Flour Blends Research Articles

Impact of Ferulated Arabinoxylans from Maize Bran on Farinograph and Pasting Properties of Wheat Flour Blends

This research explores the extraction of ferulated arabinoxylans (FAXs) from maize bran and their incorporation into wheat flour to assess their impact on rheological and pasting properties. Flour blends were prepared with FAX concentrations of 0%, 2%, 4%, 6%, 8%, and 10%, and these blends were then evaluated using farinograph, mixograph, micro-extensibility, and viscosity analyses. The results indicated that farinograph water absorption increased significantly (p ≤ 0.05), ranging from 54.9% to 60.5%, as the FAX content rose, correlating with higher gel-forming potential. Notably, the 2% FAX treatment (FAX2) exhibited the longest dough development time at 24.7 min. Stability and mixing time index (MTI) values also varied significantly (p ≤ 0.05) among treatments, with FAX2 displaying a longer mixing time of 14.4 ± 3.3 min. A pasting analysis revealed a significant decrease in peak and hot paste viscosity (p < 0.05) with increasing FAX concentrations, suggesting an association between lower hot paste viscosity and reduced breakdown. Micro-extensibility measures further indicated that blends with 0% and 2% FAX had greater extensibility, while the 4% FAX blend showed higher resistance. Overall, this research aims to advance the understanding of how these components can enhance flour functionality and contribute to the development of healthier, higher-quality baked products.

Standardization and evaluation of RTE extruded corn-pearlmillet snacks incorporated with kidney bean or green gram flour: A comparative study

The presentstudy aimed to develop ready-to-eat extruded snacks by incorporating kidney bean flour (0-25%) or green gram flour (0-25%) in a cornpearlmillet (70:30) flour blend. All flours were tested for their compositional and nutritional parameters (crude fibre, carotenoid, phyticacid, polyphenols, iron, zinc, and total dietary fibre). Evaluation of pasting characteristics, water absorption, and dough extensibility of flours and physical (bulk density, expansion ratio, sectional expansion index, and hardness) and sensory properties of extruded snacks weredone. The addition of pulses reduced pasting values, resistance to extension, and extensibility of flour while increasing water absorptions significantly (p<0.05). Physical properties and sensory characteristics of extrudates were also significantly (p<0.05) reduced by pulses addition. However, considering nutritional aspects, kidney bean flour up to 15% or green gram flour up to 10% is recommended to be incorporated for obtaining extrudates of desirable quality. Both pulses hadsimilar effects on product quality, but the use of green gram flour is preferred over kidney bean due to its minimum anti-nutritional factors available in the resulting product.

Optimization and Validation of Extrusion Process Parameters for the Sensory Characteristics of Extruded Aerial Yam and Soybean Flour Blends

The aim of this study was to optimize and validate the extrusion process parameters (barrel temperature, screw speed, and feed moisture) for the sensory properties (texture, taste, appearance, and aroma) of extrudates made from blends of soybean and aerial yam flours. Five levels of barrel temperature (95, 100, 105, 110, and 115 °C), screw speed (85, 100, 115, 130, and 145 rpm), and feed moisture (31, 33, 35, 37, and 39%) were employed in 20 runs of the response surface methodology (RSM), which was based on the Box-Behnken design with three variables. A single-screw extruder at the laboratory scale was used to carry out the extrusion procedure. A high regression coefficient (R2 ≥ 0.9) indicates that the models are useful for navigating the design space. Numerical optimization results indicated that the optimal extrusion process parameters - barrel temperature of 114.12 °C, screw speed of 100.56 rpm, and feed moisture of 38.02% - produced extrudates with optimal sensory property scores of 5.34 for texture, 4.91 for taste, 6.97 for appearance, and 5.80 for aroma, with a desirability of 0.943. The correlation between the predicted and experimental values yielded a high coefficient of determination, indicating a good correlation. The “Fit and Diagnostic Case” statistics showed a low range of deviations between the predicted and observed values for the sensory characteristics. Therefore, the generated quadratic model accurately predicts the sensory characteristics of aerial yam-soybean flour blends and is thus validated.

Physicochemical and sensory properties of wheat-germinated sorghum-pigeon pea flour blends and their chin-chin-making potential

The effects of the substitution of wheat flour (WF) with Germinated Sorghum Flour (GSF) and Pigeon Peas Flour (PPF) at ratios of 100:00:00; 90:5:5; 80; 10:10 and 70:15:15 respectively in the proximate and mineral composition of the flour blends and the sensory properties of the chin-chin produced from the composite flour using standard methods were evaluated. The substitution reduced the moisture content from 10.55 to 9.18% while ash, fiber, protein, and fat content increased from 5.25 to 8.16%; 0.45 to 1.23%; 8.11 to 14.19%, and 3.37 to 5.42% respectively. An expected decrease in the carbohydrate content was recorded. The addition of GSF and PPF increased the sodium (1.18 - 1.45mg/100g); Potassium (1.48 - 3.49 mg /100g) and magnesium (0.68 - 1.66mg/100g) while zinc which was the most abundant out of all the mineral element assessed decreased from 74.32 - 36.61 mg/100g. The 100% WF Chin- -chin was ranked highest in color, taste, aroma, crispness, and general -acceptability closely followed by chin-chin produced fun 80WF: 10GSF: 10 PPF. This implies that wheat flour, germinated sorghum four and pigeon pea flour blends will produce chin-chin of good nutritional qualities

Design of gluten-free instant whole acorn-maize blended flour by extrusion process

Design of gluten-free instant whole acorn-maize blended flour by extrusion process

Effects of Barrel Temperature, Screw Speed and Feed Moisture Content on the Organoleptic Properties of Aerial Yam-Soybean Flour Extruded Snacks

The effects of barrel temperature, screw speed and feed moisture content, as extrusion process parameters, on the organoleptic properties of aerial yam-soybean flour extruded snacks were investigated, using Response Surface Analysis. The extruded snacks were produced using a Laboratory scale single-screw food extruder. Results of the determination of organoleptic properties of the extruded snacks showed that: texture; taste; colour; and aroma ranged from 4.38 to 6.02; 4.68 to 6.78; 4.58 to 6.97; and 4.45 to 7.00, respectively. Response surface Analysis indicated that barrel temperature and screw speed had significant effect (p < 0.05) on texture, while feed moisture had no significant effect (p > 0.05) on the texture of the snacks. All the extrusion parameters had significant effect (p < 0.05) on the taste of the snacks. Barrel temperature and feed moisture had significant effect (p < 0.05) on colour, while screw speed showed non-significant effect (p > 0.05) on the colour of the snacks. Barrel temperature had significant effect (p < 0.05) on aroma, while screw speed and feed moisture had no significant effect (p > 0.05) on the aroma of the snacks. The results obtained for the organoleptic properties of the snacks can attest to the fact that it is possible to obtain expanded or ready-to-eat (RTE) products from aerial yam-soybean flour blends by extrusion processing technology, that possess desirable organoleptic properties.

Impact of Corn, Bean, and Semolina Flour Blends and Processing Methods on the Physical Properties and Antioxidant Activity of Instant Noodles

Impact of Corn, Bean, and Semolina Flour Blends and Processing Methods on the Physical Properties and Antioxidant Activity of Instant Noodles

The Influence of Processing Using Conventional and Hybrid Methods on the Composition, Polysaccharide Profiles and Selected Properties of Wheat Flour Enriched with Baking Enzymes.

In this study, a developed wheat flour blend (F), consisting of a high content of non-starch polysaccharides, was fortified with cellulase (C) and a cellulase-xylanase complex (CX) and then processed via conventional and hybrid treatment methods. Dry heating (T), hydrothermal treatment (H) and extrusion processing (E) were applied without or with enzyme addition as hybrid treatments. Proximate composition and polysaccharide profiles selected techno-functional and structural properties of modified wheat flours, were analyzed. Conventional and hybrid treatments induced changes in polysaccharide fraction compositions (especially the arabinoxylans) and the rheology of modified flour. Dry heating caused an inconsiderable effect on flour composition but reduced its baking value, mainly by reducing the elasticity of the dough and worsening the strain hardening index, from 49.27% (F) to 44.83% (TF) and from 1.66 (F) to 1.48 (TF), respectively. The enzymes added improved the rheological properties and baking strength, enhancing the quality of gluten proteins. Hydrothermal enzyme-assisted treatment increased flour viscosity by 14-26% and improved the dough stability by 12-21%; however, the use of steam negatively affected the protein structure, weakening dough stretchiness and elasticity. Extrusion, especially enzyme-assisted, significantly increased the hydration properties by 55-67% but lowered dough stability, fat content and initial gelatinization temperature due to the changes in the starch, mostly induced by the hybrid enzymatic-extrusion treatment. The structure of extruded flours was different from that obtained for other treatments where the peak intensity at 20° was the highest, suggesting the presence of amorphous phases of amylose and lipids. The results can be helpful in the selection of processing conditions so as to obtain flour products with specific techno-functional properties.

Properties and characteristics of steam-exploded donkey bone powder and corresponding whole wheat cookies

Steam explosion was found to be the most effective preparation method for donkey bone powder, compared with non-treatment, autoclave and steam processing. And the effect of steam-exploded donkey bone powder (SEDBP) on the quality characteristics of whole wheat cookies was evaluated. Compared with untreated powder, particle size of SEDBP was reduced by 55.60 %, while oil- and water-holding capacity, water solubility and ABTS radical-scavenging rate significantly increased by 13.94 %, 26.86 %, 298.26 % and 91.47 %, respectively. Steam explosion enhanced protein digestibility from 32.17 % to 71.43 %, increased the Ca2+ release rate from 37.47 % to 47.82 %, and increased the release of 11 amino acids during digestion. SEDBP reduced the solvent retention capacity of flour blends and improved the color, hardness and spread ratio of whole wheat cookies. Cookies with 30 % SEDBP addition had better flavor, texture and scored the highest on overall acceptability. The results will help expand animal bone applications and develop nutrition-fortified foods.

Quality Evaluation of Composite Flour From Wheat, Soybean and Sunflower Seeds for Bread Making

Composite flours with good functional properties and high nutrient content was developed by substituting wheat with soybeans and sunflower seed flour. Wheat flour was supplemented with soybeans and sunflower seeds flour at a ratio of 100:0:0, 90:10:10, 80:10:10, 70:20:10 and 60:30:10, respectively. Standard analytical procedures were used for all the analysis on the samples. The composite flours obtained were evaluated for their functional properties, proximate composition and antinutritional properties. The results for the functional properties showed values which ranged from 1.76 to 2.38 mL/g and 1.85 to 2.45 mL/g for water absorption capacity, 1.02 to 1.10 mL/g and 1.10 to 1.25 mL/g for oil absorption capacity, 0.40 to 0.78 g/mL and 0.52 to 0.78 g/mL for bulk density, 8.33 to 12.10% and 8.66 to 12.10% for swelling capacity and 4.00 to 10.00% and 4.00 to 9.00% for least gelation concentration, respectively for the flours and flour blends. Addition of soybeans and sunflower seeds flour led to significant (p<0.05) increase in the protein content (15.22 to 28.90%), ash (1.01 to 3.31%), crude fibre (1.34 to 2.97%), fat (5.39 to 16.37%), energy value (388.05 to 434.67%) and a decrease in carbohydrate (69.68 to 42.94%) and moisture content (7.38 to 5.3%) for the flour blends. Processing methods affected the antinutritional factors as there was no significant increase in the tannin content (0.43 to 0.65 mg/100g), saponins (0.36 to 0.43 mg/ 100g), oxalates (1.24 to 2.40 mg/100g) and phytates content (1.22 to 2.12 mg/100g) concentration of the composite flour. The results reveal that the wheat, soybeans and sunflower seeds flours had good functional and nutritional density.

Augmented dough rheology, physical and nutritional quality of air fried chips from germinated flour blends of maize and lentil

AbstractBlends of germinated maize and germinated lentil (100:0, 85:15, 70:30, 55:45, and 40:60) were utilised for preparation of chips by air frying. Higher contents of protein, ash, total phenols, flavonoids and antioxidant activity were confirmed in germinated flours through analysis of FTIR spectra. Doughs from blends containing higher amounts of germinated lentil flour showed improved viscoelastic behaviour indicating better protein network as compared to maize dough. Significant (P ≤ 0.05) variation was observed in colour and hardness of air fried chips prepared from various blends. The 70:30 blend was found most acceptable based on sensory evaluation. Chips from this formulation were found superior to ungerminated maize chips in terms of protein digestibility and mineral composition.

Quality Evaluation of Flour and Crackers Made from Acha and Orange-Fleshed Sweet Potato Composite Flour Supplemented with Fermented Cowpea Flour

The present study aimed at evaluating the effects of supplementing 60% acha and 40% orange-fleshed sweet potato (OFSP) composite flour with 0, 10, 20, 30, 40 and 50% fermented cowpea flour on the functional properties of the flour blends and on the proximate composition, mineral content, antinutrients, and sensory characteristics of the crackers made from the blends. The 100% composite of acha and orange-fleshed sweet potato flours served as the control sample. The results obtained showed that all the parameters evaluated varied with the proportion of fermented cowpea flour supplementation. The bulk density increased significantly while the water absorption capacity, oil absorption capacity, pH, wettability, and gelatinization temperature decreased significantly with the increase in fermented cowpea flour supplementation. The moisture and carbohydrate content of the crackers progressively decreased from 8.83% - 8.08% and from 68.34% - 54.33% respectively with increase in cowpea flour supplementation. The ash, fibre, fat and protein contents of the crackers progressively increased from 1.90 - 2.43%, 0.40 – 0.70%, 14.46 – 18.45% and 6.07 – 16.01% respectively with increase in fermented cowpea flour supplementation. The potassium content of the crackers decreased from 87.51 – 68.66 mg/100g while the calcium, magnesium, iron and zinc contents of the crackers increased progressively from 59.16 - 96.61 mg/100g, 12.60 – 36.69 mg/100g, 0.62 – 0.78 mg/100g and 0.78 – 1.08 mg/100g respectively with increase in fermented cowpea flour supplementation. The oxalate and phytate contents of the crackers decreased progressively, while the tannin content increased with increasing fermentation of cowpea flour supplementation. It is evident from the study that acceptable crackers of high nutritional value could be produced from a composite of 60% acha and 40% orange-fleshed sweet potato flour supplemented with 30% fermented cowpea flour. This would increase the utilization of these locally grown crops and reduce wheat importation into the country.

Application of Conventional and Hybrid Thermal-Enzymatic Modified Wheat Flours as Clean Label Bread Improvers

A new flour blend (F) composed of selected milling and leaving passages with a high content of non-starch polysaccharides underwent thermal (T), hydrothermal (H) or hybrid processing and was used along with cellulase (C) and cellulase-xylanase complex (CX) to produce bread. This modified flour can be considered a clean label product. In this study, blends of common and treated flours were tested for dough properties and rheology. The modified flours were added at 10 and 20% to the base wheat flour. A pan bread was then prepared to test their suitability for bread baking. Dough and bread properties were subsequently assessed. Accordingly, dough with added thermally, hydrothermally, and hybrid modified flours revealed differences in rheology. Addition of hybrid enzymatic-hydrothermal treated flour increased dough tenacity by 23% and baking strength by 26%, but decreased dough extensibility by 19%, whereas hybrid enzymatic-thermal modification increased water absorption by 6% and bread yield from 146.77% to 150.02% when modified flour was added at 20%. Breads with added modified flours demonstrated a 16% increase in bread volume, 8% lower baking loss, and 14% greater density, with no negative effect on color and texture. Thus, hybrid thermal-enzymatic treatment of the developed flours can be recommended as a suitable method for enhancing the utilization of waste flour fractions and increasing their value by enabling them to be considered as clean label bread improvers.

Proximate, functional and sensory characteristics of blended yellow maize and hard-to-cook cowpea extruded snacks.

Cowpea is a rich source of low-cost protein, but it remains underutilised due to the development of the hard-to-cook phenomenon. However, milling hard-to-cook (HTC) seeds has shown potential for their utilisation in developing food products. Also, yellow maize is a relatively underutilised grain that is rich in nutrients, including vitamin A. Extrusion cooking of blends including yellow maize and HTC cowpea in snack formulations has the potential to improve their utilisation. Therefore, the objective of the study was to formulate a nutritious acceptable extruded snack using a combination of HTC cowpea and yellow maize flours. The results showed that addition of HTC cowpea flour increased ash (0.56-1.47%), fibre (3.56-5.31%) and protein content (10.20-12.38%) for flour blends. While carbohydrate (2.39-1.57%) and moisture content (10.33-9.74%) decreased. Blended formulations had lower fat content (4.17-4.41%) than yellow maize (4.80%). Furthermore, addition of HTC cowpea increased water (21.18-30.07%) and oil absorption capacities (14.12-22.03%) for flour blends. While expansion ratio (2.39-1.57%) of snacks decreased. The formulation with 15% HTC cowpea and 85% yellow maize flour had higher sensory ratings for overall acceptability (6.98). HTC cowpea addition in yellow maize flour improved the proximate and functional properties. Also, blending of yellow maize-based snacks with HTC cowpea improves consumer acceptability. Yellow maize and HTC cowpea flour blends have potential for industrial utilisation and can be useful in food formulations. © 2024 Society of Chemical Industry.

Technological Properties of Inulin-Enriched Doughs and Breads, Influence on Short-Term Storage and Glycemic Response.

The use of inulin in food is highly appreciated by consumers because of its prebiotic effect. In this study, the effects of increasing additions (5, 10 and 20%) of inulin as a substitute for wheat flour in bread production were investigated with regard to the physical, technological and rheological properties of the flour blends. Inulin reduced the water-binding capacity from 1.4 g/100 g with 0 flour to 0.80 g/100 g with the 20% inulin addition, while there were no statistical differences in the oil-binding capacity. The addition of inulin also influenced the yeast rates, especially in the samples with 5 and 10% addition. On the farinograph, inulin caused a reduction in water absorption (40.75 g/100 g with 20% inulin), an increase in dough development time (18.35 min with 10% inulin) and dough stability (13.10 min with 10% inulin). The mixograph showed a longer kneading time for the sample with 20% inulin (8.70 min) than for the control (4.61 min). In addition, there was an increase in dough firmness and tightness due to the addition of inulin (W: 203 × 10-4 J; P/L: 4.55 for the 20% inulin sample) compared with the control. The physical and technological properties of the loaves were evaluated at time 0 and after 4 days (T4). The addition of inulin reduced the volume of the bread while increasing the weight, albeit with a weight loss at T4 (compared to T0) of 4.8% for the 20% inulin and 14.7% for the control. The addition of inulin caused a darkening of the crust of the enriched bread, proportional to the increase in inulin content. In addition, the inulin content ranged from 0.82 g/100 g in the control to 14.42 g/100 g in the 20% inulin bread, while the predicted glycemic index ranged from 94.52 in the control to 89.39 in the 20% inulin bread. The available data suggest that the formulation with 5% inulin provides the highest performance.

Production of noodles using cocoyam (Colocasia esculenta)

The potential of making noodles using cocoyam flour was investigated. Cocoyam (Taro) and wheat flour were prepared. The proximate compositions of 100% cocoyam (C) flour, 100% wheat (W) flour, 50:50, and 70:30 blends of cocoyam-wheat (CW) flour were determined. Noodles were produced from cocoyam and wheat flour and their blends. The mean proximate composition of 100% cocoyam flour was found to be 11.19% amylose content, 8.70% crude protein, 4.86% ash, 0.60% fat content, 5.06% moisture content (wb), 6.38% crude fiber, and 72.22% carbohydrates with a swelling volume of 17.45 mL/g. The mean textural quality characteristics of the 100% cocoyam flour noodles were 5.88% cooking loss, 9.18 N/m2 tensile strength, 39.75 Pa elasticity, and 74.06 mm firmness with a cooking time of 4.31 mins. The 100% cocoyam noodles were rated 5.0, 3.0, 4.0, 5.0, and 4.0 for appearance, flavor, hardness, texture, and overall acceptability, respectively on a 9- point hedonic scale. In comparison with 100% wheat flour noodles with an acceptability of 7.0, the 100% cocoyam noodles had a lower score. The 50:50 cocoyam-wheat flour blend noodles, however, scored 6.0 on acceptability which was very close to that of 100% wheat noodles. This study showed that though noodles could be made from 100% cocoyam flour, a 50:50 cocoyam-wheat flour blend would make better quality noodles in terms of nutrition and overall acceptability.

Use of Integral Forage Palm Flour as an Innovative Ingredient in New Fettuccine-Type Pasta: Thermomechanical and Technological Properties, and Sensory Acceptance.

Dehydrated integral forage palm cladode flour (FPF) presents a promising nutritional and functional approach to enriching fettuccine-type pasta. This study investigated the use of microwave-dehydrated FPF (at 810 W) as a partial wheat flour substitute (0, 5, 10, 15, and 20% w/w) in fresh and dry fettuccine-type pasta. The thermomechanical properties of flour blends and the technological and sensory attributes of the resulting pasta were evaluated. FPF displayed a high protein (15.80%), mineral (15.13%), dietary fiber (67.35%), and total soluble phenolic compound (251 mg EAG·100 g-1) content. While water absorption (~58%) and dough stability remained consistent across formulations, a decrease in maximum torque during heating was observed (p < 0.05). Fettuccine-type pasta containing 10% FPF exhibited an acceptable optimal cooking time, solid loss, weight gain, and textural properties for both fresh and dry pasta. Sensory evaluation revealed acceptability above 63% for pasta with 10% FPF, with a slight preference for the fresh version. Fresh pasta flavored with garlic and extra virgin olive oil (garlic and oil pasta) achieved a sensory acceptance rate of 79.67%. These findings demonstrate the potential of FPF for fettuccine-type pasta production, contributing desirable technological characteristics and achieving acceptable sensory profiles.

Evaluation of the nutritional and chemical composition of crackers developed from blends of wheat, unripe plantain, and mushroom flour

Crackers are considered a healthier substitute for other types of biscuits that are more calorie-dense. Novel ingredients are therefore being searched for in the formulation of crackers. This study evaluated crackers' nutritional and chemical composition from blends of wheat, unripe plantain, and mushroom flours. Compared to wheat flour, the functional properties of the blends showed high water absorption capacity (WAC), and bulk density, while swelling capacity was not significantly affected. The moisture (4.98–8.51 %), protein (10.47–21.31 %), fat (7.17–11.46 %), fiber (0.20–0.60 %), and ash (1.61–3.47 %), contents of the composite crackers were higher, while carbohydrate content (51.81–72.07 %) was lower than the control. The soluble and insoluble dietary fiber increased from 5.13 % to 9.00 %, and 3.49 % to 7.08 % respectively. K and Na were the principal minerals in the crackers based on the mineral analysis results, which increased upon 10 % replacement of mushroom flour. The oxalate and phytate contents of the crackers ranged between 0.05–0.07 mg/g and 7.78–14.98 mg/g respectively. The crackers with 10 % replacement of mushroom flour were accepted by panelists. The study revealed the feasibility of cracker production with enhanced nutritional composition using wheat, unripe plantain, and mushroom flour blends.

Quality and microstructural analysis of chickpea-enriched wheat semolina pasta using X-ray micro-computed tomography

The microstructure of manufactured foods largely governs palatability qualities such as crunchiness, crispness, mouthfeel and texture. While enriching cereal flour with leguminous flour increases its nutritional value, it should not compromise the palatability of the end products. This study investigated the flour blend properties as well as the physical and microstructural characteristics of durum wheat semolina pasta enriched with 50% chickpea flour obtained from single-stage (Ferkar) and multi-stage (roller) mills. Results of the flour blend analysis indicated the influence of milling on the protein, ash and particle size distribution of pasta. High protein chickpea blend showed minimal impact on the microstructure of the pasta. Also, the textural analysis of the pasta samples showed that the hardness and firmness of pasta made with roller-milled flours, specifically reduction and straight-grade flours, were not statistically significantly different (p < 0.05). However, correlating the texture and total porosity indicated that flour from roller mill reduction rolls resulted in pasta with a firmer texture along with a more compact internal and external microstructure. The findings of this study provide useful insight into the quality attributes of chickpea-enriched wheat semolina pasta as influenced by the mill type and stream blend of the chickpea flour.

Nutritional, Phytochemical, Functional and Antioxidant Properties of Acha, Chia and Soycake Flour Blends

Functional flour blends are been developed with nutritional and health promoting benefits to fit in to the third agenda of Sustainable Development Goal (SDG) 2030. A blend of fermented acha (FAF), defatted chia (DCF), and defatted soycake flours (DSF flour were blended to harness the proficient potential of the blends. Response surface methodology (RSM) was used to generate fourteen runs using the the protein and the crude fibre of the flour blends. The three blends that the protein ranges from 15-20% and fibre from 3-5% were selected and the composite flours were analyzed for proximate composition, minerals, phytochemical composition, functional properties, and antioxidant properties. Results indicated that protein content increased with higher DSF proportions ranging from 15.37% in ACSF13 (80% of fermented acha, 10% of defatted chia seed, 10% soycake) to 19.51% in ACSF9 (45% of Fermented acha, 10% of defatted chia seed, 45% soycake). Energy content also rose from 335.4 kcal to 391.4 kcal in ACSF13 to ACSF1 (57% of fermented acha, 22% of defatted chia seed, 21% Soycake). ACSF1 is the blend with the highest fibre (5.06%) and ACSF9 possess the highest ash content of (4.13%). The blends were rich in potassium, calcium, zinc, iron and magnesium with phytochemical, phytate- mineral ratio and oxalate mineral ratio within recommended levels. Sample ACSF1 had the highest bulk density while ACSF9 possess both the highest swelling capacity and water absorption. The total phenolic and flavonoid content of the flour blends ranged from 273.55 to 149mg GAE/g and 66.71 to 31.60mgQE/g with sample ACSF13 having the highest phenolic content (273.55GAEmg/g) and flavonoid content of 66.71mgQE/g. The increase in the Soycake flour is an indications to improvement on the nutritional values of the flour blends.