Proximate composition, pasting and functional properties of composite flour blends from cassava and chia seeds flour

The study established the proximate composition, pasting, and functional properties of cassava flour (CF) blended with chia seeds flour (CSF). Composite flour was prepared by blending CF with CSF in the ratios of 95:05, 90:10, 85:15, 80:20, and 75:25 with CF and CSF used as controls, respectively. The effect of blending significantly (p < 0.05) increased protein, fat, fibre, and ash contents as CSF increased. On other hand, moisture and carbohydrate contents decreased significantly. Pasting properties of composite flour blends decreased significantly (p < 0.05) as the incorporation of CSF increased and a noticeable change was observed for composite flour (75:25) except for peak time and pasting temperature. Functional properties of water absorption capacity (WAC) of CSF were significantly different with CF and composite flour blends. Oil absorption capacity (OAC) of CF and CSF were significantly different, while the composite flour blends had varied OAC due to the inclusion of the different amounts of CSF. The swelling capacity (SC) of CF and CSF were not significantly different, but composite flour blends were significantly different from both CSF and CF. The least gelation concentration (LGC) and bulk density (BD) increased significantly as chia seeds increased. Increased concentration of chia CSF in the composite flour blends showed to alter the functional properties. This study recommends composite flour 75:25 for processing semiliquid products like porridge due to reduced pasting properties values that may be associated with increased energy density compared to CF.

Quality evaluation of powdered ogi produced from maize-sorghum and soybean flour blends in Nigeria

Ogi is a fermented cereal porridge usually made from single cereals such as maize (Zea mays). In traditional production, it is sometimes combined with other cereals such as sorghum or millet. It is usually in semi-solid form after production and has low shelf stability. This study was carried out to produce and evaluate the quality of ogi powder from mixtures of selected cereals (maize and sorghum), with soybean inclusion as advancement for improving the nutritive value of the product. Ogi flour was obtained from grains of maize and sorghum by weighing, sorting, soaking (for 72 hours), wet milling, sieving, dewatering, oven-drying, pulverizing and sieving through muslin cloth with maximum pore size of 20 mm. Optimal blend (70:30) for maize - sorghum ogi cumulating to 100% maize - sorghum mixture was obtained from a preliminary study; and fortified with soybean in the ratios of 90:10, 80:20, 70:30, 60:40, 50:50, and 100:0. The samples were analyzed for functional, proximate and micronutrient properties using standard methods. Results of water absorption and swelling capacity showed significant (p<0.05) differences among the samples. Proximate composition results showed significant (p<0.05) differences in all samples and ranged as follows: moisture (5.39 - 7.72%), protein (6.22 - 21. 46%), ash (2.66 - 3.64%), crude fibre (2.22 - 2.65%), crude fat (4.22 - 10.22%) and carbohydrate (51.31 - 79.14%). The micronutrient levels were improved and ranged from 166 - 360 mg/100g calcium, 1.15 - 3.22 mg/100g iron, 24.3 - 47.6 IU ß-carotene and 0.59 - 0.89 mg/100g thiamine. Soybean addition generally improved the quality of the samples. Protein increase was observed from 20% inclusion of soybean. The maximum inclusion level of 50% increased the protein content of the sample to 21.5%. Despite adding value and variety to ogi meal due to its powdered form, fortifying maize-sorghum ogi with soybean would reduce the problem of malnutrition especially among children who are usually fed ogi as infant formulae in developing countries.

Proximate composition and sensory characteristics of refractance window dried cowpea composite porridges

Undernutrition is a major public health concern in Uganda. Locally available nutrient dense diets can help reduce the problem of undernutrition. Utilisation of cowpea leaf powder in preparing composite porridge blends depends on sensory acceptance of the consumers. A Nutrisurvey software was used to formulate two composite flour blends, namely maize and millet in a ratio 2:8 and cowpea-maize in a ratio of 1:9 to achieve the daily requirement of protein for children. The study developed a process for the production of composite cowpea flour from finger millet flour and maize flour and followed a one factor design in which maize flour (MF) and millet flour (MMF) was substituted with cowpea leaves flour (CPL). The composites were dried using refractance window drying technology. The proximate composition of the composite flours were determined using standard methods while sensory acceptability of porridges was rated on a five-point Likert scale using an untrained panel. Results indicated a significant (p < 0.05) increase in protein (10.9 to 13.4%), dietary fibre (11.01 to 13.0%) and lipids (4.71 to 5.3%) contents for cowpea-millet composite porridge. For cowpea-maize composite flour, a significant (p < 0.05) increase in protein (5.9 to 7.6%), dietary fibre (1.47 to 3.3%) and lipids (2.84 to 3.3%) was also observed. Sensory evaluation indicated that between the two composite porridges, the cowpea-millet porridge blend was significantly (P≤0.05) more appealing in terms of colour (3.61±0.8), aroma (2.96±0.2), taste (3.24±0.6), texture (3.62±0.6) and general acceptability (3.61±0.8) to the panellists than the cowpea-maize porridge blend. The cowpea-millet and cowpea-maize composite flours can contribute more than 100% of the recommended dietary allowance of protein and carbohydrate requirements for children aged 0-8 years. The study findings indicate that the cowpea-based composite flours have the potential to make a significant contribution to the improvement in the nutritional status of infants and children in developing countries.

Enrichment of Fermented Sorghum Flour with Pumpkin Pulp and Seed for Production of A Vitamin A and Iron Enhanced Supplementary Food

Vitamin A and iron deficiencies are prevalent in preschool children being a public health concern. The study aimed at developing a flour blend formulation made of sorghum, pumpkin pulp and seeds and examining its contribution to the daily nutrient requirement for iron and vitamin A among preschool children. Three flour blends were formulated using a mixture of fermented sorghum flour, pumpkin seed flour and pumpkin pulp flour with the following ratios 80:10:10 (FP1), 70:15:15 (FP2) and 60:20:20 (FP3), respectively whereas control was made of 100% fermented sorghum flour. The flour blends and the control were analyzed for moisture content, protein, crude fiber, crude fat, ash, carbohydrate, beta-carotene and iron content. Further, sensory tests were conducted using a nine-hedonic scale to evaluate consumers acceptability of porridge made of the flour samples. Microbial analysis was conducted to establish the safety of developed flours. The results show that as the proportion of pumpkin pulp and pumpkin seed flours increased the protein content, ash, vitamin A and iron content significantly (P&lt;0.05) increased. The flour blend FP3 recorded the highest amount of protein (22.87%), vitamin A (875.00 &micro;g RAE/100g) and iron (27.51 mg/100g). The FP2 flour blend was the most preferred with sensory score of 7.91 and had ability to meet &gt;70% of daily protein, iron and vitamin A requirements of preschool children thus most suitable for a feeding trial. The findings of this study demonstrate that pumpkin pulp and pumpkin seed can be used to enhance the nutritive value of sorghum and as such meet the protein, iron and vitamin A requirements of preschool children aiding in the eradication of nutritional deficiencies.

Exploring the possibilities of some selected flour blends for the development of bakery products: Comparison with some physicochemical and functional properties of wheat flour

This study explored the possibilities of some selected flour blends vis-a-vis the physicochemical and functional properties of wheat flour. Ten flour blends from potato starch, cassava, maize and soybean flours and wheat flour were made and evaluated for physicochemical, functional and anti-nutritional properties. The range of proximate values were for moisture (3.76%–6.67%), protein (4.33–8.96%), ash (1.35–1.96%), fat (3.37–4.88%), fibre (1.22–1.89%) and carbohydrate (78.35–84.94%), whereas wheat flour had moisture (9.45%), protein (11.31%), ash (2.54%), fat (3.78%), fibre (1.31%) and carbohydrate (73.90%). Cyanogenic glucoside, saponion and tannin contents increased with increase substitution of cassava and soybean flours. Pasting temperatures of flour blends ranged from 69.03°C to 78.83°C, while wheat flour had 78.05°C. Peak, hot paste, breakdown, setback and cold paste viscosities were 1514–2822, 1036–1597, 487–1225, 580–884 and 1616–2461 cp in flour blends compared to 2361, 1360, 1001, 1079 and 2439 cp of wheat flour. Substitutions with soy flour decreased the peak, hot paste, breakdown and cold paste viscosities but increased the pasting temperatures. L*, a* and b* values ranged from 78.56 to 87.65, −0.34 to 0.71 and 10. 95 to 13.50 in flour blends while the wheat flour varied significantly at 2361.00, 1360.00 and 1001.00. The nutritional and pasting properties of some of flour blends were closely related to wheat flour and may be used for bakery requirements.

Plantain based dough meal: nutritional property, antioxidant activity and dyslipidemia ameliorating potential in high-fat induced rats

Abstracts Background Dyslipidemia is an aberrant rise in blood lipids due to diet and lifestyle. It has implicated as the major risk factor for developing hypertension among other diseases. This study was designed to evaluate plantain based dough meal nutritional property, antioxidant activity and dyslipidemia ameliorating potential in high-fat induced rats. Methods The flour blends, i.e., PSC (Plantain 70%, Soycake 30%), PSR (Plantain 65%, Soycake 30%, Rice-bran 5%), PSO (Plantain 65%, Soycake 30%, Oat-bran 5%), PSRO (Plantain 60%, Soycake 30%, Rice-bran 5%, Oat-bran 5%) and controls (100% Plantain flour & Cerolina) were evaluated for chemical, antioxidants and antihyperlipidemia. Results Protein, fiber and energy composition varied from 2.2–4.97 g/100 g, 16.44–19.59 g/100 g and 369.7–385.5 kcal/100 g, respectively. Essential amino acid index and predicted-biological values of the foods ranged from 68.31–76.31% and 62.19–71.48%, respectively. Phenolic profiles (mg/g) were gallic acid (25.33–31.26), caffeic acid (2.75–4.61), ferulic acid (5.16–12.73), luteolin (16.31–23.60), kaempferol (21.51–30.64), quercetin (24.28–37.13), chlorogenic acid (42.25–59.78), myricetin (28.41–38.41), 3,5-dicaffeoylquinic acid (27.17–41.59) and 4, 5-dicaffeoylquinic acid (39.96–51.28). The antioxidant activity of PSRO on ABTS, DPPH, FRAP, Fe2+ chelation and OH free radicals was higher than other foods. Atherogenic index, coronary risk index and log (TG/HDL-conc.) of rats fed on experimental foods were lower than recommended values. Conclusion The study established that PSRO had higher antioxidant and anti-hyperlipidemia properties; hence, it may be suitable as a functional food.

Pasting Properties of Composite Flour Made from Sorghum, Millet and African Yam Bean

The aim of this research was to produce acceptable ‘fufu’ from a mixture of sorghum, millet, and African yam bean flours that will have a moderate carbohydrate and protein content with most optimized texture. The functional and sensory properties of flour blends produced from Sorghum, Millet and African yam bean was studied. Sorghum, Millet and African yam bean were processed into flour and mixed at different ratios to obtain composite flours. The flour formulations obtained were analyzed for water absorption capacity, bulk density, least gelation concentration , and viscosity .The water absorption capacity ranged from 1.00 to 3.00, the bulk density ranged from 0.56 to 0.82;the least gelation concentration ranged from 5.77 to 6.87,while the viscosity ranged from 0.956 to 9.30.Also proximate composition of the individual flours before formulation was analyzed, it ranged from 6.13 to 8.46 moisture, 2.00 to 4.67 ash, 0.17 to 8.00 fiber,5.47 to 8.61 fat, 7.57 to 21.84 protein, 58.34 to 69.27 carbohydrate.The sensory values ranged from 5.60 to 6.45 for taste; 4.25 to 6.85 for colour; 5.15 to 6.80 for texture; 3.85 to 5.70 for aroma; 5.45 to 6.45 acceptability. Sample 10 (with the ratio of 40:70:20) had the highest rating for general acceptability. It was observed that sample 1(with the ratio of 60:50:60) had the lowest rating in taste and aroma. The mixture components that could produce optimum texture was determined through optimization plot. This work has demonstrated that acceptable ‘fufu’ with moderate protein and carbohydrate could be successfully produced using composite flours of sorghum, millet and African yam bean.

Comprehensive Understanding of Roller Milling on the Physicochemical Properties of Red Lentil and Yellow Pea Flours

The development of convenience foods by incorporating nutrient-rich pulses such as peas and lentils will tremendously alter the future of pulse and cereal industries. However, these pulses should be size-reduced before being incorporated into many food products. Therefore, an attempt was made to adapt roller mill settings to produce de-husked yellow pea and red lentil flours. The milling flowsheets unique to yellow peas and red lentils were developed in producing small, medium, and large flours with maximum yield and flour quality. This study also investigated the differences in chemical composition, physical characteristics, and particle size distributions of the resultant six flour fractions. The kernel dimensions and physicochemical properties of the whole yellow pea and red lentils were also studied to develop customized mill settings. Overall, the mill settings had a significant effect on the physical properties of different particle-sized flours. The geometric mean diameters of different particle-sized red lentil flours were 56.05 μm (small), 67.01 μm (medium), and 97.17 μm (large), while for yellow pea flours they were 41.38 μm (small), 60.81 μm (medium), and 98.31 μm (large). The particle size distribution of all the flour types showed a bimodal distribution, except for the small-sized yellow pea flour. For both the pulse types, slightly more than 50% flour was approximately sizing 50 μm, 75 μm, and 100 μm for small, medium, and large settings, respectively. The chemical composition of the flour types remained practically the same for different-sized flours, fulfilling the objective of this current study. The damaged starch values for red lentil and yellow pea flour types increased with a decrease in flour particle size. Based on the Hausner’s ratios, the flowability of large-sized flour of red lentils could be described as passable; however, all the remaining five flour types were indicated as either poor or very poor. The findings of this study assist the millers to adapt yellow pea and red lentil milling technologies with minor modifications to the existing facilities. The study also helps in boosting the production of various baking products using pulse and wheat flour blends to enhance their nutritional quality.