FNS  Vol.5 No.22 , December 2014
Evaluation Quality of One Layer Flat Bread Supplemented with Beans and Sorghum Baked on Hot Metal Surface
Abstract: The present study was carried out to develop the wheat flour nutritional value with good quality of unleavened bread by adding 5%, 10% and 15% of bean or sorghum flour. Water absorption was increased by addition of bean flour as a result of increase rate of substitution. Dough stability decreased for bean and sorghum blends as the same as increasing addition. Softening gradually increased with increasing the addition of beans or sorghum. Addition of 15% sorghum had the highest degree of softening compared with wheat control and beans mixtures. The extensibility, elasticity and the energy of produced dough were decreased with addition of beans or sorghum to wheat flour and the reduction increased with increasing the level of substitution. In contrast, addition of beans or sorghum to wheat flour increased the proportional number of the produced dough from 3.25 to 3.62 and from 1.80 to 2.90 for beans and sorghum dough, respectively. Bread supplemented with beans had the highest values in protein, ash and fiber compared with wheat and sorghum bread whereas, bread supplemented with sorghum had the highest values in fat content compared with wheat and beans bread. Sorghum bread had the highest iron and zinc content while beans bread had the highest calcium content. The sensory evaluation showed that different blends of beans and sorghum bread had highly acceptable values of all characteristics comparing with wheat control bread. Freshness of all unleavened flat bread blends decreased at different periods as well as bread control compared with zero time period. Water holding capacity (WHC) was significantly increased in all samples compared with wheat bread. Supplementation of bread with 15% beans recorded the highest value in WHC.
Cite this paper: Seleem, H. and Omran, A. (2014) Evaluation Quality of One Layer Flat Bread Supplemented with Beans and Sorghum Baked on Hot Metal Surface. Food and Nutrition Sciences, 5, 2246-2256. doi: 10.4236/fns.2014.522238.

[1]   Al-Dmoor, H.M. (2012) Flat Bread: Ingredients and Fortification. Quality Assurance and Safety of Crops and Foods, 4, 2-8.

[2]   Bornet, F.R., Billaux, M.S. and Messing, B. (1997) Glycaemic Index Concept and Metabolic Diseases. International Journal of Biological Macromolecules, 21, 207-219.

[3]   Livingstone, A.S., Feng, J.J. and Malleshi, N.G. (1993) Development and Nutritional Quality Evaluation of Weaning Foods Based on Malted, Popped and Dried Wheat and Chickpea. International Journal of Food Science Technology, 28, 35-43.

[4]   Hahn, D.H. and Rooney, L.W. (1985) Effect of Genotype on Tannin and Phenols of Sorghum. Cereal Chemistry, 63, 4-8.

[5]   Egli, I., Davidsson, L., Juillerat, M.A., Barclay, D. and Hurrell, R.F. (2002) The Influence of Soaking and Germination on the Phytase Activity and Phytic Acid Content of Grains and Seeds Potentially Useful for Complementary Feeding. Journal of Food Science, 67, 3484-3488.

[6]   Steiner, T., Mosenthin, R., Zimmermann, B., Greiner, R. and Roth, S. (2007) Distribution of Total Phosphorus, Phytate Phosphorus and Phytase Activity in Legume Seeds, Cereals and Cereal By-Products as Influenced by Harvest Year and Cultivar. Animal Feed Science and Technology, 133, 320-334.

[7]   Traoré, T., Mouquet, C., Icard-Verniere, C., Traore, A.S. and Treche, S. (2004) Changes in Nutrient Composition, Phytate and Cyanide Contents and α-Amylase Activity during Cereal Malting in Small Production Units in Ouagadougou (Burkina Faso). Food Chemistry, 88, 105-114.

[8]   Kayodé, A.P.P. (2006) Diversity, Users’ Perception and Food Processing of Sorghum: Implications for Dietary Iron and Zinc Supply. Ph.D. Dissertation, Wageningen University, Wageningen, 151.

[9]   Shobha, V., Kasturiba, B., Naik, R. K. and Yenagi, N. (2008) Nutritive Value and Quality Characteristics of Sorghum Genotypes. Karnataka Journal of Agriculture Science, 20, 586-588.

[10]   Dicko, M.H., Gruppen, H., Traoré, A.S., Voragen, A.G.J. and van Berkel, W.J.H. (2006) Sorghum Grain as Human Food in Africa: Relevance of Content of Starch and Amylase Activities. African Journal of Biotechnology, 5, 384-395.

[11]   Afify, A.M.R., El-Beltagi, H.S., Abd El-Salam, S.M. and Omran, A.A. (2012) Protein Solubility, Digestibility and Fractionation after Germination of Sorghum Varieties. PLoS ONE, 7, e31154.

[12]   Afify, A.M.R., El-Beltagi, H.S., Abd El-Salam, S.M. and Omran, A.A. (2012) Effect of Soaking, Cooking, Germination and Fermentation Processing on Proximate Analysis and Mineral Content of Three White Sorghum Varieties (Sorghum bicolor L. Moench). Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 40, 92-98.

[13]   Prasada Rao, K.E. and Murty, D.S. (1981) Sorghum for Special Uses. Proceedings of the International Symposium on Sorghum Grain Quality, Patancheru, 129-134.

[14]   Dhore, K.R. (2011) Sensory Evaluation of Sorghum Chakali Enriched with Different Levels of Soyabean Flours. International Referred Research Journal, 3, 50-51.

[15]   Oyarekua, M.A. and Adeyeye, E.I. (2009) Comparative Evaluation of the Nutritional Quality, Functional Properties and Amino Acid Profile of Co-Fermented Maize/Cowpea and Sorghum/Cowpea Ogi as Infant Complementary Food. Asian Journal of Clinical Nutrition, 1, 31-39.

[16]   Mepba, H.D., Eboh, L. and Nwaojigwa, S.U. (2005) Chemical Composition, Functional and Baking Properties of Wheat-Plantain Composite Flours. African Journal of Food, Agriculture, Nutrition and Development, 7, 1-22.

[17]   Mohammed, M.A.E., Makki, H.M.M. and Mustafa, A.E.M.I. (2011) Production of Cereal-Based Infant Food from Sorghum [Sorghum bicolor (L) Moench] and Pigeon Pea (Cajanus cajan). Pakistan Journal of Nutrition, 10, 910-913.

[18]   AACC, American Association of Cereal Chemists (2002) Approved Methods of the AACC. 8th Edition, American Association Cereal Chemistry. Method 54-21, St. Paul.

[19]   AOAC (2005) Official Methods of Analysis of the Association of Official Analytical Chemists. 18th Edition, Washington DC.

[20]   Land, D.G. and Shepherd, R. (1988) Scaling and Ranking Methods. In: Piggott, J.R., Ed., Sensory Analysis of Foods, Elsevier Applied Science, London, 155-185.

[21]   Yamazaki, W.T. (1953) An Alkaline Water Retention Capacity Test for the Evaluation of Cookie Baking Potentialities of Soft Winter Wheat Flours. Cereal Chemistry, 30, 242-246.

[22]   Kitterman, J.S. and Rubenthaler, G.L. (1971) Assessing the Quality of Early Generation Wheat Selection with the Micro AWRC Test. Cereal Science Today, 16, 313-316.

[23]   Beuchat, L.R. (1977) Functional and Electrophoretic Characteristics of Succinylated Peanut Flour Protein. Journal of Agricultural and Food Chemistry, 25, 258-261.

[24]   Coskuner, Y., Karababa, E. and Ercan, R. (1999) Flat Bread Production Technology. The Journal of Food, 24, 83-97.

[25]   Elgun, A. and Ertugay, Z. (1995) Cereals Processing Technology. Ataturk University Press, Erzurum, 376 p.

[26]   Deshpande, S.S., Rangnekar, P.D., Sathe, S.K. and Salunkhe, D.K. (1983) Functional Properties of Wheat-Bean Composite Flours. Journal of Food Science, 48, 1659-1662.

[27]   Morales-de-León, J.C., Vázquez-Mata, N., Torres, N., Gil-Zenteno, L. and Brezan, R. (2007) Preparation and Characterization of Protein Isolate Fresh and Hardened Beans (Phaseolus vulgaris L.). Journal of Food Science, 72, C96C102.

[28]   Lee, M.R., Swanson, B.G. and Baik, B.K. (2001) Influence of Amylose Content on Properties of Wheat Starch and Bread Making Qualities of Starch and Gluten Blends. Cereal Chemistry, 78, 701-706.

[29]   Morita, N., Maeda, T., Miyazaki, M., Yamamori, M., Miura, H. and Ohtsuka, I. (2002) Dough and Baking Properties of High Amylase and Waxy Wheat Flours. Cereal Chemistry, 79, 491-495.

[30]   Hussein, M.A., Saleh, A. and Noaman, M. (1977) Effect of Adding Sorghum Flour on Physical and Chemical Properties of Bread. Periodica Polytechnica-Chemical Engineering, 21, 343-354.

[31]   Foda, Y.H., Ramy, A., Rasmy, N.M., Abu-Salem, F.M.A. and Yassen, A.A.E. (1987) Rheological and Sensory Characteristics of Doughs and Balady Bread Based on Wheat, Sorghum, Millet and Defatted Soy Flours. Annals of Agricultural Science, Ain Shams University, 32, 381-395.

[32]   Rao, S.J. and Rao, G.V. (1997) Effect of Incorporation of Sorghum Flour to Wheat Flour on Chemical, Rheological and Bread Characteristics. Journal of Food Science and Technology, 34, 251-254.

[33]   Bushuk, W. (1985) Rheology: Theory and Application to Wheat Flour Dough. In: Faridi, H., Ed., Rheology of Wheat Products, American Association of Cereal Chemists, Inc., St Paul, 1-26.

[34]   Hamann, D.D. and Macdonald, G.A. (1992) Rheology and Texture Properties of Surimi Based Food. In: Lanier, T.C. and Lee, C.M., Eds., Surimi Technology, Marcel Dekker, New York, 429-500.

[35]   Malomo, S.A., Eleyinmi, A.F. and Fashakin, J.B. (2011) Chemical Composition, Rheological Properties and Bread Making Potentials of Composite Flours from Breadfruit, Breadnut and Wheat. African Journal of Food Science, 5, 400 -410.

[36]   Manay Shakuntala, N. and Shabakshanaswamy, M. (1997) Chemical Composition of Sorghum Food Facts and Principles. New Age International Publishers, Delhi, 243-245.

[37]   Wani, I.A., Sogi, D.S., Wani, A.A. and Gill, B.S. (2013) Physico-Chemical and Functional Properties of Flours from Indian Kidney Bean (Phaseolus vulgaris L.) Cultivars. LWT-Food Science and Technology, 53, 278-284.

[38]   Singh, U. (1991) The Role of Pigeon Pea in Human Nutrition. ICRISAT Conference Paper No. CP628, ICRISAT Centre, Patancheru.

[39]   Food and Agriculture Organization (FAO) (1979) Human Nutrition in Tropical Africa. Food and Agriculture Organization of the United Nations, Rome.

[40]   Tharanathan, R.N. and Mahadevamma, S. (2003) Grain Legumes—A Boon to Human Nutrition. Trends in Food Science and Technology, 14, 507-518.

[41]   Koehler, H.H., Chang, C., Scheier, G. and Burke, D.W. (1987) Nutrient Composition, Protein Quality, and Sensory Properties of Thirty-Six Cultivars of Dry Beans (Phaseolus vulgaris L.). Journal of Food Science, 52, 1335-1340.

[42]   Shehata, N.A., Darwish, N., El-Nahry, F. and Razek, F.A.A. (1988) Supplementation of Wheat Flour with Some Local Legumes. Food/Nahrung, 32, 1-8.

[43]   Anton, A.A., Ross, K.A., Lukow, O.M., Gary Fulcher, R. and Arntfield, S.D. (2008) Influence of Added Bean Flour (Phaseolus vulgaris L.) on Some Physical and Nutritional Properties of Wheat Flour Tortillas. Food Chemistry, 109, 33-41.

[44]   Ameh, M.O., Gernah, D.I. and Igbabul, B.D. (2013) Physico-Chemical and Sensory Evaluation of Wheat Bread Supplemented with Stabilized Undefatted Rice Bran. Food and Nutrition Sciences, 4, 43-48.

[45]   Shubhangini, A.J. (2002) Nutrition and Dietetics. 2nd Edition, Tata McGraw-Hill Publishing Co. Ltd., New Delhi.

[46]   Abulude, F.O. (2005) Distribution of Selected Minerals in Some Nigerian White Bread. Nigerian Food Journal, 23, 139-147.

[47]   Al-Mussali, M.S. and Al-Gahri, M.A. (2009) Nutritive Value of Commonly Consumed Bread in Yemen. E-Journal of Chemistry, 6, 437-444.

[48]   Abdel-Kader, Z.M. (2001) Enrichment of Egyptian Balady Bread. Part 2. Nutritional Values and Biological Evaluation of Enrichment with Decorticated Cracked Broad Beans Flour (Vicia faba L.). Molecular Nutrition and Food Research, 45, 31-34.

[49]   Shaikh, I.M., Ghodke, S.K. and Ananthanarayan, L. (2008) Inhibition of Staling in Chapatti (Indian Unleavened Flat Bread). Journal of Food Processing and Preservation, 32, 378-403.

[50]   Shalini, K.G. and Laxmi, A. (2007) Influence of Additives on Rheological Characteristics of Whole-Wheat Dough and Quality of Chapatti (Indian Unleavened Flat Bread) Part I—Hydrocolloids. Food Hydrocolloids, 21, 110-117.

[51]   Shaikh, I.M., Shalini, K.G. and Ananthanarayan, L. (2007) Staling of Chapatti (Indian Unleavened Flat Bread). Food Chemistry, 101, 113-119.

[52]   Sultan, W.J. (1990) Practical Baking. 5th Edition, Van Nostrand Reinhold, New York.

[53]   Gallaher, D. and Schneeman, B.O. (2001) Dietary Fiber. In: Bowman, B. and Russel, R., Eds., Present Knowledge in Nutrition, ILSI, Washington DC, 805.

[54]   Kethireddipalli, P., Hung, Y.C., Phillips, R.D. and Mcwaters, K.H. (2002) Evaluating the Role of Cell Material and Soluble Protein in the Functionality. Journal of Food Science, 67, 53-59.

[55]   Lopez, G., Ros, G., Rincon, F., Periago, M.J., Martinez, M.C. and Ortuno, J. (1996) Relationship between Physical and Hydration Properties of Soluble and Insoluble Fiber of Artichoke. Journal of Agricultural and Food Chemistry, 44, 2773-2778.