Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-23T05:16:11.276Z Has data issue: false hasContentIssue false

Effect of a processed soy protein product on growth and gut physiology of broiler chickens

Published online by Cambridge University Press:  11 May 2015

S.S.M. Beski
Affiliation:
School of Environmental and Rural Sciences, University of New England, Armidale, NSW 2351, Australia
P.A. Iji*
Affiliation:
School of Environmental and Rural Sciences, University of New England, Armidale, NSW 2351, Australia
*
Corresponding Author: Paul Iji Email:[email protected] Phone:(02)67732082

Summary

A 4 × 2 factorial experiment was conducted to investigate the effect of a processed soy protein (PSP) on broiler performance and digestive physiology. Four inclusion levels of PSP (0, 25, 50 or 100 g/kg in either corn or wheat-based diets) were used in the starter diets. Feed intake was significantly lower (P < 0.01) on corn-based diets than those on wheat-based diets at 35 d. Over the first 10 d, chicks on corn-based diets tended (P < 0.09) to have higher body weight (BW) than wheat-based diet chicks. Across the 35 d trial, PSP level showed a strong tendency (P < 0.06) to be related to higher BW in birds, regardless of grain type. Both grain and PSP experimental factors significantly (P < 0.01, and P < 0.001) interacted at an early age, improving BW and feed conversion ratio (FCR) for birds received high PSP on wheat-based diets. Significantly heavier (P < 0.01) small intestine and gizzard + proventriculas weights at an early age, and heavier (P < 0.001) gizzard + proventriculas and pancreas during the grower stage were recorded in birds fed the corn-based diets. At 24 d, pancreatic chymotrypsin amidase and lipase enzymes were significantly (P < 0.01) more active in chickens fed the wheat-based diet. The interaction of PSP level and the type of the grain was significant (P < 0.01) for pancreatic chymotrypsin amidase and lipase as well as jejunal maltase (P < 0.05). Both experimental factors had a significant influence on jejunum histomorphology at 24 d of age (P < 0.001). There was a significant interaction between level of PSP and the type of grain (P < 0.05) resulting in the highest villus surface areas being seen for birds fed the corn-based diet and receiving the medium level of PSP. The trial demonstrated that PSP supplement can be included at between 50 and 100 g/kg of starter diets, depending on the basal diet.

Type
Original Research
Copyright
Copyright © Cambridge University Press and Journal of Applied Animal Nutrition Ltd. 2015 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Almirall, M., Francesch, M., Perez-Vendrell, A.M., Brufau, J. and Esteve-Garcia, E. (1995). The differences in intestinal viscosity produced by barley and beta-glucanase alter digesta enzyme activities and ileal nutrient digestibilities more in broiler chicks than in cocks. The Journal of nutrition, 125: 947955.Google ScholarPubMed
Batal, A. and Parsons, C. (2003). Utilisation of different soy products as affected by age in chicks. Poultry Science, 82: 454462.Google Scholar
Bradford, M.M. (1976). A rapid and sensitive method for the quantitation of microgram quantities of protein utilising the principle of protein-dye binding. Analytical Biochemistry, 72: 248254.Google Scholar
Choct, M., Hughes, R. and Bedford, M. (1999). Effects of a xylanase on individual bird variation, starch digestion throughout the intestine, and ileal and caecal volatile fatty acid production in chickens fed wheat. British Poultry Science, 40: 419422.Google Scholar
Feng, J., Liu, X., Xu, Z., Wang, Y. and Liu, J. (2007). Effects of fermented soybean meal on digestive enzyme activities and intestinal morphology in broilers. Poultry Science, 86: 11491154.Google Scholar
Gabriel, I., Mallet, S. and Leconte, M. (2003). Differences in the digestive tract characteristics of broiler chickens fed on complete pelleted diet or on whole wheat added to pelleted protein concentrate. British Poultry Science, 44: 283290.Google Scholar
Hargis, P.H and Creger, C. (1980). Effects of varying dietary protein and energy levels on growth rate and body fat of broilers. Poultry Science, 59: 14991504.Google Scholar
Holdsworth, E. (1970). The effect of vitamin d on enzyme activities in the mucosal cells of the chick small intestine. Journal of Membrane Biology, 3: 4353.CrossRefGoogle ScholarPubMed
Iji, P.A., Saki, A. and Tivey, D. (2001). Body and intestinal growth of broiler chicks on a commercial starter diet. 1. Intestinal weight and mucosal development. British Poultry Science, 42: 505513.Google Scholar
Iji, P.A., Saki, A. and Tivey, D.R. (2001). Body and intestinal growth of broiler chicks on a commercial starter diet. 2. Development and characteristics of intestinal enzymes. British Poultry Science, 42: 514522.Google Scholar
Jankowski, J., Juskiewicz, J., Gulewicz, K., Lecewicz, A., Slominski, B. and Zdunczyk, Z. (2009). The effect of diets containing soybean meal, soybean protein concentrate, and soybean protein isolate of different oligosaccharide content on growth performance and gut function of young turkeys. Poultry Science, 88: 21322140.Google Scholar
Jiang, H., Gong, L., Ma, Y., He, Y., Li, D. and Zhai, H. (2006). Effect of stachyose supplementation on growth performance, nutrient digestibility and caecal fermentation characteristics in broilers. British Poultry Science, 47: 516522.CrossRefGoogle ScholarPubMed
Kleyn, R. and Chrystal, P. (2008). Feeding the young broiler chicken in practice: A review. 23rd world's poultry cogress. Brisbane, australia. Revista de Igiena, Bacteriologie, Virusologie, Parazitologie, Epidemiologie, Pneumoftiziologie. Bacteriologia, Virusologia, Parazitologia, Epidemiologia.Google Scholar
Kocher, A., Choct, M., Porter, M. and Broz, J. (2002). Effects of feed enzymes on nutritive value of soyabean meal fed to broilers. British Poultry Science, 43: 5463.Google Scholar
Maiorka, A., Dahlke, F. and Morgulis, M.S.F.A. (2006). Broiler adaptation to post-hatching period. Cienca Rural, 36: 701708.Google Scholar
Marsman, G., Gruppen, H., Van der Poel, A., Kwakkel, R., Verstegen, M. and Voragen, A. (1997). The effect of thermal processing and enzyme treatments of soybean meal on growth performance, ileal nutrient digestibilities, and chyme characteristics in broiler chicks. Poultry Science, 76: 864872.Google Scholar
Mehri, M., Adibmoradi, M., Samie, A. and Shivazad, M. (2010). Effects of β-mannanase on broiler performance, gut morphology and immune system. African Journal of biotechnology, 9: 62216228.Google Scholar
Nitsan, Z., Dror, Y., Nir, I. and Shapira, N. (1974). The effects of force-feeding on enzymes of the liver, kidney, pancreas and digestive tract of chicks. British Journal of Nutrition, 32: 241247.Google Scholar
Noy, Y. and Sklan, D. (2002). Nutrient use in chicks during the first week posthatch. Poultry Science, 81: 391399.Google Scholar
Palacios, M., Easter, R., Soltwedel, K., Parsons, C., Douglas, M., Hymowitz, T. and Pettigrew, J. (2004). Effect of soybean variety and processing on growth performance of young chicks and pigs. Journal of Animal Science, 82: 11081114.Google Scholar
Peisker, M. (2001). Manufacturing of soy protein concentrate for animal nutrition. Cahiers Options Mediterraneennes, 54: 103107.Google Scholar
Perez-Maldonado, R., Mannion, P. and Farrell, D. (2003). Effects of heat treatment on the nutritional value of raw soybean selected for low trypsin inhibitor activity. British Poultry Science, 44: 299308.Google Scholar
Pluske, J.R., Thompson, M.J., Atwood, C.S., Bird, P.H., Williams, I.H. and Hartmann, P.E. (1996). Maintenance of villus height and crypt depth, and enhancement of disaccharide digestion and monosaccharide absorption, in piglets fed on cows' whole milk after weaning. British Journal of Nutrition, 76: 409422.CrossRefGoogle ScholarPubMed
Qin, G. (2003). The anti-nutritional factors and their eliminating methods. Pig and Poultry Marketing Magazine, 23: 1013.Google Scholar
Serviere-Zaragoza, E., del Toro, M. and Garcia-Carreno, F. (1997). Protein-hydrolyzing enzymes in the digestive systems of the adult mexican blue abalone. Aquaculture, 157: 325336.Google Scholar
Sharma, R.P. and Schumacher, U. (2001). Carbohydrate expression in the intestinal mucosa. Advances in Anatomy, Embryology and Cell Biology, 160: 191.Google Scholar
Shirazi-Beechey, S., Smith, M., Wang, Y. and James, P. (1991). Postnatal development of lamb intestinal digestive enzymes is not regulated by diet. Journal of Physiology, 437: 691698.Google Scholar
Short, F., Gorton, P., Wiseman, J. and Boorman, K. (1996). Determination of titanium dioxide added as an inert marker in chicken digestibility studies. Animal Feed Science and Technology, 59: 215221.Google Scholar
Šiugždaité, J., Jerešiúnas, A., Stankevičius, R. and Kulpys, J. (2008). Efficiency of soy protein concentrate in diets of weaned piglets. Czech Journal of Animal Science, 53: 916.Google Scholar
Sklan, D. and Noy, Y. (2000). Hydrolysis and absorption in the small intestines of posthatch chicks. Poultry Science, 79: 13061310.Google Scholar
Sweeney, R.A. (1989). Generic combustion method for determination of crude protein in feeds: Collaborative study. Journal - Association of Official Analytical Chemists, 72: 770774.Google Scholar
Tousi-Mojarrad, M., Seidavi, A. and Dadashbeiki, M. (2012). Effects of soybean meal processing on broiler organs. Annals of Biological Research, 3: 37323739.Google Scholar
Uni, Z., Noy, Y. and Sklan, D. (1999). Posthatch development of small intestinal function in the poult. Poultry Science, 78: 215222.Google Scholar
Xu, F., Li, L., Liu, H., Zhan, K., Qian, K., Wu, D. and Ding, X. (2012). Effects of fermented soybean meal on performance, serum biochemical parameters and intestinal morphology of laying hens. Journal of Animal and Veterinary Advances, 11: 649654.Google Scholar