EFFECT OF OKARA AND Detarium microcarpum INCORPORATION ON THE QUALITY OF ‘TALIA’ PRODUCED FROM WHEAT AND SORGHUM FLOUR BLENDS
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of study
- 1.3Problem Statement
- 1.4Objective of study
- 1.5Limitation of study
- 1.6Scope of study
- 1.7Significance of study
- 1.8Structure of the research
- 1.9Definition of terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Okara and Detarium microcarpum
- 2.2Nutritional composition of Okara
- 2.3Nutritional composition of Detarium microcarpum
- 2.4Previous studies on Okara and Detarium microcarpum
- 2.5Effects of Okara and Detarium microcarpum on food products
- 2.6Consumer perception of Okara and Detarium microcarpum
- 2.7Economic aspects of Okara and Detarium microcarpum
- 2.8Environmental impact of Okara and Detarium microcarpum
- 2.9Processing techniques of Okara and Detarium microcarpum
- 2.10Future trends in the use of Okara and Detarium microcarpum
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research design
- 3.2Sampling methods
- 3.3Data collection techniques
- 3.4Data analysis methods
- 3.5Variables and measures
- 3.6Ethical considerations
- 3.7Research limitations
- 3.8Research validity and reliability
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Analysis of data on Okara and Detarium microcarpum incorporation
- 4.2Comparison of quality attributes in 'Talia' produced from wheat and sorghum flour blends
- 4.3Impact of Okara and Detarium microcarpum on sensory characteristics
- 4.4Nutritional implications of incorporating Okara and Detarium microcarpum
- 4.5Shelf-life evaluation of 'Talia' with Okara and Detarium microcarpum
- 4.6Consumer acceptance studies
- 4.7Challenges faced during the research
- 4.8Recommendations for future research
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of findings
- 5.2Conclusion
- 5.3Implications of the research
- 5.4Contributions to the field
- 5.5Recommendations for further studies
Project Abstract
<p> <b>ABSTRACT </b></p><p> The effect of Okara and Detarium microcarpum seed flours on the quality of talia noddles produced from wheat and sorghum flour composites was investigated. Composites of wheat semolina/sorghum flour blended in ratio of 1000, 9010, 8020, 7030, 6040 and 5050 were prepared and evaluated for water absorption capacity, soluble solids and swelling capacity. Cold extruded talia produced from each flour composites dough was evaluated for cooking time, cooking losses and total organic matter. The 1000, 9010, 8020 and 7030 wheat semolina/sorghum flour composites were selected and blended with different levels (0-20) % of Okara and Detarium microcarpum flours, evaluated for physico-chemical properties and talia produced from the flour blends were evaluated for cooking test and sensory qualities. Four best talia products were selected, stored for six months (30 ± 2oC, 85±5% RH) and evaluated for pH, moisture content, TBA number and mould count. Presence of sorghum in the composite flour increased the water absorption capacity from 7.33% to 12.33%, decreased swelling capacity from 52.0% to 45.4%, while talia made from the composites showed increased cooking loss (0.14% to 0.82%), total organic matter (1.26 to 2.84) and reduced radial expansion (3.0 to 2.0) relative to the control. Sorghum addition at 30% level was acceptable for talia production based on low water absorption capacity and high swelling capacity. Okara addition increased the protein content (from 10.21% to 13.63%) of the composites and talia. Blends with 10% okara showed low water absorption capacity (12.75%), low cooking losses (0.73%) and high scores in all the sensory attributes except in appearance but differed significantly (p < 0.05) from the control (100% wheat). Detarium microcarpum addition increased the crude fibre (from 1.69% to 3.76%) content of the talia. There was no significant (p > 0.05) difference among samples at 5% levels of Deterium microcaprum incorporation relative to the control in all the sensory attributes except in appearance. Low water absorption capacity, cooking loss, and optimal total organic matter (2.01) were observed in the samples at 5% level of Detarium microcarpum incorporation. Okara and Detarium microcarpum addition into talia increased the total dietary fibre contents (from 8.61±0.02% to 9.97±0.01%). The total dietary fibre and mineral contents of samples differed significantly (p < 0.05) with the control. Moisture contents and TBA number did not differ (p>0.05) among stored samples but pH and mould count differed (p < 0.05) relative to the control. Low values of TBA (0.6 to 3.17 mg malonaldehyde/kg sample), mould count (0 to 1.4 x 102 cfu/100g) and moisture contents (10.5% to 14.5%) were recorded during storage. The effect of Okara and Detarium microcarpum seed flours on the quality of talia noddles produced from wheat and sorghum flour composites was investigated. Composites of wheat semolina/sorghum flour blended in ratio of 1000, 9010, 8020, 7030, 6040 and 5050 were prepared and evaluated for water absorption capacity, soluble solids and swelling capacity. Cold extruded talia produced from each flour composites dough was evaluated for cooking time, cooking losses and total organic matter. The 1000, 9010, 8020 and 7030 wheat semolina/sorghum flour composites were selected and blended with different levels (0-20) % of Okara and Detarium microcarpum flours, evaluated for physico-chemical properties and talia produced from the flour blends were evaluated for cooking test and sensory qualities. Four best talia products were selected, stored for six months (30 ± 2oC, 85±5% RH) and evaluated for pH, moisture content, TBA number and mould count. Presence of sorghum in the composite flour increased the water absorption capacity from 7.33% to 12.33%, decreased swelling capacity from 52.0% to 45.4%, while talia made from the composites showed increased cooking loss (0.14% to 0.82%), total organic matter (1.26 to 2.84) and reduced radial expansion (3.0 to 2.0) relative to the control. Sorghum addition at 30% level was acceptable for talia production based on low water absorption capacity and high swelling capacity. Okara addition increased the protein content (from 10.21% to 13.63%) of the composites and talia. Blends with 10% okara showed low water absorption capacity (12.75%), low cooking losses (0.73%) and high scores in all the sensory attributes except in appearance but differed significantly (p < 0.05) from the control (100% wheat). Detarium microcarpum addition increased the crude fibre (from 1.69% to 3.76%) content of the talia. There was no significant (p > 0.05) difference among samples at 5% levels of Deterium microcaprum incorporation relative to the control in all the sensory attributes except in appearance. Low water absorption capacity, cooking loss, and optimal total organic matter (2.01) were observed in the samples at 5% level of Detarium microcarpum incorporation. Okara and Detarium microcarpum addition into talia increased the total dietary fibre contents (from 8.61±0.02% to 9.97±0.01%). The total dietary fibre and mineral contents of samples differed significantly (p < 0.05) with the control. Moisture contents and TBA number did not differ (p>0.05) among stored samples but pH and mould count differed (p < 0.05) relative to the control. Low values of TBA (0.6 to 3.17 mg malonaldehyde/kg sample), mould count (0 to 1.4 x 102 cfu/100g) and moisture contents (10.5% to 14.5%) were recorded during storage. <br></p>
Project Overview