Optimization Method of Whole Wheat Flour, Soybean Flour, Oyster Meat Powder for Nutrient- Dense Composite Flour

Aim: To study the production of Nutrient – Dense Composite Flour from the blends of whole wheat flour, soybean flour (full fat) and oyster meat powder. Study Design: The study was design using the D-optimal combination design of Response Surface Methodology (RSM). Place and Duration of Study: The study was carried out at Department of Food, Nutrition and Home Science, University of Port Harcourt (Processing of raw materials) and the Department of Food Technology, Federal Institute of industrial research Oshodi, Lagos (Analysis of raw materials) between October 2021 and August 2022. Methodology: The raw materials were each processed to have wholesome flours, and then they were combined according to the matrix generated, which had ranges of 70 – 100%, 0 – 22%, and 0 – 8% for whole wheat flour (WWF), soybean flour (SBF) and oyster meat powder (OMP) respectively. Results: The design was used to assess the significance (5% probability) of the moisture, fat, and protein content, which ranged from 8.09 to 11.37%, 1.80 to 8.52% and 9.70 to 19.07% respectively; the water absorption (72.00 - 79.10BU), dough stability (9.3 - 17.5BU) and mixing tolerance index (25 - 50BU); and lightness and yellowness, which ranged from 65.48 - 83.2 and 13.77 - 23.58 respectively, of the flour blends. Protein content, water absorption dough stability, and mixing tolerance index were prioritized while moisture content, fat content, and yellowness were minimized for the numerical optimization of the responses. This study highlights the possibilities of utilizing non-conventional raw materials in the production of composite flour with balance nutritional and baking qualities. Conclusion: The best flour combination was 72.51% whole wheat flour, 19.63% soybean flour, and 7.86% oyster meat powder.

Some Quality Attributes of Composite Flour and Bread Produced from Wheat and African Walnut

This study explored the potential of African walnut in the formulation of composite flour which can be used for bread production and in various food applications. African walnut flour was produced and used to substitute wheat flour at different levels (5 - 25%) in the production of wheat-African walnut composite flour. Functional and pasting properties of the composite flour were evaluated using standard procedures. Proximate composition, antioxidant activity, some loaf quality attributes and sensory acceptability of bread produced from the composite flour were evaluated using standard procedures. Wheat bread served as control. The composite flour showed varying functional properties which ranged from 2.43 to 3.46 (swelling capacity), 1.15 to 1.85 mL/g (water absorption capacity), 2.15 to 2.75 mL/g (oil absorption capacity), 10.80 to16.60% (foam capacity), 63.0 to 75.0% (dispersibility), 38.92 to 69.92 seconds (wetability), 0.75 to 0.79 g/mL (packed bulk density) and 0.43 to 0.47 g/mL (loose bulk density). Inclusion of African walnut reduced peak viscosity (53.92 – 148.83 RVU), trough viscosity (52.25 – 88.58 RVU), breakdown viscosity (1.67 – 60.25 RVU), final viscosity (74.08 – 191.25 RVU) and setback viscosity (21.83 – 102.67 RVU) of the composite flour. Composite bread had better protein (9.75 – 16.93%), fat (3.42 – 9.94%), ash (1.46 – 2.75%), crude fibre (0.86 – 3.64%) but reduced specific loaf volume (2.36 – 4.18 cm3/g) and loaf height (3.00 – 5.40cm) than the control, and exhibited appreciable antioxidant activity (DPPH: 31.60 – 73.09% and FRAP: 0.51 - 4.25 mg/g). In term of sensory acceptability composite bread samples produced with 5 and 10 % levels of African walnut compared favourably with bread produced from wheat flour. Thus composite flour produced from wheat and African walnut flours showed an array of physicochemical properties which could make it useful in different food applications. Acceptable bread could be produced from wheat flour substituted with African walnut flour at 10% level.

Potentials of Cassava, Bambara Groundnut and Tigernut in Biscuit Production: A Review

Due to varying changes in lifestyle, economic level and urbanization in the developing countries, the consumption of biscuit and the development of food products using composite flour have increased and are attracting much attention from researchers in bakery and pastry productions. This work reviewed the potentials of cassava, bambara groundnut and tigernut composite flours in biscuit production. This study also includes studies on the use of flours from other tubers, legumes, cereals, and fruit sources in place of wheat flour to make a variety of food products in varying amounts. It was revealed that flour made from cassava, bambara groundnut and tigernut used to produce biscuit products has the capacity of maintaining similar characteristics to products made from full-wheat flour. The finished result demonstrates the cumulative impact of this option in terms of its functional and physicochemical features, as well as the health advantages of raw mixed flour and percentage blending. In addition, composite flour is an excellent new strategy for employing unusual food products becaue its use produced goods with a range of qualities and features, depending on the types and proportions of wheat flour used in the formulation. Also this review stated some possible challenges likely to be encountered in case Nigeria changes from use of wheat flour to composite flours and blends of non-wheat flours.

Production and Quality Assessment of Biscuit from Acha Flour Supplemented with Pigeon Pea

This research work evaluates the production of biscuits from blends of acha and pigeon pea flour. Acha and pigeon pea flour were blended in the ratio 95:5, 90:10, 85:15, 80:20 and 100:0 (control) to produce biscuits. Biscuits made from this blend were analyzed for proximate analysis, antinutrient composition, physical attributes, and sensory qualities. The moisture, protein, fat, crude fiber, ash, and carbohydrate content of the biscuits ranged from 7.87-9.84%, 7.36-8.14%, 21.99-26.33%, 0.39-0.59%, 0.87-1.24%, and 58.06-63.01%, respectively. The antinutrient composition varied from 4.24-6.82% for tannin and 3.85-4.68% for phytate. The physical attributes of the biscuits ranged from 8.34-10.98 g, 0.56-0.85 cm, 4.77-5.03, 5.99-8.59 for weight, thickness, diameter and spread ratio, respectively. The sensory evaluation showed that the biscuit sample with the blend ratio of 95% and 5% (acha to pigeon pea flour) was the most acceptable because it gave the best colour, appearance, crispness and overall acceptability. The result shows that acceptable biscuits with improved nutritional attributes can be produced from the blend of acha and pigeon pea flour. This will eliminate or reduce the problems associated with protein-energy malnutrition common in most local communities, and reduce wheat importation, thereby increasing the use of the most underutilized sources of flour in most developing countries.

Quality Characteristics of Bread Produced from Wheat and White Kidney Bean Composite Flour

Aim: To evaluate the Quality characteristics of Bread produced from Wheat and Kidney Bean composite flour blend. Study Design: Composite bread was produced from wheat and kidney bean flour of various proportions (10, 15, 20 and 25%). Proximate (protein, ash, moisture, fibre, fat and carbohydrate) composition, functional (Bulk density, foaming capacity, swelling index, water absorption capacity and oil absorption capacity) properties and sensory (appearance, taste, flavour, texture and overall acceptability) attributes were determined. Results: Bread was produced from wheat and kidney beans composite (B, C, D and E) flour. The bread samples were subjected to physical, proximate and sensory analyses. The functional properties of the composite flour blends were also determined. The functional properties shows a significant (P<0.05) difference in water absorption capacity, oil absorption capacity and swelling index with values ranged from 1.10 – 0.60 ml/g, 1.03 – 0.76 ml/g and 5.92 – 2.89 ml/g respectively. The bulk density and foaming capacity shows significant (P<0.05) difference with its values ranging from 0.90 – 0.97 g/ml and 32.69 – 26.94 cm3 respectively as kidney beans flour increases. The result of the physical properties shows significant (P<0.05) difference in dough height, proofing rate, loaf volume, specific volume, baking loss and oven spring with values ranging from 1.169 – 3.39 cm3, 0.01 – 0.02 cm3/min, 0.79 – 1.19 cm3, 0.32 – 0.48 cm3/g, 1.59 – 2.79 and 101.58 – 102.79 respectively while the loaf weight ranged from 243.21 – 246.09 g. proximate composition of the sample were also analyzed and the result shows significant (P<0.05) difference in crude protein, moisture content, ash, crude fat, crude fibre and carbohydrate with values ranging from 8.36 – 10.47%, 22.18 – 23.28%, 0.97 – 1.38%, 11.80 – 12.94%, 0.29 – 0.59% and 51.33 – 57.10% respectively. The results of the sensory scores shows a significant (P<0.05) difference in all the samples analyzed. However, sample C with 15% kidney beans flour was most preferred. Conclusion: It could be concluded that increased in kidney beans flour addition in the production of composite bread had significant (P<0.05) impact on the proximate, physical and organoleptic properties of the bread. Hence, 85% wheat to 15% kidney bean flour should be used in bread making.

Development and Evaluation of Amaranth-Soy-Wheat Composite Flours

Aims: Malnutrition among all ages is still a persistent problem in India, especially in areas where the poor largely depend on rice and wheat staples with limited access to diverse diets using underutilized foods. This study was conducted to nutritionally enhance traditional food products like roti and lapsi utilizing suitable composite flours based on amaranth, soybean and wheat without affecting their sensory quality. Study Design: Different combinations of amaranth, soybean and wheat flours were made to suit the quality characteristics of roti and lapsi. Place and Duration of Study: Department of Foods and Nutrition, G. B. Pant University of Agriculture & Technology, Pantnagar (India), between January and June 2016. Methodology: The sensory evaluation of food products and estimation of nutritional composition of composite flours was done using standard procedures. Results: The composite flours having 25% amaranth, 15% soybean and 60% wheat flour and 25% amaranth, 10% soybean and 65% wheat flour were found to be most acceptable sensorially and were significantly superior to their control counterparts for protein, ash, fibre, carbohydrate calcium and iron content (p=.05). Conclusion: Roti made from amaranth and soybean incorporated composite flours with better protein quality and low available carbohydrates and physiological energy almost same as control would be better diet alternative to diabetic and overweight patients whereas lapsi may be effectively used as supplementary food. Many other traditional food products like laddoo, halwa, puri, parantha, burfi etc. may also be made from such composite flours.

Análisis proximal, de textura y aceptación de las galletas de trigo, sorgo y frijol / Nutritional, texture and sensory profile of cookies from wheat, sorghum and bean

Las galletas son actualmente productos de gran demanda, constituyendo un sector sustancial de la industria alimentaria. Considerando la importancia de la buena alimentación y la oportunidad de incorporar leguminosas a productos de panificación como alternativa saludable logrando un mejor balance proteico, se planteó la propuesta de elaborar galletas a base de harina de trigo, sorgo y frijol. El objetivo del presente trabajo fue elaborar y evaluar galletas de harina de trigo sustituidas al 10%, 30% y 100% de harina de sorgo y frijol. Se diseñaron tres formulaciones para la elaboración de galletas al 10%, 30%, 100% de harina de sorgo y harina de frijol y la muestra control 100% trigo. Se realizó la evaluación proximal y perfil instrumental de textura a cada uno de las formulaciones; así mismo, el análisis sensorial para evaluar los atributos de color, olor, sabor y textura por medio de una escala hedónica de siete puntos. El reemplazo parcial de trigo por sorgo 10% - 30% y frijol al 10% fueron las formulaciones más acertadas con un porcentaje promedio de proteínas de 19 a 23%, además de presentar una alta puntuación en la evaluación sensorial. Estas combinaciones de harinas podrían ser utilizadas por la industria alimentaria para producir galletas de buena calidad nutricional, con características físicas y sensoriales aceptables para la población en general(AU)

Nowadays, cookies are in a real high demand, constituting a substantial sector of the food industry. Considering the importance of a good nutrition and the opportunity to incorporate legumes into baking products as a healthy alternative achieving a better protein balance, it was made a proposal to make cookies based on wheat flour, sorghum and beans. The objective of the current work was to elaborate and evaluate wheat flour cookies substituted to 10%, 30% and a 100% of sorghum and bean flour. Three formulations were prepared for the making of the cookies at 10%, 30% and a 100% of sorghum and bean flour and the control sample at a 100% of wheat. The proximal evaluation was made to each of the treatments, as well as the sensorial analysis for the evaluation of color attributes, odor, taste and texture through a hedonic scale of 7 points. The partial replacement of wheat by sorghum 10% - 30% and 10% of bean were the most successful formulations with a protein percentage average of 19 to 23% besides presenting a high score in sensory evaluation. These flour combinations could be used in the food industry for the making of cookies with a well nutritional quality, with physical and sensory qualities acceptable for the general population(AU)