownies]. / Formulación y elaboración de pastelillos tipo brownies con más fibra y menos calorías que los convencionales.

Different formulations for chocolate pastries making (brownies) were prepared by substituting 15, 20, and 25% of the wheat flour by inulin. The batter characteristics of each formulation were evaluated and the batters were baked at 175 degrees C for 15 min. After baking, the brownies were allowed to cool, put into crystal polystyrene trays, and their texture after 1, 3, 7, and 15 days of storage at room temperature (25 degrees C) and 65% of relative humidity, was evaluated. Based on the evaluations of batter characteristics and brownies textural properties during storage, the formulation containing 20% of inulin was the best. Proximate analysis was determined, and total, soluble and insoluble dietary fiber were quantified for brownies control and 20% inulin ones, as well as commercial brownies. The brownies containing 20% inulin showed lower firmness, gumminess, and masticability than the control and higher protein and lower fat content (6,3 vs 26,3%) and caloric value (331,4 vs 467.9 kcal/100 g) in comparison to the commercial brownies. The brownie with 20% inulin had twice the total dietary fiber and 22 times more soluble fiber than the brownie control. The acceptability of the brownie with 20% inulin was similar to that of the control. The incorporation of inulin in the production of brownies allowed to reduce the caloric value and to increase the soluble fiber content without adverse effects in texture of the pastries.

Gluten-free breads and cookies of raw and popped amaranth flours with attractive technological and nutritional qualities.

Gluten-free bakery foodstuffs are a challenge for technologists and nutritionists since alternative ingredients used in their formulations have poor functional and nutritional properties. Therefore, gluten-free bread and cookies using raw and popped amaranth, a grain with high quality nutrients and promising functional properties, were formulated looking for the best combinations. The best formulation for bread included 60-70% popped amaranth flour and 30-40% raw amaranth flour which produced loaves with homogeneous crumb and higher specific volume (3.5 ml/g) than with other gluten-free breads. The best cookies recipe had 20% of popped amaranth flour and 13% of whole-grain popped amaranth. The expansion factor was similar to starch-based controls and the hardness was similar (10.88 N) to other gluten-free cookies. Gluten content of the final products was around 12 ppm. The functionality of amaranth-based doughs was acceptable although hydrocolloids were not added and the final gluten-free products had a high nutritional value.