Phytase inclusions of 500 and 2000 FTU/kg in maize-based broiler diets impact on growth performance, nutrient utilisation, digestive dynamics of starch, protein (N), sodium and IP6 phytate degradation in the gizzard and four small intestinal segments

[1]  P. Plumstead,et al.  Impacts of dietary calcium, phytate, and nonphytate phosphorus concentrations in the presence or absence of phytase on inositol hexakisphosphate (IP6) degradation in different segments of broilers digestive tract , 2016, Poultry science.

[2]  P. Selle,et al.  The Economic Feasibility of Elevated Phytase Inclusions in Maize-Based Broiler Diets , 2016 .

[3]  P. Selle,et al.  Standard phytase inclusion in maize-based broiler diets enhances digestibility coefficients of starch, amino acids and sodium in four small intestinal segments and digestive dynamics of starch and protein , 2015 .

[4]  P. Selle,et al.  Effects of 500 and 1000 FTU/kg phytase supplementation of maize-based diets with two tiers of nutrient specifications on performance of broiler chickens , 2015 .

[5]  R. Greiner,et al.  Performance of Seven Commercial Phytases in an in Vitro Simulation of Poultry Digestive Tract. , 2015, Journal of agricultural and food chemistry.

[6]  E. Zeller,et al.  Hydrolysis of phytate and formation of inositol phosphate isomers without or with supplemented phytases in different segments of the digestive tract of broilers , 2015, Journal of Nutritional Science.

[7]  P. Selle,et al.  Phytase supplementation of maize-, sorghum- and wheat-based broiler diets with identified starch pasting properties influences phytate (IP6) and sodium jejunal and ileal digestibility , 2014 .

[8]  P. Selle,et al.  Effects of phytase supplementation on growth performance, nutrient utilization and digestive dynamics of starch and protein in broiler chickens offered maize-, sorghum- and wheat-based diets , 2014 .

[9]  M. Bedford,et al.  Influence of superdoses of a novel microbial phytase on growth performance, tibia ash, and gizzard phytate and inositol in young broilers. , 2014, Poultry science.

[10]  Anil . Kumar,et al.  Effect of calcium level and phytase addition on ileal phytate degradation and amino acid digestibility of broilers fed corn-based diets. , 2014, Poultry science.

[11]  W. Gerrits,et al.  Improving digestive utilization of fiber-rich feedstuffs in pigs and poultry by processing and enzyme technologies: A review , 2012 .

[12]  S. Dalsgaard,et al.  Interactions of phytate and myo-inositol phosphate esters (IP1-5) including IP5 isomers with dietary protein and iron and inhibition of pepsin. , 2012, Journal of animal science.

[13]  N. Cowieson,et al.  Protein–phytate interactions in pig and poultry nutrition: a reappraisal , 2012, Nutrition Research Reviews.

[14]  V. Ravindran,et al.  Consequences of calcium interactions with phytate and phytase for poultry and pigs , 2009 .

[15]  A. Cowieson,et al.  Effect of diet containing phytate and phytase on the activity and messenger ribonucleic acid expression of carbohydrase and transporter in chickens. , 2008, Journal of animal science.

[16]  J. W. Burton,et al.  A simple and rapid procedure for phytate determination in soybeans and soy products , 2005 .

[17]  H. Asemota,et al.  DIGESTIVE AND ABSORPTIVE ENZYMES IN RATS FED PHYTIC ACID EXTRACT FROM SWEET POTATO (IPOMOEA BATATAS) , 2005 .

[18]  M. Christman,et al.  Influence of dietary calcium and phytase on phytate phosphorus hydrolysis in broiler chickens. , 2004, Poultry science.

[19]  D. Sklan,et al.  Nutrient transport in the small intestine: Na+,K+-ATPase expression and activity in the small intestine of the chicken as influenced by dietary sodium. , 2003, Poultry science.

[20]  W. Bryden,et al.  Total and phytate-phosphorus contents and phytase activity of Australian-sourced feed ingredients for pigs and poultry , 2003 .

[21]  A. Therien,et al.  Mechanisms of sodium pump regulation. , 2000, American journal of physiology. Cell physiology.

[22]  C. Centeno,et al.  Phytase and acid phosphatase activities in plant feedstuffs. , 2000, Journal of agricultural and food chemistry.

[23]  H. Classen,et al.  Phytase activity in the small intestinal brush border membrane of the chicken. , 1998, Poultry science.

[24]  W. Bryden,et al.  Measurement of endogenous amino acid losses in poultry. , 1993, British poultry science.

[25]  B. Luttrell,et al.  The biological relevance of the binding of calcium ions by inositol phosphates. , 1993, The Journal of biological chemistry.

[26]  M. Mcdonald,et al.  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. , 1991, British poultry science.

[27]  P. A. Kemme,et al.  Improvement of phosphorus availability by microbial phytase in broilers and pigs , 1990, British Journal of Nutrition.

[28]  L. M. Potter Bioavailability of phosphorus from various phosphates based on body weight and toe ash measurements. , 1988, Poultry science.

[29]  M. Cheryan,et al.  Calcium phytate: Effect of ph and molar ratio on in vitro solubility , 1983 .

[30]  D. Ar,et al.  Identification and properties of "phytate" in cereal grains and oilseed products. , 1975 .

[31]  M. I. Davies,et al.  Intestinal alkaline phosphatase and phytase of chicks: effect of dietary magnesium, calcium, phosphorus and thyroactive casein. , 1972, Poultry science.

[32]  I. Kleinberg,et al.  Effect of pH on calcium binding by phytic acid and its inositol phosphoric acid derivatives and on the solubility of their calcium salts. , 1971, Archives of oral biology.

[33]  F. Hill,et al.  Comparison of metabolizable energy and productive energy determinations with growing chicks. , 1958, The Journal of nutrition.