Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-28T00:06:12.673Z Has data issue: false hasContentIssue false

Insect and legume-based protein sources to replace soybean cake in an organic broiler diet: Effects on growth performance and physical meat quality

Published online by Cambridge University Press:  16 December 2015

F. Leiber*
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland.
T. Gelencsér
Affiliation:
ETH Zurich, Institute of Agricultural Sciences, Universitätstrasse 2, 8092 Zurich, Switzerland.
A. Stamer
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland. Invertec, Invertebrate Protein Technologies, 5070 Frick, Switzerland.
Z. Amsler
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland.
J. Wohlfahrt
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland.
B. Früh
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland.
V. Maurer
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), Ackerstrasse 113, 5070 Frick, Switzerland.
*
*Corresponding author: [email protected]

Abstract

Protein sources other than soybean for the diets of poultry are needed for agricultural systems in temperate regions to help avoid some negative social and ecological impacts of large-scale soybean imports from overseas. The aim of the present study was to test the suitability of alternative protein sources in diets for slow-growing organic broiler chicken. Four experimental broiler diets were tested against a commercial feed for organic broiler chicken fattening (control), containing 255 g kg−1 soybean cake. Each experimental diet was based on the control diet, but 130 g kg−1 of soybean cake was replaced with alternative feeds. The diet ‘HermAlf’ contained 78 g kg−1 Hermetia meal (dried larvae of the black soldier fly, Hermetia illucens) and 52 g kg−1 alfalfa (Medicago sativa) meal. Diet ‘HermPea’ contained 78 g kg−1 Hermetia meal and 52 g kg−1 pea (Pisum sativum) groats. Diet ‘AlfPea’ contained 78 g kg−1 alfalfa meal and 52 g kg−1 pea groats. Diet ‘PeaAlf’ contained 78 g kg−1 pea groats and 52 g kg−1 alfalfa meal. Both diets containing Hermetia meal had the same amount of crude protein (CP) concentration as the control, while CP concentration was lower in diet AlfPea (by 2.7%) and in diet PeaAlf (by 3.5%) compared with the control. Over the course of the experiment, 15 broilers each (slow-growing Hubbard S757) were fattened with one of the five diets ad libitum from days 7 to 82. Additionally, all broilers received water and wheat grains (Triticum aestivum) ad libitum. Feed intake was measured by group. Daily gains, live weights, carcass weights and meat quality were analyzed individually. Compared with the control, feed intake, daily weight gain, carcass weights and feed efficiency were equivalent for all experimental diets. Regarding quality parameters, only cooking loss was increased with the HermPea diet compared with the control. The results indicate that the alternative feeds tested could replace part of the soybean products in broiler diets while achieving equivalent feed efficiency and product quality.

Type
Research Papers
Copyright
Copyright © Cambridge University Press 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

AOAC (Association of Official Analytical Chemists) 1997. Official Methods of Analysis. Arlington, VA, USA.Google Scholar
Barbut, S. 2004. Slaughter-line operation/poultry. In Devine, C. & Dikeman, M. (eds). Encyclopedia of Meat Sciences. Elsevier Academic Press, Amsterdam. p. 12551261.Google Scholar
Belluco, S., Losasso, C., Maggioletti, M., Alonzi, C.C., Paoletti, M.G., and Ricci, A. 2013. Edible insects in a food safety and nutritional perspective: A critical review. Comprehensive Reviews in Food Science and Food Safety 12:296313.CrossRefGoogle Scholar
Carrasco, S., Bellof, G., and Schmidt, E. 2014. Nutrients deposition and energy utilization in slow-growing broilers fed with organic diets containing graded nutrient concentration. Livestock Science 161:114122.CrossRefGoogle Scholar
Cassidy, E.S., West, P.C., Gerber, J.S., and Foley, J.A. 2013. Redefining agricultural yields: From tonnes to people nourished per hectare. Environmental Research Letters 8:034015.Google Scholar
Castellini, C., Mugnai, C., and Dal Bosco, A. 2002. Effect of organic production system on broiler carcass and meat quality. Meat Science 60:219225.CrossRefGoogle ScholarPubMed
Charlton, A.J., Dickinson, M., Wakefield, M.E., Fitches, E., Kenis, M., Han, R., Zhu, F., Kone, N., Grant, M., Devic, E., Bruggeman, G., Prior, R., and Smith, R. 2015. Exploring the chemical safety of fly larvae as a source of protein for animal feed. Journal of Insects as Food and Feed 1:716.Google Scholar
Diener, S., Zurbrügg, C., and Tockner, K. 2009. Conversion of organic material by black soldier fly larvae: Establishing optimal feeding rates. Waste Management and Research 27:603610.Google Scholar
Dotas, V., Bampidis, V.A., Sinapis, E., Hatzipanagiotou, A., and Papanikolaou, K. 2014. Effect of dietary field pea (Pisum sativum L.) supplementation on growth performance, and carcass and meat quality of broiler chickens. Livestock Science 164:135143.Google Scholar
European Commission 2013. Facts and Figures on Organic Agriculture in the European Union. Available at Web site http://ec.europa.eu/agriculture/markets-and-prices/more-reports/pdf/organic-2013_en.pdf (verified 07 August 2015).Google Scholar
Freedman, D., Pisani, R., and Purves, R. 2007. Statistics. Norton & Company, New York, NY.Google Scholar
Früh, B., Schlatter, B., Isensee, A., Maurer, V., and Willer, H. 2015. Report on Organic Protein Availability and Demand in Europe. Research Institute of Organic Agriculture, Frick, Switzerland, 132 p.Google Scholar
Jiang, J.F., Song, X.M., Huang, X., Zhou, W.D., Wu, J.L., Zhu, Z.G., Zheng, H.C., and Jiang, J.Q. 2012. Effects of alfalfa meal on growth performance and gastrointestinal tract development of growing ducks. Asian-Australasian Journal of Animal Science 25:14451450.CrossRefGoogle ScholarPubMed
Kenis, M., Koné, N., Chrysostome, C.A.A.M., Devic, E., Koko, G.K.D., Clottey, V.A., Nacambo, S., and Mensah, G.A. 2014. Insects used for animal feed in West Africa. Entomologia 2:218.Google Scholar
Krauze, M. and Grela, E.R. 2010. Effects of an alfalfa concentrate in turkey diets on performance and some blood parameters. Archiv für Geflügelkunde 74:226232.Google Scholar
Laudadio, V. and Tufarelli, V. 2010. Growth performance and carcass and meat quality of broiler chickens fed diets containing micronized-dehulled peas (Pisum sativum cv. Spirale) as a substitute of soybean meal. Poultry Science 89:15371543.Google Scholar
Laudadio, V., Ceci, E., Lastella, N.M.B., Introna, M., and Tufarelli, V. 2014. Low-fiber alfalfa (Medicago sativa L.) meal in the laying hen diet: Effects on productive traits and egg quality. Poultry Science 93:18681874.CrossRefGoogle ScholarPubMed
Leiber, F., Messikommer, R., and Wenk, C. 2009. Buckwheat: A feed for broiler chicken? Agrarforschung 16:448453.Google Scholar
Makkar, H.P.S., Tran, G., Heuzé, V., and Ankers, P. 2014. State-of-the-art on use of insects as animal feed. Animal Feed Science and Technology 197:133.Google Scholar
Maurer, V., Holinger, M., Amsler, Z., Früh, B., Wohlfahrt, J., Stamer, A., and Leiber, F. 2015. Replacement of soybean cake by Hermetia illucens meal in diets for layers. Journal of Insects as Food and Feed, in press. doi: 10.3920/JIFF2015.0071 Google Scholar
National Research Council 1994. Nutrient Requirements of Poultry. National Academy Press, Washington, DC.Google Scholar
Perenlei, G., Tojo, H., Okada, T., Kubota, M., Kadowaki, M., and Fujimura, S. 2014. Effect of dietary astaxanthin rich yeast, Phaffia rhodozyma, on meat quality of broiler chickens. Animal Science Journal 85:895903.CrossRefGoogle ScholarPubMed
Picoli, K.P., Murakami, A.E., Duarte, C.R.A., Eyng, C., Ospina-Rojas, I.C., and Massuda, E.M. 2014. Effect of dietary restriction and hay inclusion in the diet of slow-growing broilers. Italian Journal of Animal Science 13:771775.Google Scholar
Ponte, P.I.P., Mendes, I., Quaresma, M., Aguiar, M.N.M., Lemos, J.P.C., Ferreira, L.M.A., Soares, M.A.C., Alfaia, C.M., Prates, J.A.M., and Fontes, C.M.G.A. 2004. Cholesterol levels and sensory characteristics of meat from broilers consuming moderate to high levels of alfalfa. Poultry Science 83:810814.Google Scholar
Purwin, C., Fijalkowska, M., Pysera, B., Lipinski, K., Sienkiewicz, S., Piwczynski, D., and Puzio, N. 2014. Nitrogen fractions and amino acid content in alfalfa and red clover immediately after cutting and after wilting in the field. Journal of Elementology 19:723734.Google Scholar
Roberts, S.A., Xin, H., Kerr, B.J., Russel, J.R., and Bregendahl, K. 2007. Effects of dietary fiber and reduced crude protein on nitrogen balance and egg production in laying hens. Poultry Science 86:17161725.Google Scholar
Semino, S., Paul, H., Tomei, J., Joensen, L., Monti, M., and Jelsøe, E. 2009. Soybean biomass produced in Argentina: Myths and realities. In Basse, E.M., Svenning, J.C. and Olesen, J.E. (eds). Beyond Kyoto: Addressing the Challenges of Climate Change—Science Meets Industry, Policy and Public. IOP Conference Series-Earth and Environmental Science. Iop Publishing Ltd, Bristol.Google Scholar
Sheppard, D.C., Tomberlin, J.K., Joyce, J.A., Kiser, B.C., and Sumner, S.M. 2002. Rearing Methods for the Black Soldier Fly (Diptera: Stratiomyidae). Journal of Medical Entomology 39:695698.Google Scholar
Smith, D.P., Lyon, C.E., and Lyon, B.G. 2002. The effect of age, dietary carbohydrate source, and feed withdrawal on broiler breast fillet color. Poultry Science 81:15841588.Google Scholar
Sun, T., Long, R.J., and Liu, Z.Y. 2013. The effect of a diet containing grasshoppers and access to free-range on carcase and meat physicochemical and sensory characteristics in broilers. British Poultry Science 54:130137.Google Scholar
Toscas, P.J., Shaw, F.D., and Beilken, S.L. 1999. Partial least squares (PLS) regression for the analysis of instrument measurements and sensory meat quality data. Meat Science 52:173178.Google Scholar
Tschirner, M. and Simon, A. 2015. Influence of different growing substrates and processing on the nutrient composition of black soldier fly larvae destined for animal feed. Journal of Insects as Food and Feed, in press. doi: 10.3920/JIFF2014.0008 Google Scholar
Vantomme, P. 2015. Way forward to bring insects in the human food chain. Journal of Insects as Food and Feed 1:121129.Google Scholar
Verbeke, W., Spranghers, T., De Clercq, P., De Smet, S., Sas, B., and Eeckhout, M. 2015. Insects in animal feed: Acceptance and its determinants among farmers, agriculture sector stakeholders and citizens. Animal Feed Science and Technology 204:7287.Google Scholar
von Meyer-Höfer, M., Nitzko, S., and Spiller, A. 2015. Is there an expectation gap? Consumers’ expectations towards organic: An exploratory survey in mature and emerging European organic food markets. British Food Journal 117:15271546.Google Scholar
von Witzke, H., Noleppa, S., and Zhirkova, I. 2011. Fleisch frisst Land. [Meat eats land], Berlin, Germany.Google Scholar
Weltin, J., Sundrum, A., and Bellof, G. 2015. Silage von früh genutzter Luzerne (Medicago sativa) als Eiweiss- und Raufuttermittel in der ökologischen Broilermast. In Häring, A.M., Hörning, B., Hoffmann-Bahnsen, R., Luley, H., Luthardt, V., Pape, J., Trei, G. (eds). Beiträge zur 13. Wissenschaftstagung Ökologischer Landbau, Eberswalde. p. 378381.Google Scholar
Wilkinson, J.M. 2011. Re-defining efficiency of feed use by livestock. Animal 5:10141022.Google Scholar
Willems, H., Kreuzer, M., and Leiber, F. 2013. Vegetation-type effects on performance and meat quality of growing Engadine and Valaisian Black Nose sheep grazing alpine pastures. Livestock Science 151:8091.Google Scholar
Willke, T., Hartwich, T., Reershemius, H., Jurchescu, I., Lang, S., and Vorlop, K. 2010. Ökologisch produziertes Methionin aus Mikroorganismen. In Rahmann, G. and Schumacher, U. (eds). Neues aus der ökologischen Tierhaltung. Institut für Ökologischen Landbau, Thünen-Institut, Trenthorst. p. 125136.Google Scholar