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Nutritional Value of Differently Processed Soybean Seeds


Affiliations
1 Copperbelt University, Department of Basic Sciences, School of Medicine, Zambia
2 Ndola College of Biomedical Sciences, Ndola Central Hospital, Ndola, Zambia
     

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The main objective of this study was to determine the nutritional and anti-trypsin content of raw soybean seeds in comparison to the solvent extracted and steam cooked soybeans. The proximate composition, minerals and anti-trypsin content of raw soybean seeds and differently processed soybean seeds were determined using standard methods. One way Analysis of Variance (ANOVA) was used in analysing the data. The moisture content of Solvent Extracted Soybean seeds (SES) (6.7±0.2 %) was significantly higher than Raw Soybean Seed Meal (RSSM) and Extruded Full-Fat Soybean Seeds (EFFS) (p<0.05). EFFS seeds had lower ash content (4.4±0.1 %) as compared to the SES and RSSM. SES had significantly very low crude fat content (2.7±0.2 %) than EFFS and RSSM (p<0.005). SES had higher crude protein content (48.9±0.6 %) than EFFS and RSSM. RSSM had significantly higher calcium content (1.81±0.007 %) than both EFFS and SES seeds (p<0.05). There was a significant difference in phosphorus content among all the soybean seeds with RSSM having the highest content (0.96±0.1) and EFFS seeds having the lowest (0.59±0.06%), (p<0.05). There was a significant difference in trypsin inhibitor content in raw and different processed soybeans with RSSM having the highest concentration (54.0±1.5) while EFFSs had the lowest content (1.0±0.03 mg inhibited Trypsin/g). The highest essential amino acid content in EFFS, SES and RSSM seeds was arginine (8.67±0.3), (8.69±0.5) and (7.77±0.3 g/16 g N) respectively. While the lowest essential amino acid in raw and differently processed soybeans was methionine with SES having the lowest concentration (1.46±0.2 g/16 g N). The results further indicate that EFFSs had the highest concentrations of all the non-essential amino acids apart from cystine which was slightly higher in SES than in EFFSs whilst glutamic acid was the highest non-essential amino acid obtained in EFFSs. RSSM had lower amount of all the nonessential amino acids apart from tyrosine as compared to SES and EFFS though the differences were not significant (p>0.05). Soybeans processed by steaming (EEFS) could be used as a protein and energy source at the village level as the method is easier and cheaper to use while it maintains most of the nutrients and removes the anti-nutrient factors.

Keywords

Raw Soybean, Solvent Extraction, Full-Fat Soybeans, Anti-Nutritional Factors, Proximate Analysis.
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  • Liu, K., Expanding soybean food utilization, J. Fd. Tech., 2000, 54, 46-58.
  • Traina, M.S. and Breene, W.M., Composition, functionality and some chemical and physical properties of eight commercial full-fat soy flours. J. Fd. Process. Pres., 1994, 8, 229-252.
  • Anderson, R.L. and Wolf, W.J., Compositional changes in trypsin inhibitors phytic acid, saponins and isoflavones related to soybean processing. J. Nutr., 1995, 125, 581-588.
  • Liener, I.E., Nitsan, Z., Srisangnam, C, Rackis, J.J. and Gumbmann, M.R., The USDA trypsin inhibitor, Study II, Timed related biochemical changes in the pancreas of rats. PL Fd. Hum. Nutr. 1985,
  • Bruce, K.J., Karr-Lilienthal, L.K., Zinn, K.E., Pope, L.L., Mahan, D.C., Fastinger, K.L., Watts, M., Utterback, P.L., Parsons, CM., Castaneda, E.O., Ellis, M. and Fahey, G.C., Evaluation of the inclusion of soybean oil and soybean processing by-products to soybean meal on nutrient composition and digestibility in swine and poultry. J. Anim. Sci., 2006, 84, 1403-1414.
  • Stein, H.H., Berger, L.L., Drackley, J.K., Fahey, G., Hernot, D.C. and Parsons, C, Nutritional properties and feeding values of soybeans and their coproducts. Soybeans, chemistry, production, processing and utilization. A.J. Lawrence, P.J. While and R. Galloway eds. AOCS Publishing, 2008, 613-630.
  • Buttle, L.G., Burrels, A.C. and Good, J.E., The binding of soybean aggtinin (SBA) to the intestinal epithelium of Atlantic salmon, salmo salar and rainbow trout. Oncorrhynchus mykiss, fed high levels of soybean meal. J. Veter. Immunol. ImmunopathoL, 2001, 80, 237-244.
  • Palacios, M.F., Easter, R.A. and Douglas, T., Effect of soybean variety and processing on growth performance of young chicks and pigs. J. Anim. Sci., 2004, 82, 1108-1114.
  • Van der Poel, A.F.B., Verstegen, M.W.A. and Tmminga, S., Chemical physical and nutritional effects of feed processing technology, Proceedings of the 16th Western Nutrition Conference, Saskatoon, Canada, 1995.
  • Renner, R. and Hill, F.W., Studies of the effect of heat treatments on the metabolizable energy value of soybeans and extracted soybean flakes for the chick. Nutr., 1960, 70, 219-225.
  • Rackis, J.J., Physiological properties of trypsin inhibitors and their relationship to pancreatic hypertrophy and growth inhibition of rats. Feed. Proc, 1960, 24, 1488-1493.
  • Serafin, J.A. and Nesheim, M.C., Influence of dietary heat labile factors in soybean meal upon bile acids pools and turnover in the chick. J. Nutr., 1970, 100, 786-796.
  • AOAC, "Official Method of Analysis", 15th end. Association of official analytical chemists. Washington DC. 1990.
  • Kirk, S.R. and Sawyer, R., Pearson's composition and analysis of foods, 9th end. Longman Scientific and Technical, UK, 1991.
  • Panzenga, U., 1985. Feeding parent-stock. Zootech.Intern.
  • Einarsson, S., Josefsson, B. and Lagerkvist, S., Determination of amino acids with 9- fluorenylmethylchloroformate and reversedphase High Performance Liquid Chromatography. J. Chrom., 1983, 282, 609-618.
  • Dave Oomah, B., Dave Oomah, C, Francois, J.M., Linda, B. and Anne-Sophie. Phenolics and antioxidant activity of lentil and pea hulls, Fd. Res. Int., 2011, 44, 436-441.
  • Kakade, M.L., Rackis, J.J. and Puski, G., Determination of trypsin inhibitor activity of soy products: A collaborative analysis of an improved procedure. Cereal Chem., 1974, 51, 376-382.
  • Davies, H., Processing of full-fat soybeans, proceedings of a workshop on the processing of full fat soybeans, Irene, South Africa, 2008.
  • Saulawa, L.A., Yaradua, A.I. and Shuaibu, L., Effect of different processing methods on proximate, mineral and anti nutritional factors content of Baobab (Adansonia digitata) seeds. Pak. J. Nutr., 2014, 13, 314-318.
  • Magdi, A.O., Chemical and nutrient analysis of Baobab (Adansonia digitata) fruit and seed protein solubility. PL Fd. Hum. Nutr., 2004, 59, 29-33.
  • Okoye, W.I., Kazaure, I. and Egesi, G.V., A preliminary investigation of Baobab (Adansoniadigitata. L) as a potential source of oilseed. Annual Report Nigerian Stored Prod. Res. Instit., 1980, 73-75.
  • Akinmutimi, A.H., Evaluation of swordbeans (Canavalic gladiate) as alternative feed resource for broiler chickens. Ph.D. Dissertation. Micheal Okpara University of Agriculture, Umudike, Abia state 2004.
  • Emiola, I.A., Ologhobo, A.D., Adedeji, O.S., Akanji, T.A. and Olayeni, T.B., Effect of residual trypsin inhibitor and haemagglutinin in differently processed kidney beans seed on feed intake and performance characteristics of broilers. 2002, Proc. 7th Ann. Conf. ASAN. UNAAB. 75-76.
  • Creager, M.A., Gallagher, S.J., Girerd, X.J., Coleman, S.M., Dzau, V.J. and Cooke, J.P., L-arginine improves endothelium-dependent vasodilation in hypercholesterolemic humans. J. Clin. Invest., 1992, 90.
  • Udousoro Imaobong Inyang, Roland U. Ekop and Efiok Johnson Udo., Effect of thermal processing on antinutrients in common edible green leafy vegetables grown in Ikot Abasi, Nigeria. Pak. J. Nutr., 2013, 12, 162-167.
  • Quintela, A.F., Barrio, A.S., Maraculla, T.M. and Martinez, J.A., Nutritional evaluation and metabolic effects in rats of protein isolates obtained from seeds of three legume species. J. Sci. Fd. Agric, 1998, 78, 251-260.
  • Liener, I.E., Implications of antinutritional components in soybean foods. Fd. Sci., 1994, 34, 31.
  • Mushtaq, M., Nutritional evaluation of soybean meal varying in urease and trypsin inhibitor activity. Thesis dissertation, North Carolina State University, Raleigh, NC, 1987.
  • Herkelman, K.L., Cromwell, G.L., Stahly, T.S., Pfeiffer, T.W. and Knabe, D.A., Apparent digestibility of amino acids in raw and heated conventional and low trypsin inhibitor soybean for pigs. Anim. Sci., 1992, 70, 818-824.
  • Ladeji, O., Akin, C.U. and Umaru, H.A., Level of anti-nutritional factors in vegetables commonly eaten in Nigeria. Afr. J. Nat. Sci., 2004, 71-73.
  • Agbaire, P.O., Levels of anti-nutritional factors in some common leafy edible vegetables of southern Nigeria. Afr. J. Fd. Sci. Tech., 2012, 3, 99-101.
  • Akande, K.E., Doma, U.D., Agu, H.O. and Adamu, H.M., Major anti-nutrients found in plant protein sources: Their effect on nutrition. Pak. J. Nutr., 2010, 8, 827-832.
  • Agbaire, P.O. and Emoyan, O.O., Nutritional and anti-nutritional levels of some local vegetables from Delta State, Nigeria. Afr. J. Fd. Sci., 2012, 6, 8-11.

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  • Nutritional Value of Differently Processed Soybean Seeds

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Authors

N. Siulapwa
Copperbelt University, Department of Basic Sciences, School of Medicine, Zambia
A. Mwambungu
Ndola College of Biomedical Sciences, Ndola Central Hospital, Ndola, Zambia

Abstract


The main objective of this study was to determine the nutritional and anti-trypsin content of raw soybean seeds in comparison to the solvent extracted and steam cooked soybeans. The proximate composition, minerals and anti-trypsin content of raw soybean seeds and differently processed soybean seeds were determined using standard methods. One way Analysis of Variance (ANOVA) was used in analysing the data. The moisture content of Solvent Extracted Soybean seeds (SES) (6.7±0.2 %) was significantly higher than Raw Soybean Seed Meal (RSSM) and Extruded Full-Fat Soybean Seeds (EFFS) (p<0.05). EFFS seeds had lower ash content (4.4±0.1 %) as compared to the SES and RSSM. SES had significantly very low crude fat content (2.7±0.2 %) than EFFS and RSSM (p<0.005). SES had higher crude protein content (48.9±0.6 %) than EFFS and RSSM. RSSM had significantly higher calcium content (1.81±0.007 %) than both EFFS and SES seeds (p<0.05). There was a significant difference in phosphorus content among all the soybean seeds with RSSM having the highest content (0.96±0.1) and EFFS seeds having the lowest (0.59±0.06%), (p<0.05). There was a significant difference in trypsin inhibitor content in raw and different processed soybeans with RSSM having the highest concentration (54.0±1.5) while EFFSs had the lowest content (1.0±0.03 mg inhibited Trypsin/g). The highest essential amino acid content in EFFS, SES and RSSM seeds was arginine (8.67±0.3), (8.69±0.5) and (7.77±0.3 g/16 g N) respectively. While the lowest essential amino acid in raw and differently processed soybeans was methionine with SES having the lowest concentration (1.46±0.2 g/16 g N). The results further indicate that EFFSs had the highest concentrations of all the non-essential amino acids apart from cystine which was slightly higher in SES than in EFFSs whilst glutamic acid was the highest non-essential amino acid obtained in EFFSs. RSSM had lower amount of all the nonessential amino acids apart from tyrosine as compared to SES and EFFS though the differences were not significant (p>0.05). Soybeans processed by steaming (EEFS) could be used as a protein and energy source at the village level as the method is easier and cheaper to use while it maintains most of the nutrients and removes the anti-nutrient factors.

Keywords


Raw Soybean, Solvent Extraction, Full-Fat Soybeans, Anti-Nutritional Factors, Proximate Analysis.

References