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Feed resources for poultry production in Asia and the Pacific region. I. Energy sources

Published online by Cambridge University Press:  23 March 2009

V. Ravindran
Affiliation:
Department of Animal Science, University of British Columbia, Vancouver, British Columbia, Canada V6T 2A2
R. Blair
Affiliation:
Department of Animal Science, University of British Columbia, Vancouver, British Columbia, Canada V6T 2A2
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Abstract

Throughout Asia and the Pacific region, inadequate supply of maize will limit further expansion of the poultry industries during the coming decade. In this context, the use of locally available energy feedstuffs merits increased attention. This review examines the potential feeding value and nutritional limitations of some carbohydrate sources, with special reference to Asia and the Pacific region. Some guidelines that may lead to better utilization of these feed resources are also discussed.

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Reviews
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Copyright © Cambridge University Press 1991

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References

Anon (1987) Manual of Poultry Production in the Tropics, CAB International, Wallingford, UKGoogle Scholar
Alejar, A.S., Ranit, G.O. and Manese, L.B. (1969) Sorghum as source of energy in broiler rations. Philippine Agriculturist 53: 371380Google Scholar
Al-Hiti, M.K. and Rous, J. (1978) Date waste without stones in broiler diets. British Poultry Science 19: 1719CrossRefGoogle Scholar
Ayyaluswami, P. and Jaganathan, V. (1967) Studies on maize, ragi and cowdung meal in chick mash. Indian Veterinary Journal 44: 331335Google Scholar
Balnave, D. (1982) Egg weight and production responses of laying hens fed rice pollards. Journal of the Science of Food and Agriculture 33: 231236CrossRefGoogle Scholar
Blackburn, F. (1984) Sugarcane, Longman, New YorkGoogle Scholar
Burnett, G.S. (1966) Studies of viscosity as the probable factor involved in the improvement of certain barleys for chickens by enzyme supplementation. British Poultry Science 7: 5570CrossRefGoogle Scholar
Buvanendran, V. (1961) Effect of different levels of rice bran on growth and egg production in poultry. Ceylon Veterinary Journal 9: 107113Google Scholar
Cao, Z.C., Jiang, Y.X., Jin, Y.Y. and Liu, J.X. (1985) Comparison of using high and low tannin content sorghums as broiler feed. Acta Veterinaria et Zootechnica Sinica 16: 8992Google Scholar
Chand, G. and Shukla, P.C. (1973) Use of unconventional feeds in broiler rations. Indian Journal of Animal Science 43: 10131017Google Scholar
Chandra, S. (Ed.) (1984). Edible Aroids, Clarendon Press, OxfordGoogle Scholar
Cornelius, J.A. (1980) Rice bran oil for edible purposes: a review. Tropical Science 22: 126Google Scholar
Coursey, D.G. (1967) Yams, Longmans, LondonGoogle Scholar
Coursey, D.G. and Haynes, P.H. (1970) Root crops and their potential in the tropics. World Crops 22: 261265Google Scholar
Deolankar, R.P. and Singh, K.S. (1979). Trypsin inhibitor, mineral availability, and performance of broiler chickens fed on diets based on rice bran. Animal Feed Science and Technology 4: 133141CrossRefGoogle Scholar
Devendra, C. (1988). Non-conventional Feed Resources in Asia and the Pacific, APHCA/FAO Monograph, FAO Regional Office, Bangkok, ThailandGoogle Scholar
D'Mello, J.P.F. and Acamovic, T. (1989) Leucaena leucocephala in poultry nutrition – a review. Animal Feed Science and Technology 26: 128CrossRefGoogle Scholar
Eshwaraiah, A., Reddy, C.V. and Rao, P.V. (1986) Feeding value of raw rice polish, de-oiled rice polish and parboiled rice for broiler starter chicks. Indian Journal of Poultry Science 21: 114119Google Scholar
FAO (1988a). FAO Production Yearbook, Vol. 41, Food and Agriculture Organization of the United Nations, RomeGoogle Scholar
FAO (1988b) FAO Trade Yearbook, Vol. 41, FAO, RomeGoogle Scholar
FAO (1988c) Traditional food plants. FAO Food and Nutrition Paper 42: 359361Google Scholar
Fuller, H.L. (1975) The use of fats and oils as a source of energy in mixed feeds. In: Proceedings of the Conference on Animal Feeds of Tropical and Subtropical Origin, Tropical Products Institute, London, pp. 123128Google Scholar
Fuller, H.L., Chiang, S.I. and Potter, D.K. (1967) Detoxification of dietary tannic acid by chicks. Journal of Nutrition 91: 477481CrossRefGoogle Scholar
Gardiner, E.E., Dubetz, S. and Major, D.J. (1981) Sorghum, wheat and corn in diets for broiler chicks. Canadian Journal of Animal Science 61: 511513CrossRefGoogle Scholar
Gerpacio, A.L., Roxas, A.B., Uichanco, N.M. et al. (1975) Tuber meals as carbohydrate sources in broiler rations. In: Proceedings of the Conference on Animal Feeds of Tropical and Subtropical Origin, Tropical Products Institute, London, pp. 151154Google Scholar
Gohl, B. (1981) Tropical Feeds, Food and Agriculture Organization of the United Nations, RomeGoogle Scholar
Gualtieri, M. and Rapaccini, M. (1990) Sorghum grain in poultry feeding. World's Poultry Science Journal 46: 246254CrossRefGoogle Scholar
Harris, L.E., Leche, T.F., Kearl, L.C., Fonnesbeck, P.V. and Lloyd, H. (1982) Central and Southeast Asia. Tables of Feed Composition, International Feedstuffs Institute, Logan, Utah, USAGoogle Scholar
Hew, V.F. (1977) Problematic aspects of carbohydrate sources used for pigs in Malaysia. In: Feedingstuffs for Livestock in South-East Asia. (Eds Devendra, C. and Hutagalung, R.I.), Malaysian Society of Animal Production, Selangor, Malaysia, pp. 177190Google Scholar
Hijikuro, S. (1983) Improvement of feeding value of barley by enzyme supplementation. Japanese Agricultural Research Quarterly 17: 5558Google Scholar
Hijikuro, S. and Takemasa, M. (1982) Effect of enzyme supplementation on the feeding value of various barley varieties for chicks. Japanese Poultry Science 19: 222226CrossRefGoogle Scholar
Hodgkinson, A. (1977) Oxalic Acid in Biology and Medicine, Academic Press, LondonGoogle Scholar
Holloway, W.D., Argall, M.E., Jealous, W.T., Lee, J.A. and Bradbury, J.H. (1989) Organic acids and calcium oxalates in tropical root crops. Journal of Agriculture and Food Chemistry 37: 337341CrossRefGoogle Scholar
Hulse, J.H., Laing, E.M. and Pearson, O.E. (1980) Sorghum and Millets: Their Composition and Nutritive Value, Academic Press, New YorkGoogle Scholar
Hutagalung, R.I. (1977) Additives other than methionine in cassava diets. In: Cassava as Animal Feed (Eds Nestel, B. and Graham, M.), International Development Research Centre, Ottawa, pp. 1832Google Scholar
Hutagalung, R.I. (1978) Non-traditional feedstuffs for livestock. In: Feedstuffs for Livestock in South-East Asia (Eds Devendra, C. and Hutagalung, R.I.), Malaysian Society of Animal Production, Selangor, Malaysia, pp. 259268Google Scholar
Hutagalung, R.I. (1981) The use of tree crops and their byproducts for intensive animal production. In: Intensive Animal Production for Developing Countries (Eds Smith, A.J. and Gunn, R.G.), British Society of Animal Production Occasional Publication No. 4, D. & J. Croal Ltd, Haddington, UKGoogle Scholar
Hutagalung, R.I., Jalaludin, S. and Chang, C.C. (1974) Evaluation of agricultural products and byproducts as animal feeds. II. Effects of levels of dietary cassava leaf and root on performance, digestibility and body composition. Malaysian Agricultural Research 3: 4959Google Scholar
Jalaludin, S., Wong, W.C., Mahmud, A. and Ch'ng, G.C. (1970) Utilization of sago for growth in the fowl. Malaysian Agricultural Research 47: 492499Google Scholar
Jensen, L.S., Fry, R.E., Alfred, J.B. and McGinnis, J. (1957) Improvement in the nutritional value of barley for chicks by enzyme supplementation. Poultry Science 36: 919921CrossRefGoogle Scholar
Juliano, B.O. (Ed.) (1985) Rice: Chemistry and Technology, The American Association of Cereal Chemists, Inc., St. Paul, Minnesota, USAGoogle Scholar
Khajarern, S. and Khajarern, J.M. (1985) Roots and tubers as cereal substitutes. FAO Animal Production and Health Paper 63: 7990Google Scholar
Kamel, B.S., Dias, M.F., Ilian, M.A. and Salman, A.J. (1981) Nutritional value of whole dates and date pits broiler rations. Poultry Science 60: 10051011CrossRefGoogle Scholar
Kim, K.S., Han, I.K., Ha, J.K. and Kwack, C.H. (1986) The effect of substituting sorghum grain for corn and supplementation of methionine and lysine on the performance of broiler chicks. Korean Journal of Animal Sciences 28: 732735Google Scholar
Kratzer, F.H., Earl, L. and Chiaravanond, C. (1974) Factors influencing the feeding value of rice bran for chickens. Poultry Science 53: 17951800CrossRefGoogle Scholar
Kuruwita, H.S. and Ravindran, V. (1987) Nutritive evaluation of avocado seed meal. Proceedings of Sri Lankan Association for the Advancement of Science 43: 78 (abstract)Google Scholar
Latif, M.A. and Islam, M.S. (1971) Economic feasibility of partial replacement of cereal grains by sweet potatoes and molasses in growing chick rations. Bangladesh Journal of Animal Sciences 4: 3241Google Scholar
Lin, Y.H. and Chen, H.L. (1980) Level and heat stability of trypsin inhibitor activity among sweet potato varieties. Bulletin Academia Sinica, New Series 21: 113Google Scholar
Loesecke, H. Von. (1950) Bananas, Interscience, New YorkGoogle Scholar
Lopez, J., Trinidade, D.S., Oliveira, S.C. and Cavalheiro, A.C. (1976). Feeds used in Brazil as corn replacers in the formulation of broiler diets. In: Proceedings First International Symposium on Feed Composition, Animal Nutrient Requirements and Computerization of Diets (Eds Fonnesbeck, P.V., Harris, L.E. and Kearl, L.C.), Utah State University, Logan, Utah, USAGoogle Scholar
Lopez, P.D.L. (1985) Legislation and quality control of feeds: the experience of Asian countries. FAO Animal Production and Health Paper 63: 156162Google Scholar
Maner, J. (1985) Nutritional advantages and problems related to the use of various types of cereals in feeds. FAO Animal Production and Health Paper 63: 6878Google Scholar
McDonald, M.W. (1964) The replacement value of grains in poultry diets. World's Poultry Science Journal 20: 122127CrossRefGoogle Scholar
Mohamedain, G.M., Babiker, S.A. and Mohammed, T. (1986) Effect of feeding millet, maize and sorghum grains on performance, carcase yield and chemical composition of broiler meat. Tropical Agriculture (Trinidad) 63: 173176Google Scholar
Montilla, J.J. (1977) Cassava in the nutrition of broilers. In: Cassava as Animal Feed (Eds Nestel, B. and Graham, M.) International Development Research Centre, Ottawa, pp. 4350Google Scholar
Mukherjee, R. and Parthasarathy, D. (1948) The digestible nutrients of certain cereal grains as determined by experiments on Indian fowls. Indian Veterinary Journal 18: 4145Google Scholar
Muller, Z., Chou, K.C. and Nah, K.C. (1974) Cassava as a total substitute for cereals in livestock and poultry rations. World Animal Review 12: 1935Google Scholar
Nagy, S. and Shaw, P.E. (1980) Tropical and Subtropical Fruits, AVI Publishing, Inc., Westport, ConnecticutGoogle Scholar
Negi, S.S. (1982) Tannins in sal seed and sal seed meal limit their utilization as livestock feeds. Animal Feed Science and Technology 7: 161183CrossRefGoogle Scholar
Nelson, T.S., Stephenson, E.L., Burgos, A., Floyd, J. and York, J.O. (1975) Effect of tannin content and dry matter digestion on energy utilization and average amino acid availability of hybrid sorghum grains. Poultry Science 54: 16201623CrossRefGoogle Scholar
Oke, O.L. (1969) The role of hydrocyanic acid in nutrition. World Review of Nutrition and Dietetics 11: 170198CrossRefGoogle ScholarPubMed
Oke, O.L. (1978) Problems in the use of cassava as animal feed. Animal Feed Science and Technology 3: 345380CrossRefGoogle Scholar
Omole, T.A. (1977) Cassava in the nutrition of layers. In: Cassava as Animal Feed (Eds Nestel, B. and Graham, M.), International Development Research Centre, Ottawa, pp. 5155Google Scholar
Onwueme, I.C. (1978) Tropical Tuber Crops, John Wiley & Sons, New YorkGoogle Scholar
Palipane, K.B. and Swarnasiri, C.D.P. (1985) Composition of raw and parboiled rice bran from common Sri Lankan varieties and from different types of rice mills. Journal of Agriculture and Food Chemistry 33: 732734CrossRefGoogle Scholar
Panda, B., Jayaraman, M., Ramamurty, N.S. and Nair, R.B. (1969) Processing and utilization of sal seed meal as a source of energy in poultry feed. Indian Veterinary Journal 46: 10731077Google Scholar
Patil, S.N., Netke, S.P. and Dabadghad, A.K. (1982) Processing and feeding value of mango seed kernal for starting chicks. British Poultry Science 23: 185194CrossRefGoogle Scholar
Paul, A.K., Gupta, S.N.S., Mondal, G.B. and Sarkar, S.K. (1972) Effect of feeding sal seed cake on chicks. Indian Journal of Animal Sciences 42: 10611065Google Scholar
Phillips, T.P. (1974) Cassava Utilization and Potential Markets, IDRC-020e, International Development Research Centre, OttawaGoogle Scholar
Pino, J.A. (1962) Sources of energy for poultry in the Pacific area. World's Poultry Science Journal 18: 405418Google Scholar
Qureshi, M.S. (1967) To assess the value of maize and bajra alone or in combination in the starting and growing rations for chickens. Agriculture Pakistan 18: 519529Google Scholar
Rachie, K.O. (1974) The Millets and Minor Cereals: A Bibliography of World Literature, The Scare Crow Press, Inc., Metuchen, New JerseyGoogle Scholar
Rajaguru, A.S.B. (1972/1973) Elimination of hydrocyanic acid from processed manioc chips. Journal of National Agricultural Society of Ceylon 9/10: 5360Google Scholar
Rajaguru, A.S.B. and Ravindran, V. (1984) Sweet potato meal as a source of energy in poultry diets. Sri Lankan Journal of Agricultural Science 21: 4047Google Scholar
Ramachandra, G., Virupaksha, T.K. and Shadaksharaswamy, M. (1977) Relationship between tannin levels and in vitro protein digestibility in finger millet. Journal of Agriculture and Food Chemistry 25: 11011104CrossRefGoogle ScholarPubMed
Ravindran, V., Kornegay, E.T. and Rajaguru, A.S.B. (1983) Utilization of the whole cassava plant as a swine feed. World Review of Animal Production 19: 714Google Scholar
Ravindran, V., Kornegay, E.T., Rajaguru, A.S.B., Potter, L.M. and Cherry, J.A. (1986) Cassava leaf meal as a replacement for coconut oil meal in broiler diets. Poultry Science 65: 17201727CrossRefGoogle Scholar
Ravindran, V., Kornegay, E.T., Webb, K.E. and Rajaguru, A.S.B. (1982a) Nutrient characterization of some feedstuffs from Sri Lanka. Journal of National Agricultural Society of Sri Lanka 19: 1932Google Scholar
Ravindran, V. and Rajaguru, A.S.B. (1985) Nutrient contents of some non-conventional poultry feeds. Indian Journal of Animal Science 55: 5861Google Scholar
Ravindran, V., Rajaguru, A.S.B., De Silva, K.C. and Fernando, B. (1982b) Taro as a feed ingredient in tropical broiler diets. Journal of Animal Science 55 (Supplement 1): 293Google Scholar
Reddy, C.V. (1975) Utilization of by-products in poultry feeding in India. World Review of Animal Production 11: 6672Google Scholar
Reddy, N.R., Sathe, S.K. and Salunkhe, D.K. (1982) Phytates in legumes and cereals. Advances in Food Research 28: 192CrossRefGoogle ScholarPubMed
Rogers, D.J. (1963) Studies of Manihot esculenta Crantz and related species. Bulletin Torrey Botanical Club 90: 4347CrossRefGoogle Scholar
Rosenburg, M.M. (1956) Evaluation of Cuban high test syrup in chick rations. Poultry Science 35: 558562CrossRefGoogle Scholar
Rotter, B.A., Marquardt, R.R., Nesker, M. and Guenter, W. (1987) Improvement of the nutritional value of barley grain through the use of crude enzymes of microbial origin. In: Biotechnology in the Feed Industry (Ed. Lyons, T.P.), Alltech Technical Publications, Nicholasville, Kentucky, USA, pp. 251256Google Scholar
Sakai, W.S. (1979) Aroid crops: acridity and raphides. In: Tropical Feeds: Chemistry and Nutrition, Vol. 1 (Eds Inglett, G.E. and Charalambous, G.), Academic Press, New York, pp. 265278CrossRefGoogle Scholar
Salunkhe, D.K. and Desai, B.B. (1984) Postharvest Biotechnology of Fruits, Volumes I and II, CRC Press, Boca Raton, FloridaGoogle Scholar
Salunkhe, D.K., Jadhav, S.J., Kadam, S.S. and Chavan, J.K. (1982) Chemical, biochemical and biological significance of polyphenols in cereals and legumes. CRC Critical Reviews in Food Science and Nutrition 17: 277305CrossRefGoogle ScholarPubMed
Sanford, P.E., Camacho, F., Knake, R.P., Deyoe, C.W. and Casady, A.J. (1973) Performance of meat-strain chicks fed pearl millet as a source of energy and protein. Poultry Science 52: 2081Google Scholar
Shaheen, A.B., El Dah, A.A. and El Shirbeeny, A.E. (1975) Effect of parboiling of rice on the rate of lipid hydrolysis and deterioration of rice bran. Cereal Chemistry 52: 18Google Scholar
Sharma, B.D., Sadagopan, V.R. and Reddy, V.R. (1979) Utilization of different cereals in broiler diets. British Poultry Science 20: 371378CrossRefGoogle Scholar
Shrivastav, A.K., Panda, B. and Darshan, N. (1990) Comparative nutritive values of different cereals in quail diets. Indian Journal of Animal Sciences 60: 720724Google Scholar
Singh, P., Singh, U., Eggum, B.O., Kumar, K.A. and Andrews, D.J. (1987) Nutritional evaluation of high protein genotypes of pearl millet. Journal of the Science of Food and Agriculture 38: 4148CrossRefGoogle Scholar
Singh, S.D. and Barsaul, C.S. (1976) Replacement of maize by coarse grains for growth production in White Leghorn and Rhode Island Red birds. Indian Journal of Animal Sciences 46: 9699Google Scholar
Sinha, S.K. and Nair, T.V.R. (1968) Studies on the variability of cyanogenic glucoside content in cassava tubers. Indian Journal of Agricultural Science 38: 958963Google Scholar
Sinha, S.B., Rao, P.V., Sadagopan, V.R. and Panda, B. (1980) Comparative efficiency of a few cereals and rice polish in chicks. Indian Journal of Animal Sciences 50: 353356Google Scholar
Springhall, J.A. and Ross, E. (1965a) Preliminary studies with poultry rations for the territory of Papua and New Guinea. 1. Grower rations with copra, sago and Leucaena leucocephala. Papua New Guinea Agricultural Journal 17: 117121Google Scholar
Springhall, J.A. and Ross, E. (1965b) Preliminary studies with poultry rations for the territory of Papua and New Guinea. 2. Layer rations with copra, sago and Leucaena leucocephala. Papua New Guinea Agricultural Journal 17: 122126Google Scholar
Sunell, L.A. and Healey, P.L. (1979) Distribution of calcium oxalate idioblasts in corms of taro Colocasia esculenta. American Journal of Botany 66: 10291032CrossRefGoogle Scholar
Syed, A.A.B., Yeong, S.W. and Seet, C.P. (1975) Performance of layers fed high levels of broken rice and tapioca as a direct substitution of maize. Malaysian Agricultural Research and Development Institute Research Bulletin 3: 6370Google Scholar
Szylit, O., Durand, M., Borgida, L.P., Bewa, H., Charbonniere, R. and Delort-Laval, L. (1979) Nutritional value for growing chickens of five tropical starchy feeds in relation to some physicochemical properties of starch. Annales de Zootechnie 26: 547563CrossRefGoogle Scholar
Thakur, R.S., Gupta, P.C. and Lodhi, G.P. (1984) Feeding value of different varieties of sorghum in broiler rations. Indian Journal of Poultry Science 19: 103107Google Scholar
Thomas, C.A. (1980) Jackfruit, Artocarpus heterophyllus, as a source of food and income. Economic Botany 34: 154159CrossRefGoogle Scholar
Todorov, N.A. (1988) Livestock feed resources and feed evaluation in Europe. II. Feedstuffs. 3. Cereals, pulses and oilseeds. Livestock Production Science 19: 4796CrossRefGoogle Scholar
Velauther, Y. and Ravindran, V. (1987) Evidence for presence of anti-nutritional factor(s) in raw jack seeds. Proceedings Sri Lankan Association for Advancement of Science 43: 97 (abstract)Google Scholar
Vogt, H. (1966) The use of tapioca meal in poultry rations. World's Poultry Science Journal 22: 113125CrossRefGoogle Scholar
Wah, C.S., Sharma, K. and Jackson, M.G. (1977) Studies of various chemical treatments of sal seed meal to remove or inactivate tannins. Indian Journal of Animal Sciences 47: 811Google Scholar
Waldroup, P.W. (1981) Use of molasses and sugars in poultry diets. World's Poultry Science Journal 37: 193202CrossRefGoogle Scholar
Warren, B.E. and Farrel, D.J. (1990a) The nutritive value of full-fat and defatted Australian rice bran. I. Chemical composition. Animal Feed Science and Technology 27: 219228CrossRefGoogle Scholar
Warren, B.E. and Farrel, D.J. (1990b) The nutritive value of full-fat and defatted Australian rice bran. IV. Egg production of hens on diets with defatted rice bran. Animal Feed Science and Technology 27: 259268CrossRefGoogle Scholar
Yoshida, M. (1962) Sources of energy in Pacific area for poultry. World's Poultry Science Journal 18: 399406Google Scholar
Yoshida, M. and Hoshii, H. (1970) Nutritive value of rice for poultry feed. Japanese Poultry Science 7: 139143CrossRefGoogle Scholar
Yoshida, M., Hoshii, H., Kosaka, K. and Morimoto, H. (1966) Nutritive value of various energy sources for poultry feed. IV. Estimation of available energy of cassava meal. Japanese Poultry Science 3: 2934CrossRefGoogle Scholar
Zombade, S.S., and Ichhponani, J.S. (1983) Nutritive value of raw, parboiled, stabilised and deoiled rice bran for growing chicks. Journal of the Science of Food and Agriculture 34: 783788CrossRefGoogle Scholar
Zombade, S.S., Lodhi, G.N. and Ichhponani, J.S. (1981) Evaluation of raw and parboiled rice bran. 3. Effect on growth and subsequent productive performance of White Leghorn pullets. Indian Journal of Poultry Science 16: 5768Google Scholar