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Implications of phytic acid and supplemental microbial phytase in poultry nutrition: a review

Published online by Cambridge University Press:  18 September 2007

S Sebastian ,
S.P. Touchburn  and
E.R CHAVEZ
S Sebastian
Affiliation:
Department of Animal Sience, Macdonald Campus of McGill University, 21,111 Lakeshore Road, Ste. Anne de Bellevue, Québec, CanadaH9X 3V9
S.P. Touchburn
Affiliation:
Department of Animal Sience, Macdonald Campus of McGill University, 21,111 Lakeshore Road, Ste. Anne de Bellevue, Québec, CanadaH9X 3V9
E.R CHAVEZ
Affiliation:
Department of Animal Sience, Macdonald Campus of McGill University, 21,111 Lakeshore Road, Ste. Anne de Bellevue, Québec, CanadaH9X 3V9
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Abstract

Phytic acid or phytate is a naturally occurring organic complex found in plants. As a reactive anion, it forms a wide variety of insoluble salts with divalent and trivalent cations. Phytic acid is also known to complex with proteins and consequently reduce their availability. Recent studies indicate that phytic acid reduces the activity of pepsin, trypsin and αamylase. Because of a lack of endogenous phytase, which hydrolyses phytic acid, phytate phosphorus is biologically less available to poultry. Because of the complex factors influencing phytate hydrolysis, such as dietary calcium content, inorganic phosphorus and vitamin D3, and the age and genotype of birds, there is wide disagreement concerning the ability of poultry to utilize phytate phosphorus. Data suggest that the amount of endogenous phytase is extremely low in young birds but that it increases with age. Cereal based poultry diets supplemented with microbial phytase result in increased digestibility and availability of phytate bound phosphorus, calcium, zinc and copper. Microbial phytase supplementation has also been shown to increase ileal digestibility of crude protein and amino acids in female broiler chickens and in female turkeys, but curiously not in male chickens. There is no report to date of such a study in male turkeys. While the efficacy of supplemental microbial phytase depends on its rate of inclusion, on the calcium and phytate phosphorus contents and on the dietary ca1cium:phosphorus ratio, clear benefits have been shown in terms of increased availability of phytate-bound minerals and crude protein, and reduced environmental pollution through lower levels of phosphorus and nitrogen excretion. To maximize the benefit from the addition of microbial phytase, future research should focus on determining the optimum dietary conditions for it to work.

Keywords

Phytic acidmicrobial phytasepoultrygrowthdigestibility
Type
Research Article
Information
World's Poultry Science Journal , Volume 54 , Issue 1 , March 1998 , pp. 27 - 47
Copyright
Copyright © Cambridge University Press 1998

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References

Anderson, P.A. (1985) Interactions between proteins and constituents that affect protein quality. In: Digestibility and Amino Acid Availability in Cereals and Oilseeds (Finley, G.W. and Hopkins, D.T., Eds), American Association of Cereal Chemists, St. Paul, Minnesota, pp. 3136Google Scholar
Anderson, R.J. (1914) A contribution to the chemistry of phytin. Journal of Biological Chemistry 17: 171190CrossRefGoogle Scholar
Aoyagi, S. and Baker, D. (1995) Effect of microbial phytase and 1,25-dihydroxycholecalciferol on dietary copper utilization in chicks. Poultry Science 74: 121126CrossRefGoogle ScholarPubMed
Ashton, W.M., Evans, C. and Williams, P.C. (1960) Phosphorus compounds of oats. II. The utilization of phytate phosphorus by growing chicks. Journal of the Science of Food and Agriculture 11: 722729CrossRefGoogle Scholar
Atwal, A.S., Eskin, N.A.M., Mcdonald, B.E. and Vaisey-Genser, M. (1980) The effects of phytate on nitrogen utilization and zinc metabolism in young rats. Nutrition Reports International 21: 257267Google Scholar
Ballam, G.C., Engster, H.M. and Snetzinger, D.C. (1984) Effect of calcium level on the ability of broiler and single comb white leghorn to hydrolyse phytate phosphorus. Poultry Science 63: 61 (Abstract)CrossRefGoogle Scholar
Barre, R., Curtois, J.E. and Wormser, G. (1956) Etude de la structure de l'acide phytique aumoyen de ses courbes de titration et de la conductivity de ses solutions. Bulletin de Société de Chimie Biologique 36: 455460Google Scholar
Bartnik, M. and Szafranska, I. (1987) Changes in phytate content and phytase activity during germination of some cereals. Journal of Cereal Science 5: 2328CrossRefGoogle Scholar
Biehl, R.R., Baker, D.H. and Deluca, H.F. (1995) Hydroxylated cholecalciferol compounds act additively with microbial phytase to improve phosphorus, zinc and manganese in chicks fed soy-based diets. Journal of Nutrition 125: 24072416CrossRefGoogle ScholarPubMed
Bitar, K. and Reinhold, J.G. (1972) Phytase and alkaline phosphatase activities in intestinal mucosa of rat, chicken, calf and man. Biochimica Biophysia Acta 268: 442452CrossRefGoogle ScholarPubMed
Broz, J., Oldale, P., Perrin-Voltz, A.H., Rychen, G., Schulze, J. and Simoes Nunes, C. (1994) Effect of supplemental phytase on performance and phosphorus utilization in broiler chickens fed a low phosphorus diet without addition of inorganic phosphates. British Poultry Science 35: 273280CrossRefGoogle ScholarPubMed
Caldwell, R.A. (1992) Effect of calcium and phytic acid on the activation of trypsinogen and the stability of trypsin. Journal of Agricultural Food Chemistry 40: 4346CrossRefGoogle Scholar
Campbell, G.L. and Bedford, M.R. (1992) Enzyme applications for monogastric feeds: A review. Canadian journal of Animal Science 72 449466CrossRefGoogle Scholar
Camovale, E., Lugaro, E. and Lombardi-Boccia, G. (1988) Phytic acid in Faba bean and pea: Effect of protein availability. Cereal Chemistry 65: 114117Google Scholar
Cawley, R.W. and Mitchell, T.A (1968) Inhibition of wheat alpha-amylase by bran phytic acid. Journal of the Science of Food and Agriculture 19: 106CrossRefGoogle Scholar
Chang, C.W. (1967) Study of phytase and fluoride effects in germinating corn seeds. Cereal Chemistry 44: 129142Google Scholar
Chang, R.H. (1975) Removal of phytic acid from beans by potentiation of in situ phytase. Ph.D dissertation, University of California, BerkeleyGoogle Scholar
Cheryan, M. (1980) Phytic acid interactions in food systems. CRC. Critical Reviews in Food Science and Nutrition 13: 297302CrossRefGoogle Scholar
Cooper, J.R. and Gowing, H.S. (1983) Mammalian small intestinal phytase (EC 3.1.3.8). British Journal of Nutrition 50: 673678CrossRefGoogle ScholarPubMed
Cosgrove, D.J. (1980) Inositol Phosphates: Their Chemistry, Biochemistry and Physiology, Elsevier Scientific Publishing Co., New YorkGoogle Scholar
Cosgrove, D.J. (1966) The chemistry and biochemistry of inositol polyphosphates. Review of Pure Applied Chemistry 16: 209215Google Scholar
Couch, J.R. and Creger, C.R. (1970) Levels and sources of phosphorus in laying hen nutrition. Nutrition Reports International 1: 95103Google Scholar
Davies, M.I. and Motzok, I. (1972) Properties of intestinal phytase. Poultry Science 51: 494501CrossRefGoogle ScholarPubMed
Davis, P.N., Norris, L.C. and Kratzer, F.H. (1961) Interference of soybean protein with the utilization of trace minerals. journal of Nutrition 77: 217223CrossRefGoogle Scholar
de Rham, O. and Jost, T. (1979) Phytate-protein interactions in soybean extracts and low- phytate soy protein products. Journal of Food Science 44: 596601CrossRefGoogle Scholar
de Boland, A.R., Gamer, G.B. and O'dell, B.L. (1975) Identification and properties of phytate in cereal grains and oil seed products. Journal of Agricultural Food Chemistry 23: 11861189CrossRefGoogle Scholar
Denbow, D.M., Ravindran, V., Komegay, E.T., Yi, Z. and Hulet, R.M. (1995) Improving phosphorus availability in soybean meal for broilers by supplemental phytase. Poultry Science 74: 18311842CrossRefGoogle ScholarPubMed
Deshpande, S.S. and Cheryan, M. (1984) Effects of phytic acid, divalent cations, and their interactions on alpha-amylase activity. Journal of Food Science 49: 516519CrossRefGoogle Scholar
Edwards, H.M. Jr. (1966) The effect of protein source in the diet of Zn65 absorption and excretion by chickens. Poultry Science 45: 421422CrossRefGoogle Scholar
Edwards, H.M. Jr. (1983) Phosphorus. 1. Effect of breed and strain on utilization of sub-optimal levels of phosphorus in the ration. Poultry Science 62: 7784CrossRefGoogle Scholar
Edwards, H.M. Jr. (1991) Effects of phytase utilization by monogastric animals. Proceedings of the Georgia Nutrition Conference for Feed Manufacturers,Atlanta, pp. 16Google Scholar
Edwards, H.M. Jr. (1993) Dietary 1,25-dihydroxycholecalciferol supplementation increases natural phytate phosphorus utilization in chickens. Journal of Nutrition 123: 567577CrossRefGoogle ScholarPubMed
Edwards, H.M. Jr., Palo, P., Soonchaerenying, S. and Elliot, M.A. (1989) Factors influencing the bioavailability of phytate phosphorus to chickens. In: Nutrient Availability: Chemical and Biological Aspects (Southgate, D., Johnson, I. and Fenwick, G.R., Eds), The Royal Society Chemistry, Cambridge pp. 271276Google Scholar
Eeckhout, W. and De Paepe, M. (1991) The quantitative effects of an industrial microbial phytase and wheat phytase on the apparent phosphorus absorbability of a mixed feed by piglets. Proceedings of Fifth Forum of Applied Bio-technologyPart 11, University of GentBelgium pp. 16431646Google Scholar
Eeckhout, W. and De Paepe, M. (1994) Total phosphorus, phytate-phosphorus and phytase activity in plant feedstuffs. Animal Feed Science and Technology 47: 1929CrossRefGoogle Scholar
Erdman, J.W. Jr. (1979) Oilseed phytates: nutritional implications. Journal of American Oil Chemists' Society 56: 736741CrossRefGoogle Scholar
Ewing, W.R. (1963) Poultry Nutrition, Fifth Edition (Revised), The Ray Ewing Company, Pasadena, CaliforniaGoogle Scholar
Farrell, D.J., Martin, E., Preez, J.J., Bongarts, M., Sudaman, A. and Thomson, E. (1993) The beneficial effects of a microbial phytase in diets of broiler chickens and ducklings. Journal of Animal Physiology and Animal Nutrtion 69: 278286CrossRefGoogle Scholar
Gibbins, L.N. and Norris, F.W. (1963) Phytase and acid phosphatase in the dwarf bean (Phasrolus vulgaris). Biochemical Journal 186: 6771CrossRefGoogle Scholar
Harms, R.H., Waldroup, P.W., Shirley, R.L. and Anderson, C.B. (1962) Availability phytic acid phosphorus for chicks. Poultry Science 41: 11891191CrossRefGoogle Scholar
Hegsted, D.M., Trulson, M.F. and Stare, F.J. (1954) Role of wheat and wheat products nutrition. Physiological Reviews 34: 221258CrossRefGoogle ScholarPubMed
Jongbloed, A.W., Mroz, Z. and Kemme, P.A. (1992) The effect of supplementary Aspergillus niger phytase in diet for pigs on concentration and digestibility of dry matter, total phosphorus, and phytic acid in different sections of the alimentary tract. Journal of Animal Science 70: 11591168CrossRefGoogle ScholarPubMed
Knuckles, B.E and Betschart, A.A. (1987) Effect of phytate and other myo-inositol phosphate esters on alpha-amylase digestion of starch. Journal of Food Science 52: 719721CrossRefGoogle Scholar
Knuckles, B.E., Kuzmicky, D.D. and Betschart, A.A. (1985) Effects of phytate and partially hydrolysed phytate on in vivo protein digestibility. Journal of Food Science 50: 10801082CrossRefGoogle Scholar
Komegay, E.T., Denbow, D.M., Yi, Z. and Ravindran, V. (1996) Response of broilers to graded levels of Natuphos phytase added to corn-soybean meal based diets containing three levels of nonphytate phosphorus. British Journal of Nutrition 75: 839852Google Scholar
Kratzer, F.H., Alfred, J.B., Davis, P.N., Marshall, B.J. and Vohra, V. (1959) The effect of autoclaving soybean protein and the addition of ethylenediaminetetraacetic acid on biological activity of dietary zinc for turkey poults. Journal of Nutrition 68: 313323CrossRefGoogle Scholar
Lease, J.G. (1966) The effect of autoclaving sesame meal on its phytic acid content and on the availability of its zinc to the chick. Poultry Science 45: 237241CrossRefGoogle Scholar
Lei, X.G., Ku, P.K., Millar, E.R., Yokoyama, M.T. and Ullrey, D.E. (1994) Calcium level affects the efficacy of supplemental microbial phytase in corn soybean diets of weanling pigs. Journal of Animal Science 72: 139143CrossRefGoogle ScholarPubMed
Liener, I.E. (1989) Antinutritional factors in legume seeds: state of art. In: Recent Advances of Research in Antinutritional Factors in Legume Seeds (Huisman, J., Van der Poel, T.F. B. and Liener, I.E., Eds), Pudoc, Wageningen, The Netherlands pp. 613Google Scholar
Lolas, G.M. and Markalds, P. (1977) The phytase of navy beans (Phaseohs vulgaris). Journal Food Science 42: 10941097CrossRefGoogle Scholar
Low, A.G. (1985) Role of dietary fibre in pig diets. In: Recent Advances in Animal Nutrition (Haresign, W. and Cole, D.G.A., Eds), Butterworths, London p. 8793CrossRefGoogle Scholar
Maddaiah, V.T., Kumick, A.A., Hulett, B.J. and Reid, B.L. (1964) Nature of intestinal phytase activity. Proceedings of the Society for Experimental Biology and Medicine 115: 10541057CrossRefGoogle ScholarPubMed
Maenz, D.D., Engele-Schaan, C.M. and Classen, H.L. (1995) Phytase activity in the chick intestinal brush border membrane. Poultry Science 74: 76 (Supplement 1)Google Scholar
Mandal, N.C. and Biswas, B.B. (1970) Metabolism of inositol phosphates. 1. Phytase synthesis during germination in cotyledons of mung beans, Phaseolus aureus. Plant Physiology 45: 47CrossRefGoogle ScholarPubMed
Mccuaig, L.W., Davies, M.I. and Motzok, I. (1972) Intestinal alkaline phosphatase and phytase of chicks: effect of dietary magnesium, calcium, phosphorus and thyroactive casein. Poultry Science 51: 526530CrossRefGoogle ScholarPubMed
Mcward, G.W. (1969) Effects of phytic acid and ethylenediaminetetraactic acid (EDTA) on the chick requirement for magnesium. Poultry Science 48: 791794CrossRefGoogle Scholar
Mitchell, R.D. and Edwards, H.M. (1996) Effects of phytase and 1,25-dihydroxycholecalciferol on phytate utilization and the quantitative requirement for calcium and phosphorus in young broiler chickens. Poultry Science 75: 95110CrossRefGoogle ScholarPubMed
Mohammed, A., Gibney, M.J. and Taylor, T.G. (1991) The effect of dietary levels of inorganic phosphorus, calcium and cholecalciferol on the digestibility of phytate-P by the chick. British Journal of Nutrition 66: 251259CrossRefGoogle ScholarPubMed
Moore, R.J. and Veum, T.L. (1983) Adaptive increase in phytate digestibility by phosphorus-deprived rats and the relationship of intestinal phytase (EC 3.1.3.8) and alkaline phosphatase (EC 3.1.3. 1) to phytate utilization. British Journal of Nutrition 49: 145152CrossRefGoogle Scholar
Mroz, Z., Jongbloed, A.W. and Kemme, P.A. (1994) Apparent digestibility and retention of nutrients bound to phytate complexes as influenced by microbial phytase and feeding regimen pigs. Journal of Animal Science 72: 126132CrossRefGoogle ScholarPubMed
Nagai, Y. and Funahashi, S. (1962) Phytase (myo-inositol hexaphosphate phosphohydrolase) from wheat bran. Part 1. Purification and substrate specificity. Agricultural and Biological Chemistry 26: 794797Google Scholar
NRC (NATIONAL RESEARCH COUNCIL) (1994) Nutrient Requirements of Poultry. 9th Revised Edition, National Academy Press, Washington, DCGoogle Scholar
Nayni, N.R. and Markakis, P. (1986) Phytases. In: Phytic Acid: Chemistry and Applications (Graf, E., Ed.), Pilatus Press, Minneapolis pp. 101107Google Scholar
Nelson, T.S. (1967) The utilization of phytate phosphorus by poultry: a review. Poultry Science 46: 862871CrossRefGoogle ScholarPubMed
Nelson, T.S. (1976) The hydrolysis of phytate phosphorus by chicks and laying hens. Poultry Science 55: 22622264CrossRefGoogle ScholarPubMed
Nelson, T.S. (1984) Available calcium for poultry. Proceedings of the Florida Nutrition Conference for Feed ManufacturersOrlandoFlorida pp. 16Google Scholar
Nelson, T.S. and Kirby, L.K. (1987) The calcium binding properties of natural phytate in chick diets. Nutrition Reports International 35: 949956Google Scholar
Nelson, T.S., Daniels, L.B., Hall, J.R. and Shields, L.G. (1976) Hydrolysis of natural phytate phosphorus in the digestive tract of cows. Journal of Animal Science 42: 15091512CrossRefGoogle Scholar
Nelson, T.S, Shieh, T.R., Wodzinsld, R.J. and Ware, J.H. (1968) The availability of phytate phosphorus in soybean meal before and after treatment with a mold phytase. Poultry Science 47: 18421848CrossRefGoogle ScholarPubMed
Nelson, T.S., Shieh, T.R., Wodzinski, R.J. and Ware, J.H. (1971) Effect of supplemental phytase on the utilization of phytate phosphorus by chicks. Journal of Nutrition 101: 12891293CrossRefGoogle ScholarPubMed
Newkirk, R.W. and Classen, H.L. (1995) Nutritional impact of canola meal phytate in broiler chicks. Poultry Science 74: 14 (Suppl. 1)Google Scholar
Nott, H., Morris, T.R. and Taylor, T.G. (1967) Utilization of phytate phosphorus by laying hens and young chicks. Poultry Science 46: 1301 (Abstract)Google Scholar
O'dell, B.L. (1962) Mineral availability and metal binding constituents of the diet. Proceedings of the Cornell Nutrition Conference for feed ManufacturersIthacaNew York pp. 7782Google Scholar
O'dell, B.L. and de Boland, A.R. (1976) Complexation of phytate with proteins and cations in corn germ and oilseed meals. Journal of Agricultural Food Chemistry 24: 804808CrossRefGoogle Scholar
O'dell, B.L., de Boland, A.R. and Koirtyohann, S.R. (1972) Distribution of phytate and nutritionally important elements among the morphological components of cereal grains. Journal Agricultural Food Chemistry 20: 718721CrossRefGoogle Scholar
Oberleas, D. (1973) Phytates. In: Toxicant Occurring Naturally in Foods, 2nd Edition. National Academy of Sciences, Washington D.C., pp. 363371Google Scholar
Oberleas, D. and Harland, B.F. (1996) Impact of phytate on nutrient availability, In: Phytase Animal Nutrition and Waste Management (Coelho, M.B. and Komegay, E.T., Eds), BASF Corporation, Mount Olive, NJGoogle Scholar
Officer, D.I. and Batterham, E.S. (1992) Enzyme supplementation of LinolaTM meal for growing pigs. Proceedings of the Australian Society of Animal Production 9: 288296Google Scholar
Pallauf, V.J., Hohler, D. and Rimbach, G. (1992) Effect of microbial phytase supplementation to a maize-soya diet on the apparent absorption of Mg, Fe, Cu, Mn and Zn and parameters of Zn-status in piglets. Journal of Animal Physiology and Animal Nutrition 68: 18CrossRefGoogle Scholar
Peeler, H.T. (1972) Biological availability of nutrients in feeds: availability of major mineral ions. Journal of Animal Science 35: 695699CrossRefGoogle ScholarPubMed
Peers, G.F. (1953) The phytase of wheat. Biochemical Journal 53: 102110CrossRefGoogle ScholarPubMed
Pemey, K.M., Cantor, A.H., Straw, M.L. and Herkelman, K.L. (1993) The effect of dietary phytase on growth performance and phosphorus utilization of broiler chickens. Poultry Science 72: 21062114Google Scholar
Pointillart, A. (1988) Phytate phosphorus utilization in growing pigs. In: Digestive Physiology the Pig (Buraczewska, L., Buraczewska, S. and Zebrowska, T., Eds), Proceedings of the 4th International Seminar, Polish Academy of Science, Jablonna, Poland pp. 192196Google Scholar
Prasad, A.S. (1966) Metabolism of zinc and its deficiency in human subjects, In: Zinc Metabolism (Prasad, AS., Ed.), Charles C. Thomas, Springfield, IL pp. 250256Google Scholar
Prattley, C.A. and Stanley, D.W. (1982) Protein-phytate interactions in soybeans. 1. Localization of phytate in protein bodies and globoids. Journal of Food Biochemistry 6: 243253CrossRefGoogle Scholar
Qian, H., Kornegay, E.T. and Denbow, D.M. (1995) Utilization of phytate P and Ca as influenced by microbial phytase vitamin D3 and the ca1cium:total phosphorus ratio in broiler diets. Poultry Science 74: 126 (Suppl. 1)Google Scholar
Qian, H., Komegay, E.T. and Denbow, D.M. (1996) Phosphorus equivalence of microbial phytase in turkey diets as influenced by calcium to phosphorus ratios and phosphorus levels. Poultry Science 75: 6981CrossRefGoogle ScholarPubMed
Ravindran, V., Bryden, W.L. and Kornegay, E.T. (1995a) Phytates: occurrence, bioavailability and implications in poultry nutrition. Poultry and Avian Biology Reviews 6: 125143Google Scholar
Ravindran, V., Komegay, E.T., Denbow, D.M., Yi, Z. and Hulet, R.M. (1995b) Response of turkey poults to tiered levels of Natuphos phytase added to soybean meal-based semi-purified diets containing three levels of non-phytate phosphorus. Poultry Science 74: 18431854CrossRefGoogle Scholar
Reddy, N.R., Sathe, S.K. and Salunkhe, D.K. (1982) Phytates in legumes and cereals. Advances in Food Research 28: 191CrossRefGoogle ScholarPubMed
Roberson, K. D and Edwards, H.M. (1994) Effects of 1,25-dihydroxycholecalciferol and phytase on zinc utilization in broiler chicks. Poultry Science 73: 13121326CrossRefGoogle ScholarPubMed
Rojas, S.W. and Scott, J.L. (1969) Factors affecting the nutritive value of cottonseed mealas a protein source for chick diets. Poultry Scieme 48: 819835CrossRefGoogle Scholar
Saio, K., Koyama, E. and Watanabe, T. (1967) Protein-calcium-phytic acid relationship in soybean. 1. Effects of calcium and phosphorus on solubility characteristics of soybean meal protein. Agricultural and Biological Chemistry 31: 110115Google Scholar
Salmon, A.J., Ali, M.S. and Mcginnis, J. (1969) Effect of level and sources of phosphorus and different levels of productivity on phosphorus utilization by laying hens. Poultry Science 48: 10041009CrossRefGoogle Scholar
Sandberg, A.S., Anderson, H., Carlson, N.G. and Sandstrom, B. (1987) Degradation products of bran phytate formed during digestion in the human small intestine: effect of extrusion cooking on digestibility. Journal of Nutrition 117: 20612065CrossRefGoogle ScholarPubMed
Scheideler, S.E. and Sell, J.L. (1987) Utilization of phytate phosphorus in laying hens as influenced by dietary phosphorus and calcium. Nutrition Reports International 35: 10731081Google Scholar
Scheuermann Von, S.E., Lantzsch, H.L. and Menke, K.H. (1988) In vitro and in vivo experiments on the hydrolysis of phytate. 2. Activity of plant phytase. Journal of Animal Physiology and Animal Nutrition 60: 64CrossRefGoogle Scholar
Schoner, F.J., Hoppe, P.P. and Schwartz, G. (1991) Comparitive effects of microbial phytase and inorganic phosphorus on performance and retentions of phosphorus, calcium and crude ash in broilers. Journal of Animal Physiology and Animal Nutrition 66: 248255Google Scholar
Schoner, F.J., Hoppe, P.P., Schwarz, G. and Wiesche, H. (1993) Effects of microbial phytase and inorganic phosphate in broiler chickens: performance and mineral retention at various calcium levels. Journal of Animal Physiology and Animal Nutrition 69: 235244Google Scholar
Schoner, F.J., Schwartz, G., Hoppe, P.P. and Wiesche, H. (1994) Effect of microbial phytase on Ca-availability in broilers. Third Conference of Pig and Poultry NutritionHalleGermanyNovember 29-December 1Google Scholar
Sebastian, S., Touchbum, S.P., Chavez, E.R. and Lague, P.C. (1996a) The effects of supplemental microbial phytase on the performance and utilization of dietary calcium, phosphorus, copper and zinc in broiler chickens fed a corn-soybean diets. Poultry Science 75: 729736CrossRefGoogle ScholarPubMed
Sebastian, S., Touchburn, S.P., Chavez, E.R. and Lague, P.C. (1996b) Efficacy of supplemental microbial phytase at different dietary calcium levels on growth performance and mineral utilization of broiler chickens. Poultry Science 75: 15161523CrossRefGoogle ScholarPubMed
Sebastian, S., Touchburn, S.P., Chavez, E.R. and Lague, P. C. (1997) Apparent digestibility of protein and amino acids in broiler chickens fed a corn-soybean diet supplemented with microbial phytase. Poultry Science 76: 17601769CrossRefGoogle ScholarPubMed
Shafey, T.M., Mcdonald, M.W. and Dingle, J.G. (1991) Effects of dietary calcium and available phosphorus concentration on digesta pH and on the availability of calcium, iron, magnesium and zinc from the intestinal contents of meat chickens. British Poultry Science 32: 185194CrossRefGoogle ScholarPubMed
Simons, P.C. M., Versteegh, H.A. J., Jongbloed, A.W., Kemme, P.A., Stump, P., Bos, K.D., Wolters, M.G. E., Beudeker, R.F. and Verschoor, G.J. (1990) Improvement of phosphorus availability by microbial phytase in broilers and pigs. British Journal of Nutrition 64: 525540CrossRefGoogle ScholarPubMed
Singh, B. and Sedeh, H.G. (1979) Characteristics of phytase and its relationship to acid phosphatases and certain minerals in triticale. Cereal Chemistry 56: 267272Google Scholar
Singh, M. and Krikorian, A.D. (1982) Inhibition of trypsin activity in vitro by phytate. journal of Agricultural Food Chemistry 30: 799800CrossRefGoogle Scholar
Tanaka, Y. and De Luca, H.F. (1974). Role of 1,25-dihydroxy vitamin D3 in maintaining serum phosphorus and curing rickets. Proceedings of the National Academy of Science of the United States of America 71: 10401045CrossRefGoogle Scholar
Tao, S.H., Fox, M.R. S., Phillippy, B.Q., Fry, B.E., Johnson, M.L. and Johnston, M.R. (1986) Effects of inositol phosphates on mineral utilization. Federation Proceedings 45: 819826Google Scholar
Taylor, T.G. (1965) The availability of the calcium and phosphorus of plant materials by animals. Proceedings of the Nutrition Society 24: 105110CrossRefGoogle ScholarPubMed
Temperton, H. and Cassidy, J. (1964) Phosphorus requirements of poultry.III. The effect of feeding a vegetable type diet without supplemental phosphorus to turkeys. British Poultry Science 5: 8788CrossRefGoogle Scholar
Temperton, H., Dudley, J. and Pickering, G.L. (1965a) Phosphorus requirements of poultry.IV. The effects on growing pullets of feeding diets containing no animal protein or supplementary phosphorus. British Poultry Science 6: 125133CrossRefGoogle ScholarPubMed
Temperton, H., Dudley, J. and Pickering, G.J. (1965b) Phosphorus requirements of poultry.V. The effects during the subsequent laying year of feeding growing diets containing no animal protein or supplementary phosphorus. British Poultry Science 6: 135141CrossRefGoogle ScholarPubMed
Thiel, U. and Weigand, E. (1992) Influence of dietary zinc and microbial phytase supplementation on zinc retention and zinc excretion in broiler chickens. Proceedings of XIX World's Poultry CongressWorld's Poultry Science Association, AmsterdamThe NetherlandsGoogle Scholar
Thiel, U., Weighand, E., Hoppe, P.P. and Schoner, F.J. (1993) Zinc retentionof broiler chickens as affected by dietary supplements of zinc and microbial phytase. In: Trace Elements in Man and Animals (Anke, M., Meissner, D. and Mills, C.F., Eds), Commonwealth Agricultural Bureaux, Farnham Royal, Slough SL2 3BW, UK pp. 658660Google Scholar
Thompson, L.U. and Serraino, M.R. (1986) Effect of phytic acid on rape seed protein digestibility and amino acid absorption. journal of Agricultural Food Chemistry 34: 468CrossRefGoogle Scholar
Thomson, L.U. and Yoon, J.H. (1984) Starch digestibility as affected by poly phenols and phytic acid. Journal of Food Science 49: 12281229CrossRefGoogle Scholar
Van Der Klis, J.D. and Versteegh, H.A. J. (1991) Ileal absorption of phosphorus in lightweight white laying hens using microbial phytase and various calcium contents in laying hen feed. Spelderholt Publication No. 563, Spelderholt,, Beekbergen, The NetherlandsGoogle Scholar
Vandepopuliere, J.M., Ammerman, C.B. and Harms, R.M. (1961) The relationship of ca1cium:phosphorus ratios to the utilization of plant and inorganic phosphorus by the chick. Poultry Science 40: 951957CrossRefGoogle Scholar
Vohra, P., Gray, G.A. and Kratzer, F.H. (1965) Phytic acid-metal complexes. Proceedings of the Society for Experimental Biology and Medicine 120: 447449CrossRefGoogle ScholarPubMed
Wasserman, R.H. and Taylor, A.N. (1973) Intestinal absorption of phosphate in the chicks. Effect of vitamin D and other parameters. Journal of Nutrition 103: 586599CrossRefGoogle ScholarPubMed
Wise, A. (1983) Dietary factors determining the biological activities of phytate. Nutrition Abstracts and Reviews 53: 791806Google Scholar
Yi, Z., Komegay, E.T., Lindemann, M.D. and Ravindran, V. (1994a) Effect of Natuphos phytase for improving the bioavailabilities of phosphorus and other nutrients on soybean meal-based semi-purified diets for young pigs. Journal of Animal Science 72: 7 (Suppl. 1)Google Scholar
Yi, Z., Komegay, E.T. and Meguirk, A. (1994b) Replacement values of inorganic phosphorus by microbial phytase for pigs and poultry. Journal of Animal Science 72: 330 (Suppl. 1)Google Scholar
Yi, Z., Komegay, E.T. and Denbow, D.M. (1996a) Supplemental microbial phytase improves the zinc utilization in broilers. Poultry Science 75: 540546CrossRefGoogle ScholarPubMed
Yi, Z., Kornegay, E.T. and Denbow, D.M. (1996b) Effect of microbial phytase on nitrogen and amino acid digestibility and nitrogen retention of turkey poults fed corn-soybean meal diets. Poultry Science 75: 979990CrossRefGoogle ScholarPubMed
Yi, Z., Komegay, E.T. and Denbow, D.M. (1995) Effect of microbial phytase on phosphorus and nitrogen retention and performance of turkey poults fed cornsoybean meal. Poultry Science 74: 108 (Abstract)Google Scholar
Yoshida, T., Tanaka, K. and Kasai, Z. (1975) Phytase activity associated with isolated aleurone particles of rice grains. Agricultural and Biological Chemistry 39: 289290Google Scholar