Page last updated: 2024-09-04

phosphorus and phytic acid

phosphorus has been researched along with phytic acid in 327 studies

Compound Research Comparison

Studies (phosphorus)	Trials (phosphorus)	Recent Studies (post-2010) (phosphorus)	Studies (phytic acid)	Trials (phytic acid)	Recent Studies (post-2010) (phytic acid)
48,074	1,126	17,139	3,678	176	1,232
48,074	1,126	17,139	111	0	21

Research

Studies (327)

Timeframe	Studies, this research(%)	All Research%
pre-1990	49 (14.98)	18.7374
1990's	41 (12.54)	18.2507
2000's	97 (29.66)	29.6817
2010's	86 (26.30)	24.3611
2020's	54 (16.51)	2.80

Authors

Authors	Studies
Stamp, TC	1
Reinhold, JG	1
Logan, NB; Neale, RJ	1
Coleman, JW; Taylor, TG	1
Nelson, TS	1
Edgar, WM; Jenkins, GN; Tatevossian, A	1
Campbell, BJ; Cannell, JJ; Nourmand, I; Reinhold, JG	1
Boicelli, A; Mosca, A; Nano, R; Paleari, R; Rosti, E; Russo, V; Villa, S; Zanella, A	1
Boicelli, A; Mosca, A; Nano, R; Paleari, R	1
Jongbloed, AW; Kemme, PA; Mroz, Z	1
Fisher, H	1
Burns, RA; Dickinson, DB; Erdman, JW; Fordyce, EJ; Raboy, V; Wong, MS; Zhou, JR	1
Head, HH; Morse, D; Wilcox, CJ	1
Edwards, HM; Rowland, GN; Sanders, AM	1
Pointillart, A	1
Harrison, PC; Koelkebeck, KW; Leeper, RW; Moshtaghian, J; Parsons, CM	1
Mebrahtu, T; Mohamed, AI; Rangappa, M	1
Beudeker, RF; Bos, KD; Jongbloed, AW; Kemme, PA; Simons, PC; Slump, P; Verschoor, GJ; Versteegh, HA; Wolters, MG	1
Abdel-Nabey, AA; Damir, AA	1
Hord, NG; Kunkel, ME; Powers, DL	1
Bataille, P; Fievet, P; Finet, M; Fournier, A; Renaud, H; Rogez, JC	1
Amiconi, G; Ascenzi, P; Rossi, E; Segre, AL	1
Hussain, B; Ismail, M; Khan, S; Sattar, A	1
Fontaine, N; Fourdin, A; Pointillart, A	2
Clark, WD; Gilbreath, RL; Wohlt, JE; Zajac, PK	1
Fontaine, N; Pointillart, A; Thomasset, M	1
Franz, KB	1
Beames, RM; Higgs, DA; McBride, JR; Richardson, NL	1
Taylor, TG; Williams, PJ	1
Daniels, DG; Fisher, N	1
Cook, JD; Morris, ER; Simpson, KM	1
Hasselblad, C; Hasselblad, K; Hultén, L; Sandberg, AS	1
Moore, RJ; Veum, TL	1
Ballam, GC; Kirby, LK; Nelson, TS	1
Moore, RJ; Reeves, PG; Veum, TL	1
Edwards, HM	3
Reddy, NR; Salunkhe, DK; Sathe, SK	1
O'Neill, IK; Sargent, M; Trimble, ML	1
Garcia, A; Ledoux, DR; Veum, TL; Zyła, K	1
Kirchheim, U; Lüdke, H; Schöne, F	1
Chitra, U; Geervani, P; Singh, U; Vimala, V	1
Schardt, F	1
Jonas, U; Krah, H; Schlick, R; Thon, WF; Wu, N	1
Ku, PK; Lei, XG; Miller, ER; Ullrey, DE; Yokoyama, MT	2
Ku, PK; Lei, XG; Miller, ER; Yokoyama, MT	1
Udosen, EO; Ukpanah, UM	1
Larsen, T; Sandberg, AS; Sandström, B	1
Edwards, HM; Mitchell, RD	2
Brandt, K; Most, E; Pallauf, J; Rimbach, G	1
Kujawski, M; Ledoux, DR; Veum, TL; Zyła, K	1
Denbow, DM; Kornegay, ET; Ravindran, V; Yi, Z	1
Ene-Obong, HN	1
Ravindran, V; Sivakanesan, R	1
Beynen, AC; Jongbloed, AW; Kemme, PA; Mroz, Z	1
Baker, DH; Biehl, RR	1
Carlos, AB; Edwards, HM	1
Denbow, DM; Grabau, EA; Kornegay, ET; Lacy, GH; Russell, DR; Umbeck, PF	1
Han, YM; Lei, XG; Pond, WG; Roneker, KR	1
Carlos, AB; Edwards, HM; Kasim, AB; Toledo, RT	1
Han, Y; Lei, XG; Rodriguez, E	1
Han, Y; Lei, XG; Wilson, DB	1
Barrionuevo, M; López-Frías, M; Nestares, T; Urbano, G	1
Bishnoi, S; Duhan, A; Khetarpaul, N	2
Keshavarz, K	1
Bryden, WL; Cabahug, S; Ravindra, G; Ravindran, V; Selle, PH	1
Most, E; Pallauf, J; Rimbach, G; Walter, A	1
Ertl, DS; Ledoux, DR; Li, YC; Raboy, V; Veum, TL	1
Crum, RC; Fritts, CA; Kersey, JH; Raboy, V; Saleh, EA; Stilborn, HL; Waldroup, PW; Yan, F	1
Bakalli, RI; Edwards, HM; Kilburn, J; Pesti, GM; Smith, TN	1
Hadobas, PA; Hayes, JE; Richardson, AE	1
Demigne, C; Guy, C; Krespine, V; Lopez, HW; Messager, A; Remesy, C	1
Bishnoi, S; Khetarpaul, N; Saharan, K	1
Ishida, S; Koizumi, A; Kumagai, H; Sakurai, H	1
Ertl, DS; Ledoux, DR; Raboy, V; Veum, TL	1
Drochner, W; Lantzsch, HJ; Rapp, C	3
Bollinger, DW; Cook, A; Ledoux, DR; Raboy, V; Veum, TL	1
Coon, C; Leske, K	1
Anderson, JM; Bauman, AT; Cook, A; Dorsch, JA; Murthy, PP; Raboy, V; Volkmann, CJ; Young, KA	1
Angel, R; Applegate, TJ; Classen, HL	1
TAHA, MM	1
CANALS, E; CORDIER, S; MARIGNAN, R	1
AYYAR, NK; GOWDA, HS; KEHAR, ND	2
COLLINS, RA; GILLIS, MB; KEANE, KW	1
BARTH, J; HANSARD, SL	1
Forbes, RM; Likuski, HJ	1
JENKINS, NK	1
OKE, OL	1
AMMERMAN, CB; HARMS, RH; WALDROUP, PW	1
BORDIER, P; HIOCO, D; LICHTWITZ, A; WELFLING, J	1
Lofgreen, GP	1
Crowe, SE; Gentile, JM; Lei, XG; Pond, WG; Roneker, KR	1
Ledwaba, MF; Roberson, KD	1
Angel, R; Tamim, NM	1
Cook, A; Ernst, RA; Fadel, JG; Jang, DA; Klasing, KC; Mireles, AJ; Raboy, V; Young, KA	1
Guyton, AD; Knowlton, KF; McKinney, JM	1
Nogueira, AR; Vieira, EC	1
Augspurger, NR; Baker, DH	1
Raboy, V; Rossnagel, BG; Thacker, PA	1
Charbeneau, RA; Klunzinger, MW; Roberson, KD	1
Acamovic, T; Bedford, MR; Cowieson, AJ	1
Beynen, AC; Everts, H; van Doorn, DA; Wouterse, H	1
Li, L; Li, SM; Tang, C; Zhang, FS	1
Aggrey, SE; Ankra-Badu, GA; Bakalli, RI; Edwards, HM; Pesti, GM	1
Koreleski, J; Mika, M; Stodolak, B; Swiatkiewicz, S; Wikiera, A; Zyła, K	1
Baker, DH; Parsons, CM; Snow, JL	1
Aranda, P; López-Jurado, M; Porres, JM; Urbano, G	1
Angel, R; Christman, M; Tamim, NM	1
Casaravilla, C; Díaz, A; Ferreira, F; Iborra, F; Irigoín, F; Sim, RB	1
Andlid, TA; Sandberg, AS; Veide, J	1
Harinarayan, CV; Ramalakshmi, T; Venkataprasad, U	1
Okubo, K; Osaki, M; Shinano, T; Unno, Y; Wasaki, J	1
Aggrey, SE; Bakalli, RI; Edwards, HM; Pesti, GM; Zhang, W	2
Delacroix, DL; Delzenne, NM; Habib-Jiwan, JL; Larondelle, Y; Marques, C; Meurens, M; Mignolet, E; Petitjean, G; Pycke, JM; Quetin-Leclercq, J; Rozenberg, R; Ruibal-Mendieta, NL	1
Baxter, JW; Dighton, J	1
Chiera, JM; Finer, JJ; Grabau, EA	1
Bollinger, DW; Ellersieck, MR; Ledoux, DR; Tsunoda, A; Veum, TL	1
Adedokun, SA; Adeola, O; Dilger, RN; Jendza, JA; Sands, JS	1
Garikipati, DK; Harrison, JH; Kincaid, RL; Nennich, TD	1
Jungk, RA; Parsons, CM; Rafacz-Livingston, KA	1
Baker, DH; Martinez-Amezcua, C; Parsons, CM; Rafacz-Livingston, KA; Snow, J	1
Bhanja, SK; Panda, AK; Raju, MV; Rama Rao, SV	1
Fahey, GC; Karr-Lilienthal, LK; Martinez Amezcua, C; Merchen, NR; Parsons, CM; Utterback, PL	1
Beynen, AC; Jittakhot, S; Lemmens, AG; Wensing, T; Yuangklang, C	1
Cheng, C; Lim, BL	1
Adeola, O; Dilger, RN	2
Applegate, TJ; Pang, Y	1
Kong, F; Liao, H; Lin, W; Yan, X	1
Angel, R; Fehr, W; Fritz, ER; Powers, WJ	1
Letcher, PM; McGee, PA; Midgley, DJ	1
Bueno, IC; Dias, RS; France, J; Kebreab, E; Roque, AP; Vitti, DM	1
Araiza, BA; Cervantes, M; Htoo, JK; Liao, SF; Morales, A; Sauer, WC; Torrentera, N; Zhang, Y	1
Ledoux, DR; Raboy, V; Veum, TL	1
Albrecht, D; Antelmann, H; Hecker, M; Töwe, S	1
Nortey, TN; Patience, JF; Simmins, PH; Trottier, NL; Zijlstra, RT	1
Adeola, O; Olukosi, OA; Sands, JS	1
Harinarayan, CV; Kumar, EG; Prasad, UV; Ramalakshmi, T; Sarma, KV; Srinivasarao, PV; Sudhakar, D	1
Abdelrahaman, SM; Babiker, EE; El Tinay, AH; Elmaki, HB; Hassan, AB; Idris, WH	1
Liu, K; Peterson, KL; Raboy, V	1
Cervantes, M; Helm, JH; Htoo, JK; Sauer, WC; Yáñez, JL; Zhang, Y; Zijlstra, RT	1
Jeun, BY; Joung, H; Kim, J; King, JC; Li, SJ; Paik, HY; Welch, RM; Woodhouse, LR	1
Jyothi, LA; Prakash, J; Sheetal, G; Suma, RC	1
Chen, P; Chen, R; Fan, Y; Ma, Q; Shi, J; Tarczynski, MC; Xue, G; Yang, W; Yao, B; Zhao, Z	1
Cheng, C; Hill, JE; Lim, BL; Yeung, P	1
Bouguennec, A; Carre, B; Genthon, C; Jondreville, C; Nys, Y	1
LEE, JW; UNDERWOOD, EJ	2
Bailey, A; Beuselinck, PR; Bilyeu, KD; Coello, P; Krishnan, HB; Polacco, JC; Zeng, P; Zhang, ZJ	1
Brake, J; Burton, JW; Kwanyuen, P; Leytem, AB; Maguire, RO; Plumstead, PW	1
Ebrahimnezhad, Y; Nazeradl, K; Shivazad, M; Taherkhani, R	1
Edwards, HM; Liem, A; Pesti, GM	1
Liebl, W; Tzvetkov, MV	1
France, J; Hanigan, MD; Hill, SR; Kebreab, E; Knowlton, KF	1
Dao, TH; Hoang, KQ	1
Campbell, GL; Raboy, V; Rossnagel, BG; Salarmoini, M	1
Andaya, CB; Goyal, SS; Kim, SI; Newman, JW; Tai, TH	1
FOX, FW; IRVING, JT; WALKER, AR	1
MARUYAMA, G; SPITZER, RR	1
Priya, P; Sahi, SV	1
Costa-Bauzá, A; Ferragut, ML; Frontera, G; Grases, F; Isern, B; Perelló, J; Prieto, RM; Sanchis, P; Santiago, C	1
Fuentes, B; Jorquera, M; Mora, Mde L	1
Hill, BE; Richert, BT; Sutton, AL	1
Kwanyuen, P; Leytem, AB; Thacker, P	1
Nygren, CMR; Rosling, A	1
Adeola, O; Cowieson, AJ; Nyachoti, CM; Woyengo, TA	1
Huang, H; Luo, H; Shao, N; Shi, P; Wang, G; Wang, Y; Yang, P; Yao, B	1
Adeola, O; Dilger, RN; Ragland, D; Sands, JS	1
Kuwano, M; Takaiwa, F; Yoshida, KT	1
Atencio, A; Edwards, HM; Liem, A; Pesti, GM	1
Brearley, C; Frelet-Barrand, A; Green, P; Grob, H; Klein, M; Martinoia, E; Nagy, R; Schjoerring, JK; Weder, B	1
Leytem, AB; Thacker, PA	1
Ahn, DJ; Lee, SC; Rico, CM; Won, JG	1
ANDERSEN, O; HOFF-JORGENSEN, E	1
ANDERSEN, O; HOFF-JORGENSEN, E; NIELSEN, G	1
Araiza, BA; Barrera, MA; Cervantes, M; Fierro, S; Gómez, R; Morales, A; Sánchez, JE; Sauer, WC; Zijlstra, RT	1
Dang, J; Noureddini, H	1
Aggrey, SE; Ankra-Badu, GA; Pesti, GM	1
HOFF-JORGENSEN, E	1
DUTT, TR; NARANG, BD	1
Crowley, DE; De La Luz Mora, M; Fernández, MT; Greiner, R; Jorquera, MA; Marschner, P; Menezes-Blackburn, D; Romero, D	1
Grases, F; López-González, ÁA; Perelló, J; Prieto, RM; Sanchis, P	1
Diao, Q; Fu, D; Huang, H; Li, Z; Luo, H; Luo, J; Shi, P; Yang, P; Yao, B; Zhang, R	1
Archana, G; Naresh Kumar, G; Patel, KJ; Vig, S	1
Eichert, D; Gianoncelli, A; Kaulich, B; Kreft, I; Pongrac, P; Regvar, M; Vogel-Mikus, K	1
Cao, YX; Chen, ZH; Lu, XC; Tian, XH; Yang, XW	1
Ekholm, P; Hirvonen, T; Itkonen, S; Karp, H; Kemi, V; Lamberg-Allardt, C; Närkki, S	1
Foster, E; Guney, AC; Pesti, GM; Shim, MY; Smith, C; Tahir, M; Ward, NE	1
Bobeck, EA; Cook, ME; Helvig, C; Meyer, KM; Petkovich, M	1
Piergiovanni, AR; Sparvoli, F; Zaccardelli, M	1
Bregitzer, P; Hicks, KB; Liu, K; Moreau, RA	1
Knowlton, KF; Pearson, RE; Ray, PP; Shang, C	1
Blank, LM	1
Pesti, GM; Shim, MY; Tahir, M; Ward, NE; Westerhaus, MO	1
Huang, H; Li, Z; Liu, J; Ma, Z; Wang, J; Wang, X; Wu, L; Zhang, G	1
Fathallh Eida, M; Kouno, K; Nagaoka, T; Wasaki, J	1
Bai, L; Chen, XG; Huang, CY; Ivan, OM; Lei, J; Zhang, MQ; Zhang, Y	1
Jarrett, J; Knowlton, KF; Ray, PP	1
Bhavsar, KP; Gujar, PD; Khire, JM	1
Guy, C; Lessl, JT; Ma, LQ; Rathinasabapathi, B	1
Linares, Z; Ojeda, A; Villavicencio, I	1
Adhikari, D; Horii, S; Kubo, M; Matsuno, T; Mukai, M; Tagomori, J	1
Hadi Alkarawi, H; Zotz, G	1
Amenc, L; Bargaz, A; Djekoun, A; Drevon, JJ; Maougal, RT; Plassard, C; Sahel, C	1
Feng, XH; Liu, F; Liu, MM; Tan, WF; Yan, YP; Zhang, YY	1
Kong, Y; Li, W; Li, X; Ma, J; Yan, G; Zhang, C	1
Cui, HR; Li, WX; Pang, WQ; Poirier, Y; Shu, QY; Zhao, HJ	1
Hashimoto, Y; Kikkawa, R; Murakami, K; Takamoto, A; Yamaguchi, N	1
Bedford, MR; Bradbury, EJ; Cowieson, AJ; Cronin, GM; Thomson, PC; Wilkinson, SJ	1
Bedford, MR; Bradbury, EJ; Cowieson, AJ; Thomson, PC; Wilkinson, SJ	1
Almaguer, BL; Liu, Y; Stein, HH; Sulabo, RC	1
Feng, X; Li, W; Liu, F; Sparks, DL; Yan, Y; Yang, J; Zheng, A	1
Coban, HB; Demirci, A	1
Brand-Klibanski, S; Shenker, M; Yalin, D	1
Haese, E; Müller, K; Rodehutscord, M; Schollenberger, M; Steingass, H	1
Abdi, D; Cade-Menun, BJ; Hu, Y; Liu, J; Yang, J	1
Hoelzle, LE; Kühn, I; Rodehutscord, M; Schollenberger, M; Shastak, Y; Witzig, M; Zeller, E	1
Graminho, ER; Hoshino, T; Nakamura, A; Takaya, N	1
Anuonye, JC; Chinma, CE; Danbaba, N; Ohiare, RO; Simon, OC	1
Ganapathi, A; Hada, A; Jolly, M; Kumar, V; Sachdev, A; Singh, TR	1
Aoki, N; Iwai, T; Matsubara, C; Nishida, S; Okamura, M; Sakai, H; Terada, Y; Usui, Y; Yatou, O; Yoshida, KT	1
Giles, CD; Hill, JE; Hsu, PC; Hurst, MR; Richardson, AE	1
Casas, GA; Stein, HH	1
González-Vega, JC; Stein, HH; Walk, CL	1
Chen, X; Fan, Y; Govender, A; Shen, W; Wang, Z; Xiao, Y; Zhang, L	1
Andreote, FD; Cavalcante Franco Dias, A; Cotta, SR; Seldin, L; van Elsas, JD	1
Meyer, AS; Nielsen, AV	1
Csetenyi, L; Gadd, GM; Liang, X	1
Belgaroui, N; Berthomieu, P; Hanin, M; Rouached, H	1
Raboy, V; Veum, TL	1
Feng, G; Hodge, A; Liu, Y; Xu, M; Zhang, F; Zhang, L	1
Arpat, AB; Cui, H; Engel, KH; Frank, T; He, Z; Huang, J; Jabnoune, M; Poirier, Y; Shu, Q; Tan, Y; Zhao, H; Zhou, C	1
González-Vega, JC; Sotak-Peper, KM; Stein, HH	1
Deiner, C; den Hartog, LA; Martens, H; Martín-Tereso, J; van Laar, H; Verstegen, MW	1
Ma, JF; Mitani-Ueno, N; Miyaji, T; Takemoto, Y; Yamaji, N; Yoshida, KT	1
Bedford, MR; Beeson, LA; Olukosi, OA; Walk, CL	1
Haese, E; Möhring, J; Rodehutscord, M; Schollenberger, M; Steingass, H	1
Cao, Y; Chen, Y; da Silva, EB; Fu, JW; Liu, X; Ma, LQ; Tang, N; Turner, BL	1
Akkari, E; Allen, E; Brearley, C; Clark, IM; Guyomar, C; Hirsch, PR; Neal, AL; Rossmann, M	1
Bao, J; Chen, Y; Liu, L; Rose, TJ; Shu, Q; Tan, Y; Tong, C; Waters, DLE	1
Gu, Z; Hui, Q; Ma, Y; Wang, M; Wang, P; Yang, R	1
Ashraf, M; Malik, KA; Maqbool, A; Mohsin, S	1
Chen, Y; Jia, Z; Li, M; Li, S; Liu, K; Tian, X; Wang, S	1
Anegawa, A; Baba, K; Fukaki, H; Hayashi, M; Ishizaki, K; Kaneko, Y; Kosuge, K; Kurita, Y; Matsubara, R; Mimura, T; Ohnishi, M; Shichijo, C; Suzaki, T	1
Cardoso, EF; de Oliveira Donzele, RFM; Donzele, JL; Silva, AD; Sufiate, BL; Tizziani, T	1
Dilger, RN; Gautier, AE; Walk, CL	1
Cheng, F; Pan, G; Su, D; Zhao, Q; Zhou, L	1
Chu, C; Kopriva, S	1
Cao, Y; Chen, Y; Feng, HY; Fu, JW; Liu, X; Liu, Y; Ma, LQ; Sun, D; Xiang, P	1
Tarkka, M; Vetterlein, D	1
Ávila-Gonzalez, E; Chárraga, S; Fernández, SR	1
Abbasi, F; Abbasi, IHR; Fakhur-Un-Nisa, T; Liu, J; Luo, X	1
Ilukor, J; Nimbona, P; Njukwe, E; Sridonpai, P; Tirawattanawanich, C; Udomkun, P; Vanlauwe, B	1
Akhtar, M; Hussain, S; Sarwar, N; Yousaf, S	1
Dave, G; Modi, H	1
Aumiller, T; Burbach, K; Capezzone, F; Eklund, M; Heyer, CME; Hoelzle, LE; Mosenthin, R; Rodehutscord, M; Schmucker, S; Seifert, J; Stefanski, V; Steuber, J; Weiss, E	1
C, P; Hada, A; Jolly, M; Krishnan, V; Kumar, A; Kumar, V; Marathe, A; Sachdev, A	1
Acosta, JA; Patience, JF	1
Feng, X; Liu, F; Tan, W; Tang, Y; Wang, G; Wang, X; Yan, Y; Zeng, H	1
Faucon, MP; Firmin, S; Houben, D; Kandeler, E; Lambers, H; Michel, E; Nobile, C	1
Crum, AD; Fowler, AL; Hayes, SH; Lawrence, LM; Pyles, MB	1
Feyder, A; Grubješić, G; Haese, E; Krieg, J; Rodehutscord, M	1
Frossard, E; McLaren, TI; Reusser, JE; Verel, R	1
Auh, JH; Booth, CJ; Cha, JY; Cho, SW; Choi, C; Choi, HJ; Choi, HS; Hur, J; Im, SS; Jung, WJ; Jung, YJ; Jung, YS; Kang, J; Kim, H; Kim, JW; Kim, OH; Kim, YB; Lee, CS; Lee, DH; Lee, J; Lee, YJ; Oh, BC; Park, KS; Park, YJ; Yang, JY	1
Hirotsu, N; Kawai-Yamada, M; Makino, A; Miyagi, A; Noguchi, K; Suganami, M; Suzuki, Y; Takagi, D; Tazoe, Y; Ueda, A	1
Rama Rao, SV; Walk, CL	2
Dong, Q; Saneoka, H	1
Adeola, O; Ajuwon, KM; Bedford, M; Kuehn, I; Lu, H; Rodehutscord, M; Shin, S	1
Bennewitz, J; Camarinha-Silva, A; Hasselmann, M; Huber, K; Ponsuksili, S; Rodehutscord, M; Seifert, J; Sommerfeld, V; Stefanski, V; Wimmers, K	1
Aristilde, L; Klein, AR; Solhtalab, M	1
Breitkreuz, C; Rasul, M; Reitz, T; Tarkka, M; Yahya, M; Yasmin, S	1
Bhattacharya, S; Datta, K; Datta, SK; Gangopadhyay, G; Ghosh, S; Karmakar, A; Sarkar, SN; Sengupta, S	1
Chen, Z; Jiang, K; Sheng, C; Wang, Y; Yu, S; Zhang, H	1
Fan, QL; Jiang, SQ; Wang, WW; Wang, YB; Ye, JL; Zhang, S	1
Behera, L; Behera, S; Kumar, A; Lal, MK; Nayak, S; Ngangkham, U; Sah, RP; Sharma, S; Swain, P; Tp, A	1
Calvo, MS; Uribarri, J	1
Dersjant-Li, Y; Espinosa, CD; Oliveira, MSF; Stein, HH; Velayudhan, DE	1
He, Z; Jaisi, DP; Sun, M	1
Adeola, O; Babatunde, OO; Bello, A; Dersjant-Li, Y	2
Li, J; Li, L; Lin, S; Lin, X; Zhang, K	1
Arai, Y; Chen, Y; Shang, J; Sharma, P; Tufail, S; Wang, X; Zhang, Q; Zhao, K	1
Kim, SR; Lee, HJ; Park, EY; Park, JY	1
An, Y; Du, S; Ji, F; Li, X; Shao, Y; Sun, X; Wang, Z; Zhang, S	1
Aureli, R; Faruk, MU; Tschambser, A; Wang, JP; Zhai, HX; Zhang, Q	1
He, D; Wan, W	1
Adeola, O; Ajuwon, KM; Bedford, MR; Ogunribido, TZ	1
Cao, Y; Han, R; Liu, X; Ma, LQ; Turner, BL	1
Hussein, FB; Husted, S; Mallick, SP; Mayer, BK	1
Chen, X; Gao, W; Gu, Z; Tian, J; Wen, H; Wu, F; Yang, W	1
Dersjant-Li, Y; Lee, SA; Nelson, ME; Remus, J; Stein, HH	1
Lucas, E; Mosesso, L; Roswall, T; Scheckel, K; Shober, A; Toor, GS; Yang, YY	1
Bouain, N; Cho, H; Prom-U-Thai, C; Rouached, H; Sandhu, J; Shahzad, Z; Tuiwong, P; Zheng, L	1
Ding, S; He, J; Jiao, L; Li, L; Liu, W; Liu, Y; Zheng, J; Zhu, Y	1
Cheng, Y; Liu, H; Zhao, Q	1
Abruzzese, A; Bononi, M; Colombo, F; Nocito, FF; Pilu, R; Sangiorgio, S; Singh, SK; Tateo, F	1
Vaidyanathan, VK; Venkataraman, S	1
Bertechini, AG; Carvalho, JCC; Dalólio, FS; Reis, MP	1
Chang, C; Chu, Q; Geng, AL; Song, ZG; Wang, HH; Yan, ZX; Zhang, J; Zhang, QQ	1
Angel, CR; Korver, DR; Rodehutscord, M; Sommerfeld, V	1
Ekramzadeh, M; Kalantar-Zadeh, K; Kopple, JD; Moore, LW	1
Li, P; Liu, Y; Song, WM; Zhang, LY	1
Feng, G; George, TS; Jin, Z; Wang, G; Zhang, L	1
Christensen, T; Dersjant-Li, Y; García-González, R; Kok, I; Marchal, L; Mereu, A; Westreicher-Kristen, E	1
Hu, Y; Rahman, MZ; Song, L; Wang, X	1
Duclos, MJ; Hervo, F; Létourneau-Montminy, MP; Méda, B; Même, N; Narcy, A	1
Kumar, V; Sharma, A; Sharma, AK; Tehri, N; Tehri, P; Vashishth, A	1
Ahmed Hamza, T; Baban, J; Fakri Mustafa, Y; Hafsan, H; Ibrahim, I; Kadhim, MM; Mahmood Saleh, M; Mohammed, F; Zwain, KA	1
Guo, Q; Lai, T; Liang, C; Lu, X; Tian, J; Xue, Y; Zhu, S	1
Li, J; Li, L; Lin, S; Wang, Y; Zhang, K	1
Aria, N; Emami-Karvani, Z; Hamblin, MR; Joudaki, H; Moravej, R; Rezaei Yazdi, M	1
Arai, Y; Chen, A; Han, HS; Zhu, L	1
Kumar, S; Malik, V; Singh, B; Singh, D; Tiwari, SK	1
Chang, TY; Charng, YY; Chiang, SF; Chiou, TJ; Kuo, HF; Wang, WD	1

Reviews

13 review(s) available for phosphorus and phytic acid

Article	Year
Factors in human vitamin D nutrition and in the production and cure of classical rickets. The Proceedings of the Nutrition Society, 1975, Volume: 34, Issue:2 Topics: Adolescent; Adult; Aged; Calcium; Child; Cholecalciferol; Diet; Diet Therapy; Female; Humans; Hydroxycholecalciferols; Liver; Male; Phosphorus; Phytic Acid; Rickets; Seasons; Skin; Ultraviolet Therapy; Vitamin D; Vitamin D Deficiency	1975
Low-calcium diets enhance phytate-phosphorus availability. Nutrition reviews, 1992, Volume: 50, Issue:6 Topics: Animals; Biological Availability; Calcium; Chickens; Diet; Phosphorus; Phytic Acid; Plants, Edible	1992
[Medical treatment of idiopathic calcium lithiasis (II)]. Nephrologie, 1985, Volume: 6, Issue:4 Topics: Allopurinol; Benzothiadiazines; Calcium; Cellulose; Citrates; Citric Acid; Diuretics; Humans; Magnesium; Pentosan Sulfuric Polyester; Phosphorus; Phytic Acid; Pyridoxine; Sodium Chloride Symporter Inhibitors; Succinimides; Urinary Calculi	1985
Cataract as an outcome of zinc deficiency in salmon. Nutrition reviews, 1986, Volume: 44, Issue:3 Topics: Animal Feed; Animals; Calcium, Dietary; Cataract; Diet; Fish Diseases; Phosphorus; Phytic Acid; Salmon; Zinc	1986
Biochemistry of black gram (Phaseolus mungo L.): a review. Critical reviews in food science and nutrition, 1982, Volume: 16, Issue:1 Topics: Amino Acids; Animals; Carbohydrates; Digestion; Electrophoresis, Polyacrylamide Gel; Fabaceae; Fermentation; Flatulence; Food Handling; Hot Temperature; Hydrogen-Ion Concentration; Isoelectric Focusing; Lipids; Minerals; Nutritional Physiological Phenomena; Nutritive Value; Oryza; Phosphorus; Phytic Acid; Plant Proteins; Plants, Medicinal; Rats; Seeds; Solubility; Time Factors; Trypsin Inhibitors; Vitamins	1982
The cell and P: from cellular function to biotechnological application. Current opinion in biotechnology, 2012, Volume: 23, Issue:6 Topics: Animals; Bacteria; Biotechnology; Cells; Humans; Phosphorus; Phytic Acid; Soil Microbiology; Structure-Activity Relationship; Yeasts	2012
Are we ready to improve phosphorus homeostasis in rice? Journal of experimental botany, 2018, 06-27, Volume: 69, Issue:15 Topics: Crops, Agricultural; Homeostasis; Nutrients; Oryza; Phosphate Transport Proteins; Phosphates; Phosphorus; Phytic Acid; Plant Proteins; Seeds	2018
Zinc biofortification of cereals-role of phosphorus and other impediments in alkaline calcareous soils. Environmental geochemistry and health, 2019, Volume: 41, Issue:5 Topics: Biofortification; Biological Transport; Crops, Agricultural; Edible Grain; Fertilizers; Genetic Engineering; Nutritive Value; Phosphorus; Phytic Acid; Soil; Zinc	2019
Enhancing Phytate Availability in Soils and Phytate-P Acquisition by Plants: A Review. Environmental science & technology, 2022, 07-05, Volume: 56, Issue:13 Topics: 6-Phytase; Fertilizers; Phosphates; Phosphorus; Phytic Acid; Plants; Soil	2022
Minimum phosphorus requirements for laying hen feed formulations. Poultry science, 2023, Volume: 102, Issue:2 Topics: 6-Phytase; Animal Feed; Animals; Chickens; Diet; Dietary Supplements; Female; Ovum; Phosphorus; Phosphorus, Dietary; Phytic Acid	2023
Unraveling the potential of bacterial phytases for sustainable management of phosphorous. Biotechnology and applied biochemistry, 2023, Volume: 70, Issue:5 Topics: 6-Phytase; Animals; Ecosystem; Humans; Phosphates; Phosphorus; Phytic Acid	2023
Microbial Phytases: Properties and Applications in the Food Industry. Current microbiology, 2023, Oct-17, Volume: 80, Issue:12 Topics: 6-Phytase; Animals; Food Industry; Fungi; Humans; Phosphorus; Phytic Acid	2023
Production of fungal phytases in solid state fermentation and potential biotechnological applications. World journal of microbiology & biotechnology, 2023, Nov-27, Volume: 40, Issue:1 Topics: 6-Phytase; Animals; Fermentation; Minerals; Phosphorus; Phytic Acid	2023

Trials

33 trial(s) available for phosphorus and phytic acid

Article	Year
[Effects of doses of cereal foods and zinc on different blood parameters in performing athletes]. Zeitschrift fur Ernahrungswissenschaft, 1994, Volume: 33, Issue:3 Topics: Absorption; Adult; Blood Chemical Analysis; Copper; Edible Grain; Exercise; Humans; Iron; Lymphocyte Count; Male; Phosphorus; Phytic Acid; Potassium; Sports; Trace Elements; Zinc	1994
Escherichia coli phytase improves growth performance of starter, grower, and finisher pigs fed phosphorus-deficient diets. Journal of animal science, 2005, Volume: 83, Issue:8 Topics: 6-Phytase; Absorption; Animal Feed; Animals; Biological Availability; Body Weight; Bone and Bones; Escherichia coli; Escherichia coli Proteins; Female; Male; Nutritional Status; Phosphorus; Phytic Acid; Swine	2005
Effect of microbial phytase on production performance of White Leghorn layers fed on a diet low in non-phytate phosphorus. British poultry science, 2005, Volume: 46, Issue:4 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Body Weight; Bone and Bones; Calcium; Chickens; Diet; Dietary Supplements; Dose-Response Relationship, Drug; Female; Oviposition; Phosphorus; Phytic Acid	2005
Relative bioavailability of phosphorus and true amino acid digestibility by poultry as affected by soybean extraction time and use of low-phytate soybeans. Poultry science, 2005, Volume: 84, Issue:10 Topics: Amino Acids; Animal Feed; Animals; Biological Availability; Chickens; Diet; Digestion; Glycine max; Male; Phosphorus; Phytic Acid; Time Factors	2005
Estimation of true phosphorus digestibility and endogenous phosphorus loss in growing chicks fed conventional and low-phytate soybean meals. Poultry science, 2006, Volume: 85, Issue:4 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Digestion; Glycine max; Logistic Models; Male; Phosphorus; Phytic Acid	2006
Total and water-soluble phosphorus excretion from swine fed low-phytate soybeans. Journal of animal science, 2006, Volume: 84, Issue:7 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Feces; Glycine max; Male; Phosphorus; Phytic Acid; Swine	2006
The effect of feeding low-phytate barley-soybean meal diets differing in protein content to growing pigs on the excretion of phosphorus and nitrogen. Journal of animal science, 2007, Volume: 85, Issue:3 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Dietary Proteins; Feces; Glycine max; Hordeum; Male; Nitrogen; Phosphorus; Phytic Acid; Swine	2007
Low-phytate barley cultivars improve the utilization of phosphorus, calcium, nitrogen, energy, and dry matter in diets fed to young swine. Journal of animal science, 2007, Volume: 85, Issue:4 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Bone Density; Calcium; Diet; Energy Metabolism; Hordeum; Male; Nitrogen; Nutritive Value; Phosphorus; Phytic Acid; Swine; Weight Gain	2007
Effects of individual or combined xylanase and phytase supplementation on energy, amino acid, and phosphorus digestibility and growth performance of grower pigs fed wheat-based diets containing wheat millrun. Journal of animal science, 2007, Volume: 85, Issue:6 Topics: Amino Acids; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Cross-Over Studies; Diet; Dietary Supplements; Digestion; Endo-1,4-beta Xylanases; Female; Ileum; Male; Phosphorus; Phytic Acid; Swine; Triticum	2007
Fecal phytate excretion varies with dietary phytate and age in women. Journal of the American College of Nutrition, 2007, Volume: 26, Issue:3 Topics: Adult; Age Factors; Aged; Aging; Cross-Over Studies; Dose-Response Relationship, Drug; Feces; Female; Humans; Intestinal Absorption; Middle Aged; Phosphorus; Phosphorus, Dietary; Phytic Acid	2007
Characterisation of European varieties of triticale with special emphasis on the ability of plant phytase to improve phytate phosphorus availability to chickens. British poultry science, 2007, Volume: 48, Issue:6 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Biological Availability; Bone and Bones; Bone Density; Chickens; Diet; Dietary Supplements; Dose-Response Relationship, Drug; Edible Grain; Europe; Male; Minerals; Phosphorus; Phytic Acid	2007
Anticalculus effect of a triclosan mouthwash containing phytate: a double-blind, randomized, three-period crossover trial. Journal of periodontal research, 2009, Volume: 44, Issue:5 Topics: Adolescent; Adult; Aged; Anti-Infective Agents, Local; Calcium; Calcium Phosphates; Cross-Over Studies; Crystallization; Dental Calculus; Dental Plaque; Double-Blind Method; Durapatite; Female; Humans; Magnesium; Male; Middle Aged; Mouthwashes; Phosphorus; Phytic Acid; Placebos; Triclosan; Young Adult; Zinc	2009
Responses of pigs to Aspergillus niger phytase supplementation of low-protein or high-phytin diets. Journal of animal science, 2009, Volume: 87, Issue:8 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Aspergillus niger; Diet; Dietary Proteins; Digestion; Female; Male; Nitrogen; Phosphorus; Phytic Acid; Swine	2009
Experimental approach to optimize phytate phosphorus utilization by broiler chickens by addition of supplements. Poultry science, 2009, Volume: 88, Issue:8 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcitriol; Calcium; Chickens; Diet; Dietary Supplements; Dose-Response Relationship, Drug; Female; Male; Minerals; Phosphorus; Phytic Acid; Weight Gain	2009
Phosphorus utilization and characterization of excreta from swine fed diets containing a variety of cereal grains balanced for total phosphorus. Journal of animal science, 2010, Volume: 88, Issue:5 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Edible Grain; Feces; Phosphorus; Phytic Acid; Swine	2010
Nutritional geometry of calcium and phosphorus nutrition in broiler chicks. Growth performance, skeletal health and intake arrays. Animal : an international journal of animal bioscience, 2014, Volume: 8, Issue:7 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Bone Density; Calcium; Calcium, Dietary; Chickens; Diet; Digestion; Dose-Response Relationship, Drug; Male; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid	2014
Nutritional geometry of calcium and phosphorus nutrition in broiler chicks. The effect of different dietary calcium and phosphorus concentrations and ratios on nutrient digestibility. Animal : an international journal of animal bioscience, 2014, Volume: 8, Issue:7 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Calcium, Dietary; Chickens; Diet; Dietary Supplements; Digestion; Glycine max; Ileum; Male; Minerals; Nitrogen; Phosphorus; Phosphorus, Dietary; Phytic Acid	2014
Effects of mineral and rapeseed phosphorus supplementation on phytate degradation in dairy cows. Archives of animal nutrition, 2014, Volume: 68, Issue:6 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Brassica rapa; Cattle; Diet; Dietary Supplements; Digestion; Phosphorus; Phytic Acid	2014
Interactions between supplemented mineral phosphorus and phytase on phytate hydrolysis and inositol phosphates in the small intestine of broilers1,2. Poultry science, 2015, Volume: 94, Issue:5 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcification, Physiologic; Calcium Phosphates; Chickens; Diet; Dietary Supplements; Drug Interactions; Female; Hydrolysis; Inositol Phosphates; Intestine, Small; Male; Phosphorus; Phytic Acid; Tibia	2015
Effects of microbial phytase on the apparent and standardized total tract digestibility of phosphorus in rice coproducts fed to growing pigs. Journal of animal science, 2015, Volume: 93, Issue:7 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Digestion; Feces; Gastrointestinal Tract; Glycine max; Male; Oryza; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine; Zea mays	2015
Hulled and hull-less barley grains with the genetic trait for low-phytic acid increased the apparent total-tract digestibility of phosphorus and calcium in diets for young swine. Journal of animal science, 2016, Volume: 94, Issue:3 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Bone and Bones; Calcium; Calcium, Dietary; Diet; Female; Gastrointestinal Tract; Hordeum; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine	2016
Phytate degradation, intestinal microbiota, microbial metabolites and immune values are changed in growing pigs fed diets with varying calcium-phosphorus concentration and fermentable substrates. Journal of animal physiology and animal nutrition, 2019, Volume: 103, Issue:4 Topics: Animal Feed; Animals; Bacteria; Calcium, Dietary; Diet; Digestion; Fatty Acids, Volatile; Fermentation; Gastrointestinal Microbiome; Intestines; Phosphorus; Phytic Acid; RNA, Bacterial; RNA, Ribosomal, 16S; Swine	2019
Effect of phytase on nutrient digestibility and expression of intestinal tight junction and nutrient transporter genes in pigs. Journal of animal science, 2020, Jul-01, Volume: 98, Issue:7 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium, Dietary; Diet; Dietary Supplements; Digestion; Feces; Gastrointestinal Tract; Ileum; Inositol; Male; Nutrients; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine; Tight Junction Proteins; Tight Junctions	2020
Evaluation of the responses of broiler chickens to varying concentrations of phytate phosphorus and phytase. Ⅱ. Grower phase (day 12-23 post hatching). Poultry science, 2022, Volume: 101, Issue:3 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Diet; Dietary Supplements; Digestion; Male; Phosphorus; Phytic Acid	2022
Influence of dietary phosphorus concentrations on the performance of rearing pigeons (Columba livia), and bone properties of squabs. Poultry science, 2022, Volume: 101, Issue:4 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Columbidae; Diet; Dietary Supplements; Female; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Plant Breeding	2022
Evaluation of the efficacy of a novel phytase in short-term digestibility and long-term egg production studies with laying hens. Poultry science, 2022, Volume: 101, Issue:6 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Diet; Dietary Supplements; Female; Ovum; Phosphorus; Phytic Acid	2022
Effects of supplemental myo-inositol on growth performance and apparent total tract digestibility of weanling piglets fed reduced protein high-phytate diets and intestinal epithelial cell proliferation and function. Journal of animal science, 2022, Jul-01, Volume: 100, Issue:7 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Cell Proliferation; Diet; Diet, Protein-Restricted; Dietary Supplements; Digestion; Inositol; Phosphorus; Phytic Acid; Swine	2022
Effects of phytase supplementation of high-plant-protein diets on growth, phosphorus utilization, antioxidant, and digestion in red swamp crayfish (Procambarus clarkii). Fish & shellfish immunology, 2022, Volume: 127 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Antioxidants; Astacoidea; Calcium; Diet; Dietary Supplements; Digestion; Phosphorus; Phosphorus, Dietary; Phytic Acid; Plant Proteins	2022
Microbial phytase reduces basal endogenous loss of calcium in pigs fed diets containing phytate phosphorus at commercial levels. Journal of animal science, 2022, Oct-01, Volume: 100, Issue:10 Topics: 6-Phytase; Animal Feed; Animals; Calcium; Calcium, Dietary; Diet; Digestion; Gastrointestinal Tract; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine	2022
Phosphorus release capacity in different dietary commercial phytases through performance and bone characteristics assessment of broiler chickens. Anais da Academia Brasileira de Ciencias, 2022, Volume: 94, Issue:4 Topics: 6-Phytase; Animals; Chickens; Diet; Male; Phosphorus; Phytic Acid; Weight Gain	2022
Dietary calcium and non-phytate phosphorus levels affect the performance, serum biochemical indices, and lipid metabolism in growing pullets. Poultry science, 2023, Volume: 102, Issue:2 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium, Dietary; Chickens; Diet; Dietary Supplements; Female; Lipid Metabolism; Phosphorus; Phosphorus, Dietary; Phytic Acid	2023
Effect of a biosynthetic bacterial 6-phytase on the digestibility of phosphorus and phytate in midlactating dairy cows. Journal of animal science, 2023, Jan-03, Volume: 101 Topics: 6-Phytase; Animal Feed; Animals; Cattle; Diet; Digestion; Female; Lactation; Phosphorus; Phosphorus, Dietary; Phytic Acid; Zea mays	2023
Evaluation of Phosphorus Storage and Performance of Broilers Using Phytase Synthetic Enzyme. Archives of Razi Institute, 2023, Volume: 78, Issue:1 Topics: 6-Phytase; Animals; Calcium; Chickens; Phosphorus; Phosphorus, Dietary; Phytic Acid	2023

Other Studies

281 other study(ies) available for phosphorus and phytic acid

Article	Year
Phytate destruction by yeast fermentation in whole wheat meals. Study of high-extraction rate meals. Journal of the American Dietetic Association, 1975, Volume: 66, Issue:1 Topics: Bread; Cations, Divalent; Diet; Fermentation; Flour; Food-Processing Industry; Humans; Hydrogen-Ion Concentration; Inositol; Intestine, Small; Iran; Metals; Nutritional Physiological Phenomena; Phosphorus; Phytic Acid; Rural Population; Saccharomyces cerevisiae; Solubility; Triticum	1975
Phosphorus availability from n-paraffin-grown yeast. The Proceedings of the Nutrition Society, 1979, May-01, Volume: 38, Issue:1 Topics: Alkanes; Animals; Biological Assay; Chickens; Hindlimb; Male; Phosphorus; Phytic Acid; Yeasts	1979
A comparative study of the absorption of calcium and the availability of phytate-phosphorus in the golden hamster (Mesocricetus auratus) and the laboratory rat. The British journal of nutrition, 1979, Volume: 42, Issue:1 Topics: Animals; Calcium; Calcium, Dietary; Cricetinae; Diet; Intestinal Absorption; Male; Mesocricetus; Phosphorus; Phytic Acid; Rats	1979
Thy hydrolysis of phytate phosphorus by chicks and laying hens. Poultry science, 1976, Volume: 55, Issue:6 Topics: Animal Feed; Animals; Chickens; Hydrolysis; Inositol; Male; Phosphorus; Phytic Acid; Triticum; Zea mays	1976
Local effect of therapeutic agents on plaque composition. Journal of dental research, 1975, Volume: 54 Spec No B Topics: Administration, Oral; Calcium; Calcium Phosphates; Dental Plaque; Glycerophosphates; Humans; Nitrogen; Phosphates; Phosphorus; Phytic Acid; Saliva	1975
The effects of prolonged consumption of wholemeal bread upon metabolism of calcium, magnesium, zinc and phosphorus of two young American adults. Pahlavi medical journal, 1976, Volume: 7, Issue:1 Topics: Adult; Bread; Calcium; Eating; Female; Humans; Iran; Magnesium; Male; Phosphorus; Phytic Acid; Triticum; United States; Zinc	1976
IHP entrapment into human erythrocytes: comparison between hypotonic dialysis and DMSO osmotic pulse. Advances in experimental medicine and biology, 1992, Volume: 326 Topics: Dialysis; Dimethyl Sulfoxide; Erythrocyte Membrane; Hematologic Tests; Humans; Hypotonic Solutions; Magnetic Resonance Spectroscopy; Organophosphorus Compounds; Osmotic Pressure; Oxygen; Phosphorus; Phytic Acid; Titrimetry	1992
Quantitative IHP determination by 31P-NMR: proposal for a standardized protocol. Advances in experimental medicine and biology, 1992, Volume: 326 Topics: 2,3-Diphosphoglycerate; Adenosine Triphosphate; Dialysis; Dimethyl Sulfoxide; Diphosphoglyceric Acids; Erythrocyte Membrane; Humans; Hypotonic Solutions; Magnetic Resonance Spectroscopy; Osmotic Pressure; Phosphorus; Phytic Acid	1992
The effect of supplementary Aspergillus niger phytase in diets for pigs on concentration and apparent digestibility of dry matter, total phosphorus, and phytic acid in different sections of the alimentary tract. Journal of animal science, 1992, Volume: 70, Issue:4 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Digestion; Digestive System Physiological Phenomena; Duodenum; Hydrogen-Ion Concentration; Ileum; Male; Phosphorus; Phytic Acid; Swine	1992
Reduction of phytic acid in soybean products improves zinc bioavailability in rats. The Journal of nutrition, 1992, Volume: 122, Issue:12 Topics: Animals; Biological Availability; Diet; Eating; Glycine max; Male; Phosphorus; Phytic Acid; Rats; Rats, Sprague-Dawley; Tibia; Weight Gain; Zinc	1992
Disappearance of phosphorus in phytate from concentrates in vitro and from rations fed to lactating dairy cows. Journal of dairy science, 1992, Volume: 75, Issue:7 Topics: Animal Feed; Animals; Cattle; Feces; Female; Hydrolysis; Intestinal Absorption; Lactation; Least-Squares Analysis; Phosphorus; Phytic Acid	1992
Calcium and phosphorus requirements of the very young turkey as determined by response surface analysis. The British journal of nutrition, 1992, Volume: 67, Issue:3 Topics: Animals; Calcium; Calcium, Dietary; Diet; Male; Nutritional Requirements; Osteochondrodysplasias; Phosphorus; Phytic Acid; Poultry Diseases; Rickets; Time Factors; Turkeys; Weight Gain	1992
Enhancement of phosphorus utilization in growing pigs fed phytate-rich diets by using rye bran. Journal of animal science, 1991, Volume: 69, Issue:3 Topics: 6-Phytase; Absorption; Alkaline Phosphatase; Animal Feed; Animals; Bone Density; Calcium; Hydroxycholecalciferols; Male; Phosphorus; Phytic Acid; Random Allocation; Secale; Swine; Tibia; Weight Gain	1991
Effect of sodium aluminosilicate on phosphorus utilization by chicks and laying hens. Poultry science, 1991, Volume: 70, Issue:4 Topics: Aluminum Silicates; Animal Feed; Animals; Chickens; Dietary Fiber; Eating; Female; Male; Oviposition; Phosphorus; Phytic Acid; Regression Analysis; Tibia; Weight Gain; Zeolites	1991
Nutrient composition and anti-nutritional factors in selected vegetable soybean (Glycine max [L.] Merr.). Plant foods for human nutrition (Dordrecht, Netherlands), 1991, Volume: 41, Issue:1 Topics: Analysis of Variance; Calcium; Copper; Genotype; Glycine max; Iron; Manganese; Nutritive Value; Phosphorus; Phytic Acid; Plant Proteins; Potassium; Trypsin Inhibitors	1991
Improvement of phosphorus availability by microbial phytase in broilers and pigs. The British journal of nutrition, 1990, Volume: 64, Issue:2 Topics: 6-Phytase; Animals; Aspergillus; Biological Availability; Chickens; Diet; Digestion; Feces; Hydrogen-Ion Concentration; Male; Mathematics; Phosphorus; Phytic Acid; Swine	1990
Changes in some nutrients of fenugreek (Trigonella Foenum graecum L.) seeds during water boiling. Plant foods for human nutrition (Dordrecht, Netherlands), 1990, Volume: 40, Issue:4 Topics: Amino Acids; Carbohydrates; Cooking; Digestion; Fabaceae; Hot Temperature; Minerals; Nitrogen; Nutritive Value; Phosphorus; Phytic Acid; Plant Proteins; Plants, Medicinal; Seeds	1990
Comparison of chemical, histomorphometric, and absorptiometric analyses of bones of growing rats subjected to dietary calcium stress. Journal of the American College of Nutrition, 1990, Volume: 9, Issue:6 Topics: Absorptiometry, Photon; Animals; Body Weight; Bone and Bones; Bone Density; Calcium; Calcium, Dietary; Femur; Male; Mandible; Phosphorus; Phytic Acid; Rats; Rats, Inbred Strains; Tibia	1990
Binding of inositol hexakisphosphate to the oxygenated derivative of dromedary (Camelus dromedarius) and human hemoglobin: 31P-NMR study. Journal of inorganic biochemistry, 1989, Volume: 35, Issue:4 Topics: Animals; Camelus; Humans; Kinetics; Magnetic Resonance Spectroscopy; Oxyhemoglobins; Phosphorus; Phytic Acid; Protein Binding; Species Specificity	1989
Effect of roasting and autoclaving on phytic acid content of chickpea. Die Nahrung, 1989, Volume: 33, Issue:4 Topics: Cooking; Fabaceae; Phosphorus; Phytic Acid; Plants, Medicinal; Sterilization	1989
[Absence of effect of vitamin D on intestinal phytase and alkaline phosphatase: relation with phytic phosphorus in the pig]. Reproduction, nutrition, developpement, 1985, Volume: 25, Issue:4A Topics: 6-Phytase; Absorption; Alkaline Phosphatase; Animals; Bone and Bones; Calcifediol; Calcium; Intestines; Phosphates; Phosphorus; Phytic Acid; Swine; Vitamin D	1985
Importance of cereal phytase activity for phytate phosphorus utilization by growing pigs fed diets containing triticale or corn. The Journal of nutrition, 1987, Volume: 117, Issue:5 Topics: 6-Phytase; Animal Nutritional Physiological Phenomena; Animals; Bone and Bones; Calcium; Edible Grain; Intestine, Small; Phosphorus; Phytic Acid; Swine; Zea mays	1987
Phytate phosphorus intake and disappearance in the gastrointestinal tract of high producing dairy cows. Journal of dairy science, 1986, Volume: 69, Issue:12 Topics: Animals; Cattle; Digestive System; Female; Lactation; Phosphorus; Phytic Acid; Pregnancy	1986
Effects of vitamin D on calcium regulation in vitamin-D-deficient pigs given a phytate-phosphorus diet. The British journal of nutrition, 1986, Volume: 56, Issue:3 Topics: Alkaline Phosphatase; Animals; Calcium; Calcium-Binding Proteins; Diet; Kinetics; Parathyroid Hormone; Phosphorus; Phytic Acid; Swine; Vitamin D; Vitamin D Deficiency	1986
Magnesium intake during pregnancy. Magnesium, 1987, Volume: 6, Issue:1 Topics: Calcium; Diet; Female; Humans; Intestinal Absorption; Magnesium; Nutritional Physiological Phenomena; Phosphorus; Phytic Acid; Pregnancy; Socioeconomic Factors; Water	1987
Influence of dietary calcium, phosphorus, zinc and sodium phytate level on cataract incidence, growth and histopathology in juvenile chinook salmon (Oncorhynchus tshawytscha). The Journal of nutrition, 1985, Volume: 115, Issue:5 Topics: Animal Nutritional Physiological Phenomena; Animals; Biological Availability; Body Weight; Calcium, Dietary; Cataract; Diet; Drug Interactions; Growth; Kidney; Nephrocalcinosis; Phosphorus; Phytic Acid; Pylorus; Salmon; Trace Elements; Zinc	1985
A comparative study of phytate hydrolysis in the gastrointestinal tract of the golden hamster (Mesocricetus auratus) and the laboratory rat. The British journal of nutrition, 1985, Volume: 54, Issue:2 Topics: Alkaline Phosphatase; Animals; Bacteria; Cricetinae; Digestive System; Hydrogen-Ion Concentration; Hydrolysis; Mesocricetus; Phosphorus; Phytic Acid; Rats; Rats, Inbred Strains; Species Specificity	1985
Hydrolysis of the phytate of wheat flour during breadmaking. The British journal of nutrition, 1981, Volume: 46, Issue:1 Topics: 6-Phytase; Bread; Flour; Hydrolysis; Phosphorus; Phytic Acid	1981
The inhibitory effect of bran on iron absorption in man. The American journal of clinical nutrition, 1981, Volume: 34, Issue:8 Topics: Adult; Biological Availability; Cellulose; Chlorides; Dietary Fiber; Female; Ferric Compounds; Humans; Iron; Male; Phosphorus; Phytic Acid; Solubility; Triticum	1981
The effect of wheat bran on the absorption of minerals in the small intestine. The British journal of nutrition, 1982, Volume: 48, Issue:2 Topics: Adult; Aged; Calcium; Dietary Fiber; Female; Humans; Intestinal Absorption; Intestine, Small; Iron; Magnesium; Male; Middle Aged; Minerals; Phosphorus; Phytic Acid; Triticum; Zinc	1982
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. The British journal of nutrition, 1983, Volume: 49, Issue:1 Topics: 6-Phytase; Alkaline Phosphatase; Animals; Calcium; Diet; Digestion; Duodenum; Intestinal Mucosa; Male; Phosphorus; Phytic Acid; Rats; Rats, Inbred Strains	1983
Effect of fiber and phytate source and of calcium and phosphorus level on phytate hydrolysis in the chick. Poultry science, 1984, Volume: 63, Issue:2 Topics: Animals; Body Weight; Calcium, Dietary; Cellulose; Chickens; Cottonseed Oil; Dietary Fiber; Female; Hydrolysis; Medicago sativa; Oryza; Phosphorus; Phytic Acid; Triticum	1984
Influence of dietary phosphorus and sulphaguanidine levels on P utilization in rats. The British journal of nutrition, 1984, Volume: 51, Issue:3 Topics: 6-Phytase; Acid Phosphatase; Adaptation, Physiological; Animals; Bone and Bones; Calcium; Diet; Digestion; Female; Femur; Guanidines; Intestinal Mucosa; Male; Phosphorus; Phytic Acid; Rats; Rats, Inbred Strains; Sex Factors; Sulfaguanidine	1984
Phosphorus bioavailability in poultry nutrition. Nutrition reviews, 1984, Volume: 42, Issue:11 Topics: Animals; Biological Availability; Phosphorus; Phytic Acid; Poultry; Rats; Swine	1984
Phosphorus. 1. Effect of breed and strain on utilization of suboptimal levels of phosphorus in the ration. Poultry science, 1983, Volume: 62, Issue:1 Topics: Animals; Calcification, Physiologic; Calcium; Calcium Carbonate; Calcium Phosphates; Chickens; Diet; Male; Mortality; Phosphorus; Phytic Acid	1983
Determination of phytate in foods by phosphorus-31 Fourier transform nuclear magnetic resonance spectrometry. Analytical chemistry, 1980, Volume: 52, Issue:8 Topics: Food Analysis; Magnetic Resonance Spectroscopy; Phosphorus; Phytic Acid	1980
An in vitro procedure for studying enzymic dephosphorylation of phytate in maize-soyabean feeds for turkey poults. The British journal of nutrition, 1995, Volume: 74, Issue:1 Topics: Acid Phosphatase; Animal Feed; Animals; Aspartic Acid Endopeptidases; Aspergillus niger; Cellulase; Digestion; Female; Fungal Proteins; Glycine max; In Vitro Techniques; Pancreatin; Pepsin A; Phosphorus; Phytic Acid; Turkeys; Zea mays	1995
[Evaluation of Aspergillus niger phytase and phosphate in weaned piglets. 2. Content and gain of fat, energy, ash, Ca and P in the animal body]. Archiv fur Tierernahrung, 1995, Volume: 47, Issue:3 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Body Composition; Bone and Bones; Calcium; Energy Metabolism; Food, Fortified; Glycine max; Hordeum; Phosphates; Phosphorus; Phytic Acid; Proteins; Swine; Triticum; Weaning; Weight Gain	1995
Variability in phytic acid content and protein digestibility of grain legumes. Plant foods for human nutrition (Dordrecht, Netherlands), 1995, Volume: 47, Issue:2 Topics: Dietary Proteins; Digestion; Edible Grain; Fabaceae; Genotype; India; Nutritive Value; Phosphorus; Phytic Acid; Plant Proteins; Plants, Medicinal; Seeds	1995
Effects of magnesium citrate and phytin on reducing urinary calcium excretion in rats. World journal of urology, 1994, Volume: 12, Issue:6 Topics: Animals; Calcium; Calcium, Dietary; Citrates; Citric Acid; Magnesium; Male; Phosphorus; Phytic Acid; Rats; Rats, Wistar; Urinary Calculi	1994
Calcium level affects the efficacy of supplemental microbial phytase in corn-soybean meal diets of weanling pigs. Journal of animal science, 1994, Volume: 72, Issue:1 Topics: 6-Phytase; Alkaline Phosphatase; Animal Feed; Animals; Aspergillus niger; Biological Availability; Calcium; Calcium, Dietary; Eating; Food, Fortified; Glycine max; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Swine; Vitamin D; Weaning; Weight Gain; Zea mays	1994
Supplementing corn-soybean meal diets with microbial phytase linearly improves phytate phosphorus utilization by weanling pigs. Journal of animal science, 1993, Volume: 71, Issue:12 Topics: 6-Phytase; Absorption; Alkaline Phosphatase; Animal Feed; Animals; Aspergillus niger; Calcium; Calcium, Dietary; Digestion; Eating; Female; Glycine max; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Swine; Weaning; Weight Gain; Zea mays	1993
Supplementing corn-soybean meal diets with microbial phytase maximizes phytate phosphorus utilization by weanling pigs. Journal of animal science, 1993, Volume: 71, Issue:12 Topics: 6-Phytase; Alkaline Phosphatase; Animal Feed; Animals; Aspergillus niger; Calcium; Calcium, Dietary; Eating; Female; Glycine max; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Regression Analysis; Swine; Weaning; Weight Gain; Zea mays; Zinc	1993
The toxicants and phosphorus content of some Nigerian vegetables. Plant foods for human nutrition (Dordrecht, Netherlands), 1993, Volume: 44, Issue:3 Topics: Hydrogen Cyanide; Nigeria; Oxalates; Oxalic Acid; Phosphorus; Phytic Acid; Vegetables	1993
Dietary 1,25-dihydroxycholecalciferol supplementation increases natural phytate phosphorus utilization in chickens. The Journal of nutrition, 1993, Volume: 123, Issue:3 Topics: 6-Phytase; Animal Feed; Animals; Calcification, Physiologic; Calcitriol; Calcium; Chickens; Chromatography, High Pressure Liquid; Diet; Feces; Inositol Phosphates; Male; Phosphorus; Phytic Acid; Poultry Diseases; Rickets; Weight Gain	1993
High dietary calcium level decreases colonic phytate degradation in pigs fed a rapeseed diet. The Journal of nutrition, 1993, Volume: 123, Issue:3 Topics: Animals; Brassica; Calcium Carbonate; Chromatography, High Pressure Liquid; Colon; Diet; Digestion; Feces; Female; Gastric Mucosa; Hydrogen-Ion Concentration; Hydrolysis; Inositol Phosphates; Intestine, Small; Phosphorus; Phytic Acid; Stomach; Swine	1993
Additive effects of 1,25-dihydroxycholecalciferol and phytase on phytate phosphorus utilization and related parameters in broiler chickens. Poultry science, 1996, Volume: 75, Issue:1 Topics: 6-Phytase; Animals; Body Weight; Bone Density; Calcitriol; Chickens; Drug Synergism; Food, Fortified; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Poultry Diseases; Rickets	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, 1996, Volume: 75, Issue:1 Topics: 6-Phytase; Animals; Body Weight; Bone Density; Calcitriol; Calcium, Dietary; Chickens; Food, Fortified; Male; Nutritional Requirements; Phosphorus; Phosphorus, Dietary; Phytic Acid; Poultry Diseases; Rickets	1996
Effect of phytic acid and microbial phytase on Cd accumulation, Zn status, and apparent absorption of Ca, P, Mg, Fe, Zn, Cu, and Mn in growing rats. Annals of nutrition & metabolism, 1995, Volume: 39, Issue:6 Topics: 6-Phytase; Absorption; Animals; Aspergillus niger; Cadmium; Calcium; Copper; Diet; Iron; Kidney; Liver; Magnesium; Male; Manganese; Phosphorus; Phytic Acid; Rats; Rats, Wistar; Trace Elements; Zinc	1995
The efficacy of an enzymic cocktail and a fungal mycelium in dephosphorylating corn-soybean meal-based feeds fed to growing turkeys. Poultry science, 1996, Volume: 75, Issue:3 Topics: 6-Phytase; Animals; Aspergillus niger; Bone Density; Calcium; Food, Fortified; Glycine max; Organ Size; Phosphorus; Phytic Acid; Turkeys; Weight Gain; Zea mays	1996
Improving phytate phosphorus availability in corn and soybean meal for broilers using microbial phytase and calculation of phosphorus equivalency values for phytase. Poultry science, 1996, Volume: 75, Issue:2 Topics: 6-Phytase; Animals; Calcium; Chickens; Diet; Digestion; Food, Fortified; Glycine max; Linear Models; Male; Models, Biological; Nitrogen; Phosphorus; Phytic Acid; Random Allocation; Weight Gain; Zea mays	1996
Content of antinutrients and in vitro protein digestibility of the African yambean, pigeon and cowpea. Plant foods for human nutrition (Dordrecht, Netherlands), 1995, Volume: 48, Issue:3 Topics: Africa; Dietary Proteins; Digestion; Fabaceae; Linear Models; Nigeria; Phosphorus; Phytic Acid; Plant Proteins; Plants, Medicinal; Tannins; Trypsin Inhibitors	1995
Replacement of maize with sweet potato (Ipomoea batatas L.) tuber meal in broiler diets. British poultry science, 1996, Volume: 37, Issue:1 Topics: Animal Feed; Animals; Calcium; Calorimetry; Chickens; Energy Metabolism; Feeding Behavior; Food Analysis; Organ Size; Oxalates; Phosphorus; Phytic Acid; Plant Proteins, Dietary; Vegetables; Weight Gain; Zea mays	1996
The efficacy of Aspergillus niger phytase in rendering phytate phosphorus available for absorption in pigs is influenced by pig physiological status. Journal of animal science, 1997, Volume: 75, Issue:8 Topics: 6-Phytase; Absorption; Animals; Animals, Newborn; Aspergillus niger; Calcium; Diet; Dietary Supplements; Digestion; Female; Male; Phosphorus; Phytic Acid; Pregnancy; Pregnancy, Animal; Swine	1997
Utilization of phytate and nonphytate phosphorus in chicks as affected by source and amount of vitamin D3. Journal of animal science, 1997, Volume: 75, Issue:11 Topics: Animals; Chickens; Cholecalciferol; Diet; Dose-Response Relationship, Drug; Female; Glycine max; Hydroxycholecalciferols; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Tibia; Weight Gain; Zea mays	1997
The effects of 1,25-dihydroxycholecalciferol and phytase on the natural phytate phosphorus utilization by laying hens. Poultry science, 1998, Volume: 77, Issue:6 Topics: 6-Phytase; Analysis of Variance; Animal Feed; Animals; Calcitriol; Chickens; Digestion; Eggs; Female; Food, Fortified; Oviposition; Phosphorus; Phytic Acid	1998
Soybeans transformed with a fungal phytase gene improve phosphorus availability for broilers. Poultry science, 1998, Volume: 77, Issue:6 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Biological Availability; Bone Development; Chickens; Digestion; Glycine max; Male; Phosphorus; Phytic Acid; Plants, Genetically Modified	1998
Adding wheat middlings, microbial phytase, and citric acid to corn-soybean meal diets for growing pigs may replace inorganic phosphorus supplementation. Journal of animal science, 1998, Volume: 76, Issue:10 Topics: 6-Phytase; Animal Feed; Animals; Biological Availability; Bone Density; Citric Acid; Diet; Female; Glycine max; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine; Triticum; Weight Gain; Zea mays	1998
Effects of steam pelleting and extrusion of feed on phytate phosphorus utilization in broiler chickens. Poultry science, 1999, Volume: 78, Issue:1 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Chickens; Food Handling; Glycine max; Hot Temperature; Nutritive Value; Phosphorus; Phytic Acid; Zea mays	1999
Cloning, sequencing, and expression of an Escherichia coli acid phosphatase/phytase gene (appA2) isolated from pig colon. Biochemical and biophysical research communications, 1999, Apr-02, Volume: 257, Issue:1 Topics: 6-Phytase; Acid Phosphatase; Amino Acid Sequence; Animals; Base Sequence; Cloning, Molecular; Colon; Escherichia coli; Escherichia coli Proteins; Fungi; Genes, Bacterial; Glycosylation; Hydrogen-Ion Concentration; Kinetics; Molecular Sequence Data; Molecular Weight; Multienzyme Complexes; Nitrophenols; Organophosphorus Compounds; Phosphorus; Phytic Acid; Recombinant Proteins; Sequence Homology, Amino Acid; Swine; Temperature	1999
Expression of an Aspergillus niger phytase gene (phyA) in Saccharomyces cerevisiae. Applied and environmental microbiology, 1999, Volume: 65, Issue:5 Topics: 6-Phytase; Animals; Antibodies, Fungal; Aspergillus niger; Base Sequence; DNA Primers; Enzyme Stability; Gene Expression; Genes, Fungal; Glycosylation; Humans; Hydrogen-Ion Concentration; Phosphorus; Phytic Acid; Rabbits; Saccharomyces cerevisiae; Temperature	1999
Effect of processing methods on the calcium, phosphorus, and phytic acid contents and nutritive utilization of chickpea (Cicer arietinum L.). Journal of agricultural and food chemistry, 1999, Volume: 47, Issue:7 Topics: Animals; Calcium; Diet; Fabaceae; Female; Food Handling; Male; Nutritive Value; Phosphorus; Phytic Acid; Plants, Medicinal; Rats; Rats, Wistar	1999
Effect of various domestic processing and cooking methods on phytic acid and HCl-extractability of calcium, phosphorus and iron of pigeon pea. Nutrition and health, 1999, Volume: 13, Issue:3 Topics: Analysis of Variance; Biological Availability; Calcium; Cooking; Food Handling; Germination; Hydrochloric Acid; Iron; Phosphorus; Phytic Acid; Pisum sativum	1999
Nonphytate phosphorus requirement of laying hens with and without phytase on a phase feeding program. Poultry science, 2000, Volume: 79, Issue:5 Topics: 6-Phytase; Age Factors; Animal Feed; Animals; Body Weight; Calcium; Chickens; Digestion; Eating; Egg Shell; Eggs; Feces; Female; Nitrogen; Nutritional Requirements; Oviposition; Phosphorus; Phytic Acid; Specific Gravity; Tibia	2000
Response of broiler chickens to microbial phytase supplementation as influenced by dietary phytic acid and non-phytate phosphorous levels. II. Effects on apparent metabolisable energy, nutrient digestibility and nutrient retention. British poultry science, 2000, Volume: 41, Issue:2 Topics: 6-Phytase; Amino Acids; Analysis of Variance; Animals; Chickens; Chromatography, Ion Exchange; Dietary Supplements; Digestion; Eating; Energy Metabolism; Feces; Ileum; Linear Models; Male; Nitrogen; Phosphorus; Phytic Acid	2000
Effect of calcium supplements to a maize-soya diet on the bioavailability of minerals and trace elements and the accumulation of heavy metals in growing rats. Journal of veterinary medicine. A, Physiology, pathology, clinical medicine, 2000, Volume: 47, Issue:6 Topics: Alkaline Phosphatase; Aminolevulinic Acid; Animal Feed; Animals; Cadmium; Calcium; Calcium, Dietary; Dietary Supplements; Femur; Hemoglobins; Kidney; Lead; Liver; Magnesium; Male; Phosphorus; Phytic Acid; Rats; Rats, Wistar; Zinc	2000
Effects of low phytic acid corn on phosphorus utilization, performance, and bone mineralization in broiler chicks. Poultry science, 2000, Volume: 79, Issue:10 Topics: Animal Nutritional Physiological Phenomena; Animals; Calcification, Physiologic; Chickens; Diet; Eating; Male; Phosphorus; Phytic Acid; Weight Gain; Zea mays	2000
Nonphytate phosphorus requirement and phosphorus excretion of broiler chicks fed diets composed of normal or high available phosphate corn with and without microbial phytase. Poultry science, 2000, Volume: 79, Issue:10 Topics: 6-Phytase; Animal Feed; Animals; Calcification, Physiologic; Chickens; Diet; Feces; Male; Nutritional Requirements; Phosphates; Phosphorus; Phytic Acid; Regression Analysis; Tibia; Zea mays	2000
The use of near-infrared reflectance spectroscopy to predict the moisture, nitrogen, calcium, total phosphorus, gross energy, and phytate phosphorus contents of broiler excreta. Poultry science, 2001, Volume: 80, Issue:3 Topics: Animal Feed; Animals; Calcium; Calibration; Chickens; Feces; Nitrogen; Phosphorus; Phytic Acid; Reproducibility of Results; Spectroscopy, Near-Infrared; Water	2001
Extracellular secretion of Aspergillus phytase from Arabidopsis roots enables plants to obtain phosphorus from phytate. The Plant journal : for cell and molecular biology, 2001, Volume: 25, Issue:6 Topics: 6-Phytase; Arabidopsis; Aspergillus niger; DNA, Fungal; Extracellular Space; Genes, Fungal; Genes, Plant; Molecular Sequence Data; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid; Plant Proteins; Plant Roots; Plants, Genetically Modified; Signal Transduction	2001
Prolonged fermentation of whole wheat sourdough reduces phytate level and increases soluble magnesium. Journal of agricultural and food chemistry, 2001, Volume: 49, Issue:5 Topics: Bread; Fermentation; Hydrogen-Ion Concentration; Lactobacillus; Magnesium; Phosphorus; Phytic Acid; Solubility; Triticum; Yeasts	2001
Processing of newly released ricebean and fababean cultivars: changes in total and available calcium, iron and phosphorus. International journal of food sciences and nutrition, 2001, Volume: 52, Issue:5 Topics: Analysis of Variance; Calcium; Colorimetry; Fabaceae; Food Handling; Humans; Iron, Dietary; Nutritive Value; Phosphorus; Phytic Acid; Plants, Medicinal; Spectrophotometry, Atomic	2001
Preparation of phytate-removed deamidated soybean globulins by ion exchangers and characterization of their calcium-binding ability. Journal of agricultural and food chemistry, 2002, Jan-02, Volume: 50, Issue:1 Topics: Biological Availability; Calcium; Deamination; Globulins; Glycine max; Humans; Intestinal Absorption; Ion Exchange Resins; Phosphorus; Phytic Acid; Temperature	2002
Low-phytic acid corn improves nutrient utilization for growing pigs. Journal of animal science, 2001, Volume: 79, Issue:11 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Biological Availability; Bone and Bones; Calcium, Dietary; Diet; Energy Metabolism; Male; Nitrogen; Nutritive Value; Phosphorus; Phytic Acid; Random Allocation; Swine; Zea mays	2001
Hydrolysis of phytic acid by intrinsic plant or supplemented microbial phytase (Aspergillus niger) in the stomach and small intestine of minipigs fitted with re-entrant cannulas. Journal of animal physiology and animal nutrition, 2001, Volume: 85, Issue:11-12 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Digestion; Gastric Mucosa; Hydrolysis; Intestine, Small; Male; Phosphorus; Phytic Acid; Swine; Swine, Miniature	2001
Hydrolysis of phytic acid by intrinsic plant and supplemented microbial phytase (Aspergillus niger) in the stomach and small intestine of minipigs fitted with re-entrant cannulas. 2. Phytase activity. Journal of animal physiology and animal nutrition, 2001, Volume: 85, Issue:11-12 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Digestion; Gastric Mucosa; Hydrogen-Ion Concentration; Hydrolysis; Intestine, Small; Male; Phosphorus; Phytic Acid; Swine; Swine, Miniature	2001
Hydrolysis of phytic acid by intrinsic plant and supplemented microbial phytase (Aspergillus niger) in the stomach and small intestine of minipigs fitted with re-entrant cannulas. 3. Hydrolysis of phytic acid (IP6) and occurrence of hydrolysis products (I Journal of animal physiology and animal nutrition, 2001, Volume: 85, Issue:11-12 Topics: 6-Phytase; Animal Feed; Animals; Aspergillus niger; Digestion; Gastric Mucosa; Hydrolysis; Intestine, Small; Isomerism; Male; Phosphorus; Phytic Acid; Swine; Swine, Miniature	2001
Studies on the efficacy of cholecalciferol and derivatives for stimulating phytate utilization in broilers. Poultry science, 2002, Volume: 81, Issue:7 Topics: Animal Nutritional Physiological Phenomena; Animals; Body Weight; Calcifediol; Calcitriol; Calcium; Chickens; Cholecalciferol; Diet; Dietary Supplements; Glycine max; Hydroxycholecalciferols; Male; Phosphorus; Phytic Acid; Zea mays	2002
Low-phytic acid barley improves calcium and phosphorus utilization and growth performance in growing pigs. Journal of animal science, 2002, Volume: 80, Issue:10 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Biological Availability; Bone and Bones; Calcium; Hordeum; Intestinal Absorption; Male; Nutritive Value; Phosphorus; Phytic Acid; Swine	2002
The development of feedstuff retainable phosphorus values for broilers. Poultry science, 2002, Volume: 81, Issue:11 Topics: Animal Feed; Animals; Biological Assay; Biological Availability; Calcification, Physiologic; Calcium, Dietary; Chickens; Feces; Male; Nutritional Requirements; Nutritive Value; Phosphorus; Phosphorus, Dietary; Phytic Acid	2002
Changes in phytates and HCl extractability of calcium, phosphorus, and iron of soaked, dehulled, cooked, and sprouted pigeon pea cultivar (UPAS-120). Plant foods for human nutrition (Dordrecht, Netherlands), 2002,Fall, Volume: 57, Issue:3-4 Topics: Biological Availability; Cajanus; Calcium; Cooking; Food Handling; Germination; Hydrochloric Acid; Iron; Nutritive Value; Phosphorus; Phytic Acid	2002
Seed phosphorus and inositol phosphate phenotype of barley low phytic acid genotypes. Phytochemistry, 2003, Volume: 62, Issue:5 Topics: Chromatography, High Pressure Liquid; Genotype; Hordeum; Inositol Phosphates; Mutation; Nuclear Magnetic Resonance, Biomolecular; Phenotype; Phosphorus; Phytic Acid; Seeds; Stereoisomerism; Zea mays	2003
Effect of dietary calcium, 25-hydroxycholecalciferol, or bird strain on small intestinal phytase activity in broiler chickens. Poultry science, 2003, Volume: 82, Issue:7 Topics: 6-Phytase; Animals; Calcifediol; Calcium Carbonate; Calcium, Dietary; Chickens; Hydrolysis; Intestinal Mucosa; Intestine, Small; Male; Phosphorus; Phytic Acid; Species Specificity; Weight Gain	2003
Phytic acid distribution in foodstuffs; its relation to calcium and total phosphorus. The Journal of the Egyptian Medical Association, 1954, Volume: 37, Issue:6 Topics: Calcium; Calcium, Dietary; Food; Inositol; Phosphorus; Phosphorus, Dietary; Phytic Acid	1954
[Research on phosphorus and calcium medication; study of inositol hexaphosphates]. Bulletin de la Societe de chimie biologique, 1954, Volume: 36, Issue:8 Topics: Calcium, Dietary; Inositol; Phosphorus; Phosphorus, Dietary; Phytic Acid; Research	1954
Studies on phytic acid phosphorus metabolism in ruminants. I. Distribution of phytic-acid phosphorus and total phosphorus in some of the common Indian cattle feeds. The Indian journal of medical research, 1955, Volume: 43, Issue:4 Topics: Animals; Cattle; Food; Phosphorus; Phytic Acid; Ruminants	1955
Studies on phytic acid phosphorus metabolism in ruminants. II. Influence of high, low and medium levels of ingestion of phytic-acid phosphorus on calcium, phosphorus and magnesium metabolism. The Indian journal of medical research, 1955, Volume: 43, Issue:4 Topics: Animals; Calcium; Cattle; Eating; Magnesium; Phosphorus; Phytic Acid; Ruminants	1955
Comparative metabolism of phytate and inorganic P32 by chicks and poults. The Journal of nutrition, 1957, May-10, Volume: 62, Issue:1 Topics: Animals; Carbohydrate Metabolism; Chickens; Inositol; Meat; Phosphorus; Phytic Acid; Poultry; Turkeys	1957
Comparative availability of phytin and inorganic phosphorus to rumen microorganisms, in vitro. Proceedings of the Society for Experimental Biology and Medicine. Society for Experimental Biology and Medicine (New York, N.Y.), 1962, Volume: 109 Topics: Animals; Biochemical Phenomena; Carbohydrate Metabolism; In Vitro Techniques; Inactivation, Metabolic; Inositol; Phosphorus; Phytic Acid; Rumen; Stomach	1962
MINERAL UTILIZATION IN THE RAT. IV. EFFECTS OF CALCIUM AND PHYTIC ACID ON THE UTILIZATION OF DIETARY ZINC. The Journal of nutrition, 1965, Volume: 85, Issue:3 Topics: Calcium; Calcium, Dietary; Diet; Inositol; Magnesium; Metabolism; Minerals; Phosphorus; Phytic Acid; Rats; Research; Zinc	1965
PHYTATE METABOLISM IN ANIMALS. Nature, 1965, Jan-02, Volume: 205 Topics: Animals; Feces; Germ-Free Life; Inositol; Intestines; Meat; Phosphorus; Phytic Acid; Poultry; Research	1965
PHYTIC ACID-PHOSPHORUS CONTENT OF NIGERIAN FOODSTUFFS. The Indian journal of medical research, 1965, Volume: 53 Topics: Food Analysis; Inositol; Nigeria; Phosphorus; Phytic Acid; Research	1965
THE AVAILABILITY OF PHYTIC ACID PHOSPHORUS FOR CHICKS. 4. THE AVAILABILITY OF NATURAL PLANT PHOSPHORUS. Poultry science, 1965, Volume: 44 Topics: Animals; Chickens; Diet; Inositol; Meat; Phosphorus; Phosphorus, Dietary; Phytic Acid; Poultry; Research; Zea mays	1965
[The respective role of the kidney, intestine and bone in osteomalacias with hypophosphoremia and vitamin resistance: treatment with the combination of massive vitamin therapy and sodium phytate]. La semaine des hopitaux : organe fonde par l'Association d'enseignement medical des hopitaux de Paris, 1960, Apr-28, Volume: 36 Topics: Bone and Bones; Humans; Inositol; Intestines; Kidney; Osteomalacia; Phosphorus; Phosphorus Metabolism Disorders; Phytic Acid; Vitamin D; Vitamins	1960
The availability of the phosphorus in dicalcium phosphate, bonemeal, soft phosphate and calcium phytate for mature wethers. The Journal of nutrition, 1960, Volume: 70 Topics: Animals; Calcium Phosphates; Diet; Male; Nutrition Assessment; Phosphates; Phosphorus; Phosphorus, Dietary; Phytic Acid; Sheep	1960
Effectiveness of an experimental consensus phytase in improving dietary phytate-phosphorus utilization by weanling pigs. Journal of animal science, 2003, Volume: 81, Issue:11 Topics: 6-Phytase; Alkaline Phosphatase; Animal Feed; Animals; Biological Availability; Bone and Bones; Dose-Response Relationship, Drug; Escherichia coli; Nutritive Value; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine; Weaning; Weight Gain	2003
Effectiveness of twenty-five-hydroxycholecalciferol in the prevention of tibial dyschondroplasia in Ross cockerels depends on dietary calcium level. Poultry science, 2003, Volume: 82, Issue:11 Topics: Animals; Calcifediol; Calcium, Dietary; Chickens; Male; Osteochondrodysplasias; Phosphorus; Phosphorus, Dietary; Phytic Acid; Poultry Diseases; Tibia; Ultraviolet Rays	2003
Phytate phosphorus hydrolysis as influenced by dietary calcium and micro-mineral source in broiler diets. Journal of agricultural and food chemistry, 2003, Jul-30, Volume: 51, Issue:16 Topics: Amino Acids; Animals; Calcium, Dietary; Chickens; Diet; Hydrogen-Ion Concentration; Hydrolysis; Male; Minerals; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid	2003
Evaluation of low-phytate corn and barley on broiler chick performance. Poultry science, 2003, Volume: 82, Issue:12 Topics: Animal Nutritional Physiological Phenomena; Animals; Biological Availability; Biomechanical Phenomena; Bone and Bones; Calcium, Dietary; Chickens; Diet; Digestion; Hordeum; Magnesium; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid; Weight Gain; Zea mays; Zinc	2003
The effect of steam-flaked or dry ground corn and supplemental phytic acid on phosphorus partitioning and ruminal phytase activity in lactating cows. Journal of dairy science, 2003, Volume: 86, Issue:12 Topics: 6-Phytase; Animals; Cattle; Diet; Dietary Supplements; Digestion; Eating; Fatty Acids, Volatile; Feces; Female; Food Handling; Hydrogen-Ion Concentration; Lactation; Milk; Phosphorus; Phytic Acid; Rumen; Starch; Zea mays	2003
METABOLISM of phytin labeled with P32. Nutrition reviews, 1951, Volume: 9, Issue:4 Topics: Bone and Bones; Humans; Phosphorus; Phosphorus Compounds; Phosphorus, Dietary; Phytic Acid	1951
Orthophosphate, phytate, and total phosphorus determination in cereals by flow injection analysis. Journal of agricultural and food chemistry, 2004, Apr-07, Volume: 52, Issue:7 Topics: Edible Grain; Flow Injection Analysis; Hydrogen-Ion Concentration; Hydrolysis; Phosphates; Phosphorus; Phytic Acid; Spectrophotometry; Temperature	2004
High dietary phytase levels maximize phytate-phosphorus utilization but do not affect protein utilization in chicks fed phosphorus- or amino acid-deficient diets. Journal of animal science, 2004, Volume: 82, Issue:4 Topics: 6-Phytase; Amino Acids; Animal Feed; Animals; Aspergillus; Chickens; Dietary Proteins; Escherichia coli; Fungi; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Tibia; Weight Gain	2004
Effect of phytase supplementation on phosphorus digestibility in low-phytate barley fed to finishing pigs. Archives of animal nutrition, 2004, Volume: 58, Issue:1 Topics: 6-Phytase; Animal Feed; Animals; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Hordeum; Male; Phosphorus; Phytic Acid; Plants, Genetically Modified; Random Allocation; Swine	2004
Benefit of feeding dietary calcium and nonphytate phosphorus levels above National Research Council recommendations to tom turkeys in the growing-finishing phases. Poultry science, 2004, Volume: 83, Issue:4 Topics: Animal Feed; Animals; Calcium, Dietary; Dietary Supplements; Energy Metabolism; Male; Phosphorus; Phytic Acid; Turkeys; Weight Gain	2004
The effects of phytase and phytic acid on the loss of endogenous amino acids and minerals from broiler chickens. British poultry science, 2004, Volume: 45, Issue:1 Topics: 6-Phytase; Amino Acids; Animal Nutritional Physiological Phenomena; Animals; Chickens; Feces; Female; Glucose; N-Acetylneuraminic Acid; Nitrogen; Phosphorus; Phytic Acid; Random Allocation	2004
The apparent digestibility of phytate phosphorus and the influence of supplemental phytase in horses. Journal of animal science, 2004, Volume: 82, Issue:6 Topics: 6-Phytase; Animal Feed; Animals; Biological Availability; Calcium, Dietary; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Feces; Horses; Magnesium; Male; Phosphorus; Phytic Acid; Random Allocation; Urinalysis	2004
Acid phosphatase role in chickpea/maize intercropping. Annals of botany, 2004, Volume: 94, Issue:2 Topics: Acid Phosphatase; Agriculture; Biomass; Cicer; Crops, Agricultural; Organophosphates; Phosphates; Phosphorus; Phytic Acid; Plant Roots; Potassium Compounds; Zea mays	2004
Modeling of parameters affecting phytate phosphorus bioavailability in growing birds. Poultry science, 2004, Volume: 83, Issue:7 Topics: Animals; Biological Availability; Breeding; Calcium, Dietary; Chickens; Eating; Energy Intake; Feces; Female; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Sex Characteristics; Weight Gain	2004
Towards complete dephosphorylation and total conversion of phytates in poultry feeds. Poultry science, 2004, Volume: 83, Issue:7 Topics: 6-Phytase; Animal Feed; Animals; Calcification, Physiologic; Calcium; Calcium, Dietary; Chickens; Diet; Eating; Glycine max; Inositol; Organ Size; Phosphates; Phosphorus; Phytic Acid; Weight Gain; Zea mays	2004
Phytase, citric acid, and 1alpha-hydroxycholecalciferol improve phytate phosphorus utilization in chicks fed a corn-soybean meal diet. Poultry science, 2004, Volume: 83, Issue:7 Topics: 6-Phytase; Animals; Chickens; Citric Acid; Diet; Drug Synergism; Glycine max; Hydroxycholecalciferols; Male; Minerals; Phosphorus; Phytic Acid; Tibia; Weight Gain; Zea mays	2004
Bioavailability of phytic acid-phosphorus and magnesium from lentils (Lens culinaris m.) in growing rats: influence of thermal treatment and vitamin-mineral supplementation. Nutrition (Burbank, Los Angeles County, Calif.), 2004, Volume: 20, Issue:9 Topics: Animals; Biological Availability; Dietary Supplements; Female; Food Handling; Hot Temperature; Lens Plant; Magnesium; Male; Minerals; Nutritive Value; Phosphorus; Phytic Acid; Rats; Rats, Wistar; Vitamins; Weight Gain	2004
Influence of dietary calcium and phytase on phytate phosphorus hydrolysis in broiler chickens. Poultry science, 2004, Volume: 83, Issue:8 Topics: 6-Phytase; Animals; Biological Availability; Calcium, Dietary; Chickens; Diet; Digestion; Glycine max; Hydrogen-Ion Concentration; Hydrolysis; Intestinal Absorption; Phosphorus; Phytic Acid; Zea mays	2004
Unique precipitation and exocytosis of a calcium salt of myo-inositol hexakisphosphate in larval Echinococcus granulosus. Journal of cellular biochemistry, 2004, Dec-15, Volume: 93, Issue:6 Topics: 6-Phytase; Animals; Calcium; Cattle; Cell Wall; Echinococcosis; Echinococcus granulosus; Exocytosis; Helminth Proteins; Inositol Phosphates; Larva; Magnetic Resonance Spectroscopy; Mice; Phosphorus; Phytic Acid	2004
Metabolism of extracellular inositol hexaphosphate (phytate) by Saccharomyces cerevisiae. International journal of food microbiology, 2004, Dec-15, Volume: 97, Issue:2 Topics: 6-Phytase; Biological Availability; Bread; Culture Media; Food Handling; Food Microbiology; Hydrogen-Ion Concentration; Iron, Dietary; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid; Saccharomyces cerevisiae; Zinc	2004
High prevalence of low dietary calcium and low vitamin D status in healthy south Indians. Asia Pacific journal of clinical nutrition, 2004, Volume: 13, Issue:4 Topics: Adult; Biomarkers; Calcium; Calcium, Dietary; Feeding Behavior; Humans; India; Middle Aged; Nutritional Status; Phosphorus; Phosphorus, Dietary; Phytic Acid; Prevalence; Reference Values; Rural Health; Urban Health; Vitamin D; Vitamin D Deficiency	2004
Plant growth promotion abilities and microscale bacterial dynamics in the rhizosphere of Lupin analysed by phytate utilization ability. Environmental microbiology, 2005, Volume: 7, Issue:3 Topics: Burkholderia; Carbon; DNA, Bacterial; Inositol Phosphates; Phosphorus; Phytic Acid; Plant Roots; RNA, Ribosomal, 16S; Soil Microbiology	2005
Genetic analysis on the direct response to divergent selection for phytate phosphorus bioavailability in a randombred chicken population. Poultry science, 2005, Volume: 84, Issue:3 Topics: Animals; Biological Availability; Breeding; Chickens; Diet; Female; Male; Phosphorus; Phytic Acid; Selection, Genetic	2005
Spelt (Triticum aestivum ssp. spelta) as a source of breadmaking flours and bran naturally enriched in oleic acid and minerals but not phytic acid. Journal of agricultural and food chemistry, 2005, Apr-06, Volume: 53, Issue:7 Topics: Bread; Dietary Fiber; Fatty Acids; Flour; Lipids; Minerals; Nutritive Value; Oleic Acid; Phosphorus; Phytic Acid; Triticum	2005
Phosphorus source alters host plant response to ectomycorrhizal diversity. Mycorrhiza, 2005, Volume: 15, Issue:7 Topics: Biodiversity; Biomass; Mycorrhizae; Nitrogen; Phosphates; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid; Pinus; Plant Roots; Seedlings	2005
Ectopic expression of a soybean phytase in developing seeds of Glycine max to improve phosphorus availability. Plant molecular biology, 2004, Volume: 56, Issue:6 Topics: 6-Phytase; Antigens, Plant; Chromatography, High Pressure Liquid; Gene Expression Regulation, Developmental; Gene Expression Regulation, Enzymologic; Gene Expression Regulation, Plant; Globulins; Glycine max; Phosphorus; Phytic Acid; Plants, Genetically Modified; Promoter Regions, Genetic; Recombinant Fusion Proteins; RNA, Messenger; Seed Storage Proteins; Seeds; Soybean Proteins	2004
Correlated responses to divergent selection for phytate phosphorus bioavailability in a randombred chicken population. Poultry science, 2005, Volume: 84, Issue:4 Topics: Animals; Biological Availability; Body Weight; Breeding; Chickens; Energy Metabolism; Feeding Behavior; Female; Male; Phosphorus; Phytic Acid; Quantitative Trait Loci; Selection, Genetic	2005
A comparison of the test tube and the dialysis tubing in vitro methods for estimating the bioavailability of phosphorus in feed ingredients for swine. Journal of agricultural and food chemistry, 2005, May-04, Volume: 53, Issue:9 Topics: Animal Feed; Animals; Biological Availability; Dialysis; Digestion; Food Analysis; Hydrogen-Ion Concentration; Hydrolysis; Phosphorus; Phosphorus, Dietary; Phytic Acid; Reproducibility of Results; Swine	2005
Effect of grain source and exogenous phytase on phosphorus digestibility in dairy cows. Journal of dairy science, 2005, Volume: 88, Issue:8 Topics: 6-Phytase; Animal Nutritional Physiological Phenomena; Animals; Calcium; Cattle; Diet; Dietary Proteins; Digestion; Eating; Edible Grain; Fatty Acids, Volatile; Feces; Female; Hordeum; Hydrolysis; Intestinal Absorption; Lactation; Milk; Phosphorus; Phytic Acid; Rumen; Zea mays	2005
The effects of various organic acids on phytate phosphorus utilization in chicks. Poultry science, 2005, Volume: 84, Issue:9 Topics: Animals; Biological Availability; Bone and Bones; Calcium Gluconate; Carboxylic Acids; Chickens; Citric Acid; Crosses, Genetic; Diet; Eating; Edetic Acid; Female; Fumarates; Gluconates; Glycine max; Male; Methionine; Phosphorus; Phytic Acid; Weight Gain; Zea mays	2005
Citric acid improves phytate phosphorus utilization in crossbred and commercial broiler chicks. Poultry science, 2005, Volume: 84, Issue:9 Topics: Animals; Biological Availability; Bone and Bones; Chickens; Citric Acid; Crosses, Genetic; Diet; Eating; Glycine max; Male; Phosphorus; Phytic Acid; Weight Gain; Zea mays	2005
Effect of sodium phytate supplementation on fat digestion and cholesterol metabolism in female rats. Journal of animal physiology and animal nutrition, 2005, Volume: 89, Issue:11-12 Topics: Animal Feed; Animals; Bile Acids and Salts; Calcium; Cholesterol; Dietary Fats; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Feces; Female; Hydrogen-Ion Concentration; In Vitro Techniques; Intestinal Absorption; Liver; Magnesium; Phosphorus; Phytic Acid; Random Allocation; Rats; Solubility	2005
Beta-propeller phytases in the aquatic environment. Archives of microbiology, 2006, Volume: 185, Issue:1 Topics: 6-Phytase; Amino Acid Sequence; Bacillus subtilis; Base Sequence; Molecular Sequence Data; Phosphorus; Phylogeny; Phytic Acid; Protein Structure, Tertiary; Recombinant Proteins; Seawater; Shewanella; Water Microbiology	2006
Estimation of true phosphorus digestibility and endogenous phosphorus loss in growing pigs fed conventional and low-phytate soybean meals. Journal of animal science, 2006, Volume: 84, Issue:3 Topics: Animal Feed; Animals; Diet; Digestion; Eating; Gastrointestinal Tract; Glycine max; Linear Models; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Swine	2006
Effects of copper source and concentration on in vitro phytate phosphorus hydrolysis by phytase. Journal of agricultural and food chemistry, 2006, Mar-08, Volume: 54, Issue:5 Topics: 6-Phytase; Copper; Hydrogen-Ion Concentration; Hydrolysis; Phosphorus; Phytic Acid; Solubility	2006
[Phytate-phosphorus uptake and utilization by transgenic tobacco carrying Bacillus subtilis phytase gene]. Ying yong sheng tai xue bao = The journal of applied ecology, 2005, Volume: 16, Issue:12 Topics: 6-Phytase; Bacillus subtilis; Nicotiana; Phosphorus; Phytic Acid; Plants, Genetically Modified	2005
Access to organic and insoluble sources of phosphorus varies among soil Chytridiomycota. Archives of microbiology, 2006, Volume: 186, Issue:3 Topics: Alanine; Chytridiomycota; Durapatite; Methionine; Nitrates; Phosphates; Phosphorus; Phytic Acid; Soil Microbiology	2006
A revised model for studying phosphorus and calcium kinetics in growing sheep. Journal of animal science, 2006, Volume: 84, Issue:10 Topics: Animal Feed; Animals; Calcium; Calcium Radioisotopes; Feces; Kinetics; Male; Models, Biological; Phosphorus; Phosphorus Radioisotopes; Phytic Acid; Sheep	2006
The phosphorus source phytate changes the composition of the cell wall proteome in Bacillus subtilis. Journal of proteome research, 2007, Volume: 6, Issue:2 Topics: Bacillus subtilis; Bacterial Proteins; Base Sequence; Cell Wall; Molecular Sequence Data; Peptide Hydrolases; Phosphorus; Phytic Acid; Polymerase Chain Reaction; Proteome; RNA, Bacterial; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization	2007
Supplementation of carbohydrases or phytase individually or in combination to diets for weanling and growing-finishing pigs. Journal of animal science, 2007, Volume: 85, Issue:7 Topics: 6-Phytase; Amylases; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Endo-1,4-beta Xylanases; Female; Glycoside Hydrolases; Male; Peptide Hydrolases; Phosphorus; Phytic Acid; Random Allocation; Swine; Weaning; Weight Gain	2007
High prevalence of low dietary calcium, high phytate consumption, and vitamin D deficiency in healthy south Indians. The American journal of clinical nutrition, 2007, Volume: 85, Issue:4 Topics: Adult; Alkaline Phosphatase; Bone Density; Bone Density Conservation Agents; Calcium; Calcium, Dietary; Feeding Behavior; Female; Humans; India; Male; Middle Aged; Nutritional Status; Parathyroid Hormone; Phosphorus; Phosphorus, Dietary; Phytic Acid; Prevalence; Rural Health; Sunlight; Urban Health; Vitamin D; Vitamin D Deficiency	2007
Antinutritional factor content and hydrochloric acid extractability of minerals in pearl millet cultivars as affected by germination. International journal of food sciences and nutrition, 2007, Volume: 58, Issue:1 Topics: Calcium; Flavonoids; Food Handling; Germination; Hydrochloric Acid; Iron; Manganese; Minerals; Nutritive Value; Pennisetum; Phenols; Phosphorus; Phytic Acid; Polyphenols; Time Factors	2007
Comparison of the phosphorus and mineral concentrations in bran and abraded kernel fractions of a normal barley (Hordeum vulgare) cultivar versus four low phytic acid isolines. Journal of agricultural and food chemistry, 2007, May-30, Volume: 55, Issue:11 Topics: Calcium; Genotype; Hordeum; Metals; Minerals; Phosphorus; Phytic Acid; Sulfur	2007
Effect of low-phytate barley or phytase supplementation to a barley-soybean meal diet on phosphorus retention and excretion by grower pigs. Journal of animal science, 2007, Volume: 85, Issue:11 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Feces; Glycine max; Hordeum; Male; Nutritive Value; Phosphorus; Phytic Acid; Random Allocation; Swine; Weight Gain	2007
Influence of phytin phosphorous and dietary fibre on in vitro iron and calcium bioavailability from rice flakes. International journal of food sciences and nutrition, 2007, Volume: 58, Issue:8 Topics: Biological Availability; Calcium; Dietary Fiber; Food Technology; Humans; Infant; Iron; Nutritive Value; Oryza; Phosphorus; Phytic Acid	2007
Transgenic maize plants expressing a fungal phytase gene. Transgenic research, 2008, Volume: 17, Issue:4 Topics: 6-Phytase; Aspergillus niger; Blotting, Western; Globulins; Phosphorus; Phytic Acid; Plants, Genetically Modified; Plasmids; Promoter Regions, Genetic; Seeds; Transformation, Genetic; Zea mays	2008
Distribution and diversity of phytate-mineralizing bacteria. The ISME journal, 2007, Volume: 1, Issue:4 Topics: 6-Phytase; Bacteria; Bacterial Proteins; Genes, Bacterial; Membrane Proteins; Molecular Sequence Data; Phosphorus; Phylogeny; Phytic Acid; Soil Microbiology; Water Microbiology	2007
The total phosphorus, phytate phosphorus and inorganic phosphorus of bread and the destruction of phytic acid in bread making. The Australian journal of experimental biology and medical science, 1949, Volume: 27, Issue:Pt 1 Topics: Acids; Bread; Inorganic Chemicals; Organophosphorus Compounds; Phosphorus; Phosphorus Compounds; Phosphorus, Dietary; Phytic Acid	1949
Quantitative conversion of phytate to inorganic phosphorus in soybean seeds expressing a bacterial phytase. Plant physiology, 2008, Volume: 146, Issue:2 Topics: 6-Phytase; Acid Phosphatase; Animal Feed; Escherichia coli Proteins; Gene Expression; Germination; Glycine max; Phosphorus; Phytic Acid; Plants, Genetically Modified; Seeds	2008
Interaction of calcium and phytate in broiler diets. 2. Effects on total and soluble phosphorus excretion. Poultry science, 2008, Volume: 87, Issue:3 Topics: Adaptation, Physiological; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium, Dietary; Chickens; Dose-Response Relationship, Drug; Drug Interactions; Female; Glycine max; Ileum; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Solubility; Time Factors	2008
Effects of ethylenediaminetetraacetic acid on phytate phosphorus utilization and efficiency of microbial phytase in broiler chicks. Journal of animal physiology and animal nutrition, 2008, Volume: 92, Issue:2 Topics: 6-Phytase; Alkaline Phosphatase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Chickens; Dose-Response Relationship, Drug; Edetic Acid; Food Additives; Male; Phosphorus; Phytic Acid; Random Allocation; Weight Gain	2008
The effect of several organic acids on phytate phosphorus hydrolysis in broiler chicks. Poultry science, 2008, Volume: 87, Issue:4 Topics: 6-Phytase; Animal Nutritional Physiological Phenomena; Animals; Body Weight; Carboxylic Acids; Chelating Agents; Chickens; Citric Acid; Edetic Acid; Female; Fumarates; Malates; Male; Minerals; Phosphorus; Phytic Acid; Poultry Diseases; Random Allocation; Rickets	2008
Phytate utilization by genetically engineered lysine-producing Corynebacterium glutamicum. Journal of biotechnology, 2008, Apr-30, Volume: 134, Issue:3-4 Topics: 6-Phytase; Bacillus; Corynebacterium glutamicum; Culture Media; Genetic Engineering; Genetic Vectors; Lysine; Phosphates; Phosphorus; Phytic Acid; Transformation, Bacterial; Transgenes	2008
A model of phosphorus digestion and metabolism in the lactating dairy cow. Journal of dairy science, 2008, Volume: 91, Issue:5 Topics: 6-Phytase; Animals; Bone and Bones; Cattle; Digestion; Female; Gastrointestinal Tract; Intestinal Absorption; Lactation; Models, Biological; Phosphorus; Phosphorus, Dietary; Phytic Acid; Rumen	2008
Dephosphorylation and quantification of organic phosphorus in poultry litter by purified phytic-acid high affinity Aspergillus phosphohydrolases. Chemosphere, 2008, Volume: 72, Issue:11 Topics: Animals; Aspergillus; Fungal Proteins; Phosphoric Monoester Hydrolases; Phosphorus; Phosphorylation; Phytic Acid; Poultry; Waste Management	2008
Nutrient retention and growth performance of chicks given low-phytate conventional or hull-less barleys. British poultry science, 2008, Volume: 49, Issue:3 Topics: Animal Feed; Animals; Chickens; Energy Intake; Hordeum; Meat; Phosphorus; Phytic Acid; Random Allocation; Weight Gain	2008
Isolation and characterization of a low phytic acid rice mutant reveals a mutation in the rice orthologue of maize MIK. TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik, 2008, Volume: 117, Issue:8 Topics: Amino Acid Sequence; DNA, Plant; Gene Expression Regulation, Plant; Genes, Plant; Inositol Phosphates; Molecular Sequence Data; Mutation; Oryza; Phosphorus; Phytic Acid; Seeds; Sequence Alignment; Sequence Analysis, DNA	2008
Studies in human mineral metabolism; the effect of bread rich in phytate phosphorus on the metabolism of certain mineral salts with special reference to calcium. The Biochemical journal, 1948, Volume: 42, Issue:3 Topics: Bread; Calcium; Humans; Minerals; Phosphorus; Phytic Acid; Salts	1948
The total phosphorus, phytate phosphorus and inorganic phosphorus content of wheat, and its mill products. The Australian journal of experimental biology and medical science, 1948, Volume: 26, Issue:Pt 5 Topics: Dietary Fats, Unsaturated; Phosphorus; Phosphorus Compounds; Phosphorus, Dietary; Phytic Acid; Triticum	1948
The role of vitamin D in the utilization of phytin phosphorus. The Journal of nutrition, 1948, Feb-10, Volume: 35, Issue:2 Topics: Humans; Phosphorus; Phosphorus, Dietary; Phytic Acid; Vitamin D; Vitamins	1948
Influence of phosphorus nutrition on growth and metabolism of Duo grass (Duo festulolium). Plant physiology and biochemistry : PPB, 2009, Volume: 47, Issue:1 Topics: 6-Phytase; Acid Phosphatase; Adenosine Monophosphate; Adenosine Triphosphate; Biodegradation, Environmental; Biomass; Phosphates; Phosphorus; Phytic Acid; Poaceae; Potassium Compounds; Seedlings	2009
Dynamics of phosphorus and phytate-utilizing bacteria during aerobic degradation of dairy cattle dung. Chemosphere, 2009, Volume: 74, Issue:2 Topics: Aerobiosis; Animals; Bacteria, Aerobic; Biodegradation, Environmental; Bioreactors; Cattle; Dairying; Feces; Manure; Phosphorus; Phytic Acid	2009
Effects of low-phytic acid corn, low-phytic acid soybean meal, and phytase on nutrient digestibility and excretion in growing pigs. Journal of animal science, 2009, Volume: 87, Issue:4 Topics: 6-Phytase; Animal Feed; Animals; Diet; Digestion; Eating; Glycine max; Male; Metalloporphyrins; Phosphorus; Phytic Acid; Quaternary Ammonium Compounds; Swine; Zea mays	2009
Nutrient excretion, phosphorus characterization, and phosphorus solubility in excreta from broiler chicks fed diets containing graded levels of wheat distillers grains with solubles. Poultry science, 2008, Volume: 87, Issue:12 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Diet; Feces; Phosphorus; Phytic Acid; Triticum	2008
Localisation of phosphomonoesterase activity in ectomycorrhizal fungi grown on different phosphorus sources. Mycorrhiza, 2009, Volume: 19, Issue:3 Topics: Apatites; DNA, Fungal; DNA, Ribosomal Spacer; Fungi; Molecular Sequence Data; Mycelium; Mycorrhizae; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid; Sequence Analysis, DNA	2009
Ileal digestibility and endogenous flow of minerals and amino acids: responses to dietary phytic acid in piglets. The British journal of nutrition, 2009, Volume: 102, Issue:3 Topics: Amino Acids; Animal Feed; Animals; Calcium; Digestion; Ileum; Isoleucine; Leucine; Magnesium; Male; Minerals; Phosphorus; Phytic Acid; Potassium; Random Allocation; Sodium; Swine; Valine	2009
Diversity of beta-propeller phytase genes in the intestinal contents of grass carp provides insight into the release of major phosphorus from phytate in nature. Applied and environmental microbiology, 2009, Volume: 75, Issue:6 Topics: 6-Phytase; Amino Acid Sequence; Animals; Bacteria; Carps; Cluster Analysis; Gastrointestinal Contents; Molecular Sequence Data; Phosphorus; Phylogeny; Phytic Acid; Sequence Alignment; Sequence Analysis, DNA; Sequence Homology	2009
Differential effects of a transgene to confer low phytic acid in caryopses located at different positions in rice panicles. Plant & cell physiology, 2009, Volume: 50, Issue:7 Topics: Gene Expression Regulation, Plant; Gene Silencing; Glutens; Intramolecular Lyases; Oryza; Phosphates; Phosphorus; Phytic Acid; Plant Proteins; Plants, Genetically Modified; Promoter Regions, Genetic; Seeds; Transgenes	2009
The Arabidopsis ATP-binding cassette protein AtMRP5/AtABCC5 is a high affinity inositol hexakisphosphate transporter involved in guard cell signaling and phytate storage. The Journal of biological chemistry, 2009, Nov-27, Volume: 284, Issue:48 Topics: Adenylyl Imidodiphosphate; Arabidopsis Proteins; Biological Transport; Genetic Complementation Test; Green Fluorescent Proteins; Inositol Phosphates; Microscopy, Confocal; Microsomes; Multidrug Resistance-Associated Proteins; Mutation; Phosphorus; Phytic Acid; Plant Epidermis; Plant Stomata; Plants, Genetically Modified; Seeds; Signal Transduction; Yeasts	2009
Influence of variety, location, growing year, and storage on the total phosphorus, phytate-phosphorus, and phytate-phosphorus to total phosphorus ratio in rice. Journal of agricultural and food chemistry, 2010, Mar-10, Volume: 58, Issue:5 Topics: Oryza; Phosphorus; Phytic Acid; Species Specificity	2010
The effect of phytic acid on the absorption of calcium and phosphorus; in infants. The Biochemical journal, 1946, Volume: 40, Issue:4 Topics: Calcium; Humans; Infant; Minerals; Phosphorus; Phytic Acid; Water-Electrolyte Balance	1946
The effect of phytic acid on the absorption of calcium and phosphorus; in children. The Biochemical journal, 1946, Volume: 40, Issue:4 Topics: Calcium; Humans; Minerals; Phosphorus; Phytic Acid; Water-Electrolyte Balance	1946
Ileal digestibility of amino acids, phosphorus, phytate and energy in pigs fed sorghum-based diets supplemented with phytase and Pancreatin®. Journal of animal physiology and animal nutrition, 2011, Volume: 95, Issue:2 Topics: 6-Phytase; Amino Acids; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Dietary Supplements; Digestion; Ileum; Pancreatin; Phosphorus; Phytic Acid; Sorghum; Swine	2011
An integrated approach to the degradation of phytates in the corn wet milling process. Bioresource technology, 2010, Volume: 101, Issue:23 Topics: 6-Phytase; Aspergillus niger; Biotechnology; Calibration; Color; Escherichia coli; Hydrolysis; Indicators and Reagents; Inositol; Inositol Phosphates; Phosphates; Phosphorus; Phytic Acid; Time Factors; Waste Products; Zea mays	2010
Genetic interrelationships among phosphorus, nitrogen, calcium, and energy bioavailability in a growing chicken population. Poultry science, 2010, Volume: 89, Issue:11 Topics: Animals; Biological Availability; Calcium; Chickens; Crosses, Genetic; Energy Metabolism; Female; Male; Nitrogen; Phenotype; Phosphorus; Phytic Acid	2010
The influence of phytic acid on the absorption of calcium and phosphorus; in dogs. The Biochemical journal, 1946, Volume: 40, Issue:2 Topics: Animals; Calcium; Dogs; Phosphorus; Phosphorus Compounds; Phytic Acid; Water-Electrolyte Balance	1946
Studies on calcium and phosphorus metabolism; calcium, phosphorus and phytin contents of the diets of Kangra valley and their relation to nutrition. The Indian journal of medical research, 1945, Volume: 33 Topics: Calcium; Calcium, Dietary; Diet; Humans; India; Minerals; Nutritional Requirements; Nutritional Sciences; Nutritional Status; Phosphorus; Phytic Acid	1945
Identification of β-propeller phytase-encoding genes in culturable Paenibacillus and Bacillus spp. from the rhizosphere of pasture plants on volcanic soils. FEMS microbiology ecology, 2011, Volume: 75, Issue:1 Topics: 6-Phytase; Agriculture; Amino Acid Sequence; Bacillus; Chile; Consensus Sequence; Genes, Bacterial; Molecular Sequence Data; Paenibacillus; Phosphorus; Phylogeny; Phytic Acid; Poaceae; Polymerase Chain Reaction; Protein Structure, Tertiary; Rhizosphere; Soil; Soil Microbiology	2011
Effect of tetracalcium dimagnesium phytate on bone characteristics in ovariectomized rats. Journal of medicinal food, 2010, Volume: 13, Issue:6 Topics: Amino Acids; Animals; Biomarkers; Bone and Bones; Bone Density; Bone Resorption; Calcium; Calcium, Dietary; Diet; Disease Models, Animal; Female; Femur; Humans; Lumbar Vertebrae; Magnesium; Osteocalcin; Osteogenesis; Osteoporosis, Postmenopausal; Phosphorus; Phytic Acid; Random Allocation; Rats; Rats, Wistar	2010
Diversity, abundance and characterization of ruminal cysteine phytases suggest their important role in phytate degradation. Environmental microbiology, 2011, Volume: 13, Issue:3 Topics: 6-Phytase; Amino Acid Sequence; Animals; Bacteria; Cattle; Cysteine; Goats; Molecular Sequence Data; Phosphorus; Phytic Acid; Rumen; Soil Microbiology	2011
Effect of transgenic rhizobacteria overexpressing Citrobacter braakii appA on phytate-P availability to mung bean plants. Journal of microbiology and biotechnology, 2010, Volume: 20, Issue:11 Topics: 6-Phytase; Bacteria; Bacterial Proteins; Citrobacter; Fabaceae; Gene Expression; Phosphorus; Phytic Acid; Rhizosphere; Soil Microbiology; Transformation, Bacterial	2010
New insights into globoids of protein storage vacuoles in wheat aleurone using synchrotron soft X-ray microscopy. Journal of experimental botany, 2011, Volume: 62, Issue:11 Topics: Metals; Phosphorus; Phytic Acid; Seeds; Spectrometry, X-Ray Emission; Synchrotrons; Triticum; Vacuoles; X-Rays	2011
Impacts of phosphorus and zinc levels on phosphorus and zinc nutrition and phytic acid concentration in wheat (Triticum aestivum L.). Journal of the science of food and agriculture, 2011, Volume: 91, Issue:13 Topics: Algorithms; Biological Transport; Chelating Agents; Edetic Acid; Fertilizers; Hydroponics; Nutritive Value; Osmolar Concentration; Phosphorus; Phytic Acid; Plant Roots; Plant Stems; Seeds; Triticum; Zinc	2011
Differences among total and in vitro digestible phosphorus content of plant foods and beverages. Journal of renal nutrition : the official journal of the Council on Renal Nutrition of the National Kidney Foundation, 2012, Volume: 22, Issue:4 Topics: Beverages; Carbonated Beverages; Edible Grain; Fabaceae; Phosphorus; Phosphorus, Dietary; Phytic Acid; Seeds	2012
Phytate and other nutrient components of feed ingredients for poultry. Poultry science, 2012, Volume: 91, Issue:4 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Brassica; Calcium; Canada; Edible Grain; Glycine max; Phosphorus; Phytic Acid; Poultry; United States	2012
Sevelamer hydrochloride binds phosphate released from phytate in chicks fed 1α-hydroxy cholecalciferol. Journal of renal nutrition : the official journal of the Council on Renal Nutrition of the National Kidney Foundation, 2013, Volume: 23, Issue:1 Topics: Animal Feed; Animals; Chickens; Diet; Hydroxycholecalciferols; Hyperphosphatemia; Male; Minerals; Phosphates; Phosphorus; Phosphorus, Dietary; Phytic Acid; Polyamines; Sevelamer; Weight Gain	2013
'Fagiolo a Formella', an Italian lima bean ecotype: biochemical and nutritional characterisation of dry and processed seeds. Journal of the science of food and agriculture, 2012, Aug-30, Volume: 92, Issue:11 Topics: Chemical Phenomena; Dietary Proteins; Ecotype; Food Quality; Food, Preserved; Italy; Molecular Weight; Nutritive Value; Phaseolus; Phosphorus; Phytic Acid; Plant Proteins; Seeds; Trypsin Inhibitors; Water	2012
Compositional equivalence of barleys differing only in low- and normal-phytate levels. Journal of agricultural and food chemistry, 2012, Jul-04, Volume: 60, Issue:26 Topics: beta-Glucans; Breeding; Fatty Acids; Hordeum; Phosphorus; Phytic Acid; Seeds; Species Specificity; Tocopherols; Tocotrienols	2012
Disappearance of infused phytate from the large intestine of dairy heifers. Journal of dairy science, 2012, Volume: 95, Issue:10 Topics: Animal Nutritional Physiological Phenomena; Animals; Catheterization; Cattle; Diet; Digestion; Female; Ileum; Intestinal Absorption; Intestine, Large; Phosphorus; Phytic Acid; Rumen	2012
Evaluation of near-infrared reflectance spectroscopy (NIRS) techniques for total and phytate phosphorus of common poultry feed ingredients. Poultry science, 2012, Volume: 91, Issue:10 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Edible Grain; Phosphorus; Phytic Acid; Poultry; Spectroscopy, Near-Infrared	2012
Efficiency of phosphorus utilization in phyA-expressing cotton lines. Indian journal of biochemistry & biophysics, 2012, Volume: 49, Issue:4 Topics: 6-Phytase; Aspergillus; Extracellular Space; Gene Expression; Gossypium; Phosphorus; Phytic Acid; Plant Roots; Plants, Genetically Modified; Polymerase Chain Reaction; Rhizosphere; Soil	2012
Phytate degradation by fungi and bacteria that inhabit sawdust and coffee residue composts. Microbes and environments, 2013, Volume: 28, Issue:1 Topics: 6-Phytase; Bacteria; Coffee; Fungi; Phosphorus; Phytic Acid; Soil; Soil Microbiology; Wood	2013
Assessment of iron bioavailability in ten kinds of Chinese wheat flours using an in vitro digestion/Caco-2 cell model. Biomedical and environmental sciences : BES, 2012, Volume: 25, Issue:5 Topics: Biological Availability; Caco-2 Cells; China; Ferritins; Flour; Genetic Variation; Humans; Iron; Phosphorus; Phytic Acid; Triticum	2012
Effect of dietary phytate on phosphorus digestibility in dairy cows. Journal of dairy science, 2013, Volume: 96, Issue:2 Topics: Animals; Cattle; Diet; Dietary Supplements; Digestion; Female; Ileum; Omasum; Phosphorus; Phytic Acid	2013
Effect of phytase from Aspergillus niger on plant growth and mineral assimilation in wheat (Triticum aestivum Linn.) and its potential for use as a soil amendment. Journal of the science of food and agriculture, 2013, Volume: 93, Issue:9 Topics: 6-Phytase; Aspergillus niger; Calcium; Fertilizers; Fungal Proteins; Hydrogen-Ion Concentration; Hydrolysis; India; Iron; Manganese; Organic Agriculture; Phosphates; Phosphorus; Phytic Acid; Plant Shoots; Soil; Triticum	2013
Novel phytase from Pteris vittata resistant to arsenate, high temperature, and soil deactivation. Environmental science & technology, 2013, Mar-05, Volume: 47, Issue:5 Topics: 6-Phytase; Arsenates; Drug Resistance; Enzyme Activation; Phosphates; Phosphoric Monoester Hydrolases; Phosphorus; Phytic Acid; Plant Roots; Pteris; Soil; Soil Pollutants; Temperature; Teprotide	2013
[Phytic phosphorus and phytase activity in cereal-based infant formulas]. Archivos latinoamericanos de nutricion, 2012, Volume: 62, Issue:4 Topics: 6-Phytase; Biological Availability; Dietary Supplements; Edible Grain; Food Technology; Infant Formula; Phosphorus; Phytic Acid; Venezuela	2012
Isolation and identification of phytate-degrading bacteria and their contribution to phytate mineralization in soil. The Journal of general and applied microbiology, 2013, Volume: 59, Issue:5 Topics: Biomass; DNA, Bacterial; DNA, Ribosomal; Flavobacterium; Molecular Sequence Data; Phosphorus; Phytic Acid; Pseudomonas; RNA, Ribosomal, 16S; Sequence Analysis, DNA; Soil; Soil Microbiology	2013
Phytic acid in green leaves. Plant biology (Stuttgart, Germany), 2014, Volume: 16, Issue:4 Topics: Phosphorus; Phytic Acid; Plant Leaves; Seeds	2014
Localization of the Bacillus subtilis beta-propeller phytase transcripts in nodulated roots of Phaseolus vulgaris supplied with phytate. Planta, 2014, Volume: 239, Issue:4 Topics: 6-Phytase; Bacillus subtilis; Nitrogen Fixation; Phaseolus; Phosphorus; Phytic Acid; Plant Root Nodulation; Plant Roots; Plant Shoots; Rhizosphere; RNA, Bacterial; Symbiosis	2014
[Sorption and desorption characteristics of different structures of organic phosphorus onto aluminum (oxyhydr) oxides]. Huan jing ke xue= Huanjing kexue, 2013, Volume: 34, Issue:11 Topics: Adenosine Triphosphate; Adsorption; Aluminum Hydroxide; Aluminum Oxide; Glucose-6-Phosphate; Glycerophosphates; Phosphorus; Phytic Acid	2013
GmPAP4, a novel purple acid phosphatase gene isolated from soybean (Glycine max), enhanced extracellular phytate utilization in Arabidopsis thaliana. Plant cell reports, 2014, Volume: 33, Issue:4 Topics: Acid Phosphatase; Amino Acid Sequence; Arabidopsis; Cloning, Molecular; Computational Biology; Enzyme Assays; Escherichia coli; Extracellular Space; Gene Expression Regulation, Plant; Genes, Plant; Glycine max; Glycoproteins; Molecular Sequence Data; Phenotype; Phosphorus; Phylogeny; Phytic Acid; Plant Proteins; Plant Roots; Plants, Genetically Modified; Protein Transport; Sequence Alignment; Subcellular Fractions	2014
Seed-specific silencing of OsMRP5 reduces seed phytic acid and weight in rice. Transgenic research, 2014, Volume: 23, Issue:4 Topics: Body Weight; Germination; Multidrug Resistance-Associated Proteins; Mutation; Oryza; Phosphorus; Phytic Acid; Plant Proteins; Plants, Genetically Modified; Seeds	2014
Formations of hydroxyapatite and inositol hexakisphosphate in poultry litter during the composting period: sequential fractionation, P K-edge XANES and solution (31)P NMR investigations. Environmental science & technology, 2014, May-20, Volume: 48, Issue:10 Topics: Animals; Chemical Fractionation; Durapatite; Magnetic Resonance Spectroscopy; Manure; Phosphorus; Phosphorus Isotopes; Phytic Acid; Poultry; Soil; Solutions; Spectrum Analysis; Waste Products; X-Ray Absorption Spectroscopy; X-Ray Diffraction	2014
Standardized total tract digestibility of phosphorus in copra meal, palm kernel expellers, palm kernel meal, and soybean meal fed to growing pigs. Journal of animal science, 2014, Volume: 92, Issue:6 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Arecaceae; Diet; Dietary Supplements; Digestion; Feces; Glycine max; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Swine	2014
Mechanism of myo-inositol hexakisphosphate sorption on amorphous aluminum hydroxide: spectroscopic evidence for rapid surface precipitation. Environmental science & technology, 2014, Jun-17, Volume: 48, Issue:12 Topics: Adsorption; Aluminum; Aluminum Hydroxide; Aluminum Oxide; Chemical Precipitation; Environment; Hydrogen-Ion Concentration; Kinetics; Magnetic Resonance Spectroscopy; Phosphorus; Phytic Acid; Spectroscopy, Fourier Transform Infrared; Static Electricity; Temperature; X-Ray Diffraction	2014
Enhanced submerged Aspergillus ficuum phytase production by implementation of fed-batch fermentation. Bioprocess and biosystems engineering, 2014, Volume: 37, Issue:12 Topics: 6-Phytase; Amino Acids; Animal Feed; Aspergillus; Batch Cell Culture Techniques; Biomass; Bioreactors; Calcium Sulfate; Fermentation; Glucose; Hydrogen-Ion Concentration; Manure; Phosphorus; Phytic Acid; Temperature	2014
Comment on "Formations of hydroxyapatite and inositol hexakisphosphate in poultry litter during the composting period: sequential fractionation, P K-edge XANES and solution ³¹P NMR investigations". Environmental science & technology, 2014, Aug-19, Volume: 48, Issue:16 Topics: Animals; Chemical Fractionation; Durapatite; Magnetic Resonance Spectroscopy; Phosphorus; Phytic Acid; Soil; Waste Products; X-Ray Absorption Spectroscopy	2014
Investigation of soil legacy phosphorus transformation in long-term agricultural fields using sequential fractionation, P K-edge XANES and solution P NMR spectroscopy. Environmental science & technology, 2015, Jan-06, Volume: 49, Issue:1 Topics: Agriculture; Aluminum; Chemical Fractionation; Magnetic Resonance Spectroscopy; Oxides; Phosphates; Phosphorus; Phytic Acid; Saskatchewan; Soil; Triticum; Water Quality; X-Ray Absorption Spectroscopy	2015
Purification, biochemical characterization, and genetic cloning of the phytase produced by Burkholderia sp. strain a13. The Journal of general and applied microbiology, 2015, Volume: 61, Issue:1 Topics: 6-Phytase; Amino Acid Sequence; Burkholderia; Cloning, Molecular; Escherichia coli; Hafnia alvei; Lakes; Molecular Sequence Data; Phosphorus; Phytic Acid; Recombinant Proteins; Sequence Analysis, DNA; Substrate Specificity; Sulfhydryl Compounds	2015
Effect of germination on the physicochemical and antioxidant characteristics of rice flour from three rice varieties from Nigeria. Food chemistry, 2015, Oct-15, Volume: 185 Topics: Antioxidants; Chemical Phenomena; Flour; Germination; Magnesium; Nigeria; Oryza; Phosphorus; Phytic Acid; Plant Proteins; Potassium; Starch	2015
Probing Phosphorus Efficient Low Phytic Acid Content Soybean Genotypes with Phosphorus Starvation in Hydroponics Growth System. Applied biochemistry and biotechnology, 2015, Volume: 177, Issue:3 Topics: Dose-Response Relationship, Drug; Genotype; Glycine max; Hydroponics; Mutation; Phosphorus; Phytic Acid; Seeds	2015
A decrease in phytic acid content substantially affects the distribution of mineral elements within rice seeds. Plant science : an international journal of experimental plant biology, 2015, Volume: 238 Topics: Elements; Minerals; Mutation; Oryza; Phenotype; Phosphorus; Phytic Acid; Plants, Genetically Modified; Quantitative Trait, Heritable; Seeds	2015
The role of gluconate production by Pseudomonas spp. in the mineralization and bioavailability of calcium-phytate to Nicotiana tabacum. Canadian journal of microbiology, 2015, Volume: 61, Issue:12 Topics: 6-Phytase; Biological Availability; Calcium; Gluconates; Nicotiana; Phosphorus; Phytic Acid; Pseudomonas; Soil Microbiology	2015
Effect of phytate, microbial phytase, fiber, and soybean oil on calculated values for apparent and standardized total tract digestibility of calcium and apparent total tract digestibility of phosphorus in fish meal fed to growing pigs. Journal of animal science, 2015, Volume: 93, Issue:10 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Calcium, Dietary; Diet; Dietary Fiber; Digestion; Feces; Fish Products; Gastrointestinal Tract; Phosphorus; Phosphorus, Dietary; Phytic Acid; Soybean Oil; Swine; Zea mays	2015
Display of phytase on the cell surface of Saccharomyces cerevisiae to degrade phytate phosphorus and improve bioethanol production. Applied microbiology and biotechnology, 2016, Volume: 100, Issue:5 Topics: 6-Phytase; Bioreactors; Cell Surface Display Techniques; Enzymes, Immobilized; Ethanol; Fermentation; Manihot; Metabolic Engineering; Phosphorus; Phytic Acid; Recombinant Proteins; Saccharomyces cerevisiae; Zea mays	2016
The diversity and abundance of phytase genes (β-propeller phytases) in bacterial communities of the maize rhizosphere. Letters in applied microbiology, 2016, Volume: 62, Issue:3 Topics: 6-Phytase; Alteromonadaceae; Brazil; Caulobacter; Molecular Sequence Data; Phosphorus; Phylogeny; Phytic Acid; Pseudomonas; Rhizosphere; Soil; Soil Microbiology; Zea mays	2016
Phytase-mediated mineral solubilization from cereals under in vitro gastric conditions. Journal of the science of food and agriculture, 2016, Volume: 96, Issue:11 Topics: 6-Phytase; Aspergillus niger; Biological Availability; Carbohydrate Metabolism; Chelating Agents; Edible Grain; Escherichia coli; Gastrointestinal Tract; Humans; In Vitro Techniques; Iron; Minerals; Phosphorus; Phytic Acid; Solubility; Trace Elements; Triticum; Zinc	2016
Uranium bioprecipitation mediated by yeasts utilizing organic phosphorus substrates. Applied microbiology and biotechnology, 2016, Volume: 100, Issue:11 Topics: Biochemical Phenomena; Biodegradation, Environmental; Cryptococcus; Hydrogen-Ion Concentration; Kluyveromyces; Minerals; Phosphorus; Phytic Acid; Substrate Specificity; Uranium; X-Ray Diffraction	2016
The secretion of the bacterial phytase PHY-US417 by Arabidopsis roots reveals its potential for increasing phosphate acquisition and biomass production during co-growth. Plant biotechnology journal, 2016, Volume: 14, Issue:9 Topics: Arabidopsis; Biomass; Phosphates; Phosphorus; Phytic Acid; Plant Roots	2016
Carbon and phosphorus exchange may enable cooperation between an arbuscular mycorrhizal fungus and a phosphate-solubilizing bacterium. The New phytologist, 2016, Volume: 210, Issue:3 Topics: Acid Phosphatase; Bacteria; Carbon; Hyphae; Medicago sativa; Mycorrhizae; Phosphates; Phosphorus; Phytic Acid	2016
Disruption of OsSULTR3;3 reduces phytate and phosphorus concentrations and alters the metabolite profile in rice grains. The New phytologist, 2016, Volume: 211, Issue:3 Topics: Anion Transport Proteins; Biological Transport; Chromosome Mapping; Cloning, Molecular; Endoplasmic Reticulum; Gene Expression Regulation, Plant; Genes, Plant; Glucuronidase; Metabolic Networks and Pathways; Metabolome; Metabolomics; Mutation; Oryza; Phosphorus; Phytic Acid; Plant Proteins; Plant Vascular Bundle; Seeds; Subcellular Fractions; Sulfates; Sulfur	2016
Effects of production area and microbial phytase on the apparent and standardized total tract digestibility of phosphorus in soybean meal fed to growing pigs. Journal of animal science, 2016, Volume: 94, Issue:6 Topics: 6-Phytase; Animal Feed; Animals; Diet; Digestion; Feces; Female; Gastrointestinal Tract; Glycine max; Male; Phosphorus; Phytic Acid; Random Allocation; Swine; United States	2016
Pre-calving feeding of rumen-protected rice bran to multiparous dairy cows improves recovery of calcaemia after calving. The Journal of dairy research, 2016, Volume: 83, Issue:3 Topics: Animal Feed; Animals; Calcium; Calcium, Dietary; Cattle; Cattle Diseases; Dairying; Female; Hypocalcemia; Lactation; Oryza; Parity; Parturition; Phosphorus; Phytic Acid; Pregnancy; Rumen	2016
Reducing phosphorus accumulation in rice grains with an impaired transporter in the node. Nature, 2017, 01-05, Volume: 541, Issue:7635 Topics: Agriculture; Animals; Biological Transport; Edible Grain; Eutrophication; Fertilizers; Gene Knockout Techniques; Germination; Humans; Membrane Transport Proteins; Mutant Proteins; Mutation; Organ Specificity; Oryza; Phosphorus; Phytic Acid; Plant Cells; Plant Leaves; Plant Proteins; Seedlings; Xylem	2017
Hydrolysis of phytate to its lower esters can influence the growth performance and nutrient utilization of broilers with regular or super doses of phytase. Poultry science, 2017, Jul-01, Volume: 96, Issue:7 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Chickens; Diet; Dietary Supplements; Dose-Response Relationship, Drug; Energy Metabolism; Esters; Hydrolysis; Inositol Phosphates; Phosphorus; Phytic Acid; Random Allocation	2017
Effect of dietary mineral phosphorus and phytate on in situ ruminal phytate disappearance from different concentrates in dairy cows. Journal of dairy science, 2017, Volume: 100, Issue:5 Topics: Animal Feed; Animals; Cattle; Diet; Female; Lactation; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid; Rumen; Zea mays	2017
Phytate induced arsenic uptake and plant growth in arsenic-hyperaccumulator Pteris vittata. Environmental pollution (Barking, Essex : 1987), 2017, Volume: 226 Topics: Arsenic; Biodegradation, Environmental; Phosphorus; Phytic Acid; Plant Development; Plant Roots; Pteris; Soil; Soil Pollutants	2017
Land-use influences phosphatase gene microdiversity in soils. Environmental microbiology, 2017, Volume: 19, Issue:7 Topics: 6-Phytase; Alkaline Phosphatase; Grassland; Metagenome; Phosphorus; Phylogeny; Phytic Acid; Soil; Soil Microbiology	2017
Analysis of Lysophospholipid Content in Low Phytate Rice Mutants. Journal of agricultural and food chemistry, 2017, Jul-05, Volume: 65, Issue:26 Topics: Lysophospholipids; Mutation; Oryza; Phosphorus; Phytic Acid; Seeds	2017
Gibberellic acid promoting phytic acid degradation in germinating soybean under calcium lactate treatment. Journal of the science of food and agriculture, 2018, Volume: 98, Issue:2 Topics: 6-Phytase; Acid Phosphatase; Calcium Compounds; Gene Expression Regulation, Enzymologic; Gene Expression Regulation, Plant; Germination; Gibberellins; Glycine max; Lactates; Phospholipids; Phosphorus; Phytic Acid; Seeds	2018
Extracellular Secretion of Phytase from Transgenic Wheat Roots Allows Utilization of Phytate for Enhanced Phosphorus Uptake. Molecular biotechnology, 2017, Volume: 59, Issue:8 Topics: 6-Phytase; Gene Expression Regulation, Plant; Phosphorus; Phytic Acid; Plant Roots; Plants, Genetically Modified; Real-Time Polymerase Chain Reaction; Solutions; Stress, Physiological; Triticum	2017
Effects of Zn, macronutrients, and their interactions through foliar applications on winter wheat grain nutritional quality. PloS one, 2017, Volume: 12, Issue:7 Topics: Agriculture; Biomass; Drug Interactions; Edible Grain; Farms; Fertilizers; Nitrogen; Phosphorus; Phytic Acid; Plant Leaves; Plant Proteins; Potassium; Soil; Triticum; Zinc	2017
Inositol Hexakis Phosphate is the Seasonal Phosphorus Reservoir in the Deciduous Woody Plant Populus alba L. Plant & cell physiology, 2017, Sep-01, Volume: 58, Issue:9 Topics: Magnetic Resonance Spectroscopy; Phosphates; Phosphorus; Phytic Acid; Populus; Seasons; Spectrometry, X-Ray Emission; Wood	2017
Non-phytate phosphorus requirement for broilers from 8 to 21 days of age under heat stress conditions. Tropical animal health and production, 2018, Volume: 50, Issue:2 Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium, Dietary; Chickens; Diet; Hot Temperature; Male; Phosphorus; Phosphorus, Dietary; Phytic Acid; Random Allocation; Stress, Physiological; Tibia; Weight Gain	2018
Effects of a high level of phytase on broiler performance, bone ash, phosphorus utilization, and phytate dephosphorylation to inositol. Poultry science, 2018, Jan-01, Volume: 97, Issue:1 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcification, Physiologic; Chickens; Diet; Dietary Supplements; Digestion; Dose-Response Relationship, Drug; Male; Minerals; Phosphorus; Phytic Acid; Random Allocation	2018
Different Phosphorus Supplies Altered the Accumulations and Quantitative Distributions of Phytic Acid, Zinc, and Iron in Rice (Oryza sativa L.) Grains. Journal of agricultural and food chemistry, 2018, Feb-21, Volume: 66, Issue:7 Topics: Fertilizers; Hydroponics; Iron; Nutritive Value; Oryza; Phosphorus; Phytic Acid; Seeds; Zinc	2018
Phytate promoted arsenic uptake and growth in arsenic-hyperaccumulator Pteris vittata by upregulating phosphorus transporters. Environmental pollution (Barking, Essex : 1987), 2018, Volume: 241 Topics: Arsenic; Biodegradation, Environmental; Phosphates; Phosphorus; Phytic Acid; Plant Development; Plant Roots; Pteris; Soil; Soil Pollutants	2018
Seeds with low phosphorus content: not so bad after all? Journal of experimental botany, 2018, 10-12, Volume: 69, Issue:21 Topics: Oryza; Phosphorus; Phytic Acid; Seedlings; Seeds	2018
Evaluation of a new generation phytase on phytate phosphorus release for egg production and tibia strength in hens fed a corn-soybean meal diet. Poultry science, 2019, May-01, Volume: 98, Issue:5 Topics: 6-Phytase; Animal Nutritional Physiological Phenomena; Animals; Calcification, Physiologic; Calcium Phosphates; Chickens; Citrobacter; Dose-Response Relationship, Drug; Female; Phosphorus; Phytic Acid; Random Allocation; Reproduction	2019
Low digestibility of phytate phosphorus, their impacts on the environment, and phytase opportunity in the poultry industry. Environmental science and pollution research international, 2019, Volume: 26, Issue:10 Topics: 6-Phytase; Animal Feed; Animal Husbandry; Animals; Diet; Dietary Supplements; Digestion; Manure; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid; Poultry	2019
Promoting the use of locally produced crops in making cereal-legume-based composite flours: An assessment of nutrient, antinutrient, mineral molar ratios, and aflatoxin content. Food chemistry, 2019, Jul-15, Volume: 286 Topics: Aflatoxins; Crop Production; Edible Grain; Fabaceae; Flour; Food Contamination; Manihot; Minerals; Musa; Nutrients; Oryza; Phosphorus; Phytic Acid; Triticum; Zea mays	2019
Phytase-Fe Environmental science and pollution research international, 2019, Volume: 26, Issue:15 Topics: 6-Phytase; Catalysis; Environmental Restoration and Remediation; Eutrophication; Ferrous Compounds; India; Kinetics; Lakes; Microscopy, Electron, Transmission; Nanoparticles; Nitrogen; Phosphates; Phosphorus; Phytic Acid; Silicon Dioxide; Water Pollutants, Chemical	2019
Seed targeted RNAi-mediated silencing of GmMIPS1 limits phytate accumulation and improves mineral bioavailability in soybean. Scientific reports, 2019, 05-23, Volume: 9, Issue:1 Topics: Biological Availability; Fabaceae; Gene Expression Regulation, Plant; Genetic Engineering; Glycine max; Minerals; Myo-Inositol-1-Phosphate Synthase; Phosphorus; Phytic Acid; Plants, Genetically Modified; Promoter Regions, Genetic; RNA Interference; RNA, Antisense; Seed Storage Proteins; Seeds	2019
Insoluble dietary fiber does not affect the ability of phytase to release phosphorus from phytate in the diet of nursery pigs1. Journal of animal science, 2019, Jul-30, Volume: 97, Issue:8 Topics: 6-Phytase; Animal Feed; Animals; Diet; Dietary Fiber; Dietary Supplements; Digestion; Feces; Female; Gastrointestinal Tract; Glycine max; Male; Minerals; Phosphorus; Phytic Acid; Random Allocation; Swine; Zea mays	2019
Effects of myo-inositol hexakisphosphate, ferrihydrite coating, ionic strength and pH on the transport of TiO Environmental pollution (Barking, Essex : 1987), 2019, Volume: 252, Issue:Pt B Topics: Adsorption; Ferric Compounds; Hydrogen-Ion Concentration; Kinetics; Models, Chemical; Models, Theoretical; Nanoparticles; Osmolar Concentration; Phosphates; Phosphorus; Phytic Acid; Porosity; Quartz; Silicon Dioxide; Titanium; Water	2019
Phosphorus-acquisition strategies of canola, wheat and barley in soil amended with sewage sludges. Scientific reports, 2019, 10-16, Volume: 9, Issue:1 Topics: Acid Phosphatase; Biological Transport; Brassica rapa; Calcium Phosphates; Carboxylic Acids; Crops, Agricultural; Fertilizers; Hordeum; Humans; Phosphorus; Phytic Acid; Plant Proteins; Plant Roots; Plant Stems; Sewage; Soil; Species Specificity; Triticum	2019
Phosphorus excretion by mares post-lactation. Journal of animal physiology and animal nutrition, 2020, Volume: 104, Issue:6 Topics: Animal Feed; Animals; Diet; Digestion; Feces; Female; Horses; Lactation; Phosphorus; Phytic Acid	2020
Determination of Animal : an international journal of animal bioscience, 2020, Volume: 14, Issue:7 Topics: Animal Feed; Animals; Cattle; Diet; Digestion; Female; Phosphorus; Phytic Acid; Rumen; Spectroscopy, Near-Infrared	2020
Quantitative measures of myo-IP Environmental science. Processes & impacts, 2020, Apr-29, Volume: 22, Issue:4 Topics: Ecosystem; Magnetic Resonance Spectroscopy; Phosphorus; Phytic Acid; Soil	2020
High-phytate/low-calcium diet is a risk factor for crystal nephropathies, renal phosphate wasting, and bone loss. eLife, 2020, 04-09, Volume: 9 Topics: Animal Feed; Animals; Bone and Bones; Calcium; Calcium, Dietary; Diet; Female; Male; Minerals; Phosphates; Phosphorus; Phytic Acid; Rats, Sprague-Dawley; Renal Insufficiency, Chronic; Risk Factors	2020
Phosphorus toxicity disrupts Rubisco activation and reactive oxygen species defence systems by phytic acid accumulation in leaves. Plant, cell & environment, 2020, Volume: 43, Issue:9 Topics: Ascorbate Peroxidases; Chloroplasts; Cytosol; Enzyme Activation; Gene Expression Regulation, Plant; Oryza; Phosphorus; Photosynthesis; Phytic Acid; Plant Leaves; Plant Proteins; Reactive Oxygen Species; Ribulose-Bisphosphate Carboxylase; Superoxide Dismutase	2020
Dietary phytate has a greater anti-nutrient effect on feed conversion ratio compared to body weight gain and greater doses of phytase are required to alleviate this effect as evidenced by prediction equations on growth performance, bone ash and phytate de Poultry science, 2020, Volume: 99, Issue:1 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Body Weight; Calcium; Chickens; Diet; Male; Minerals; Phosphorus; Phytic Acid	2020
Increasing dietary phytate has a significant anti-nutrient effect on apparent ileal amino acid digestibility and digestible amino acid intake requiring increasing doses of phytase as evidenced by prediction equations in broilers. Poultry science, 2020, Volume: 99, Issue:1 Topics: 6-Phytase; Amino Acids; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Chickens; Diet; Digestion; Gastrointestinal Tract; Male; Phosphorus; Phytic Acid	2020
Physiological Characteristics, Phytase Activity, and Mineral Bioavailability of a Low-Phytate Soybean Line during Germination. Plant foods for human nutrition (Dordrecht, Netherlands), 2020, Volume: 75, Issue:3 Topics: 6-Phytase; Biological Availability; Germination; Glycine max; Minerals; Phosphorus; Phytic Acid	2020
Phytate degradation, myo-inositol release, and utilization of phosphorus and calcium by two strains of laying hens in five production periods. Poultry science, 2020, Volume: 99, Issue:12 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium; Chickens; Diet; Female; Inositol; Male; Phosphorus; Phytic Acid; Random Allocation	2020
Hierarchical Reactivity of Enzyme-Mediated Phosphorus Recycling from Organic Mixtures by Journal of agricultural and food chemistry, 2021, Feb-24, Volume: 69, Issue:7 Topics: 6-Phytase; Aspergillus niger; Molecular Docking Simulation; Phosphorus; Phytic Acid	2021
The wheat growth-promoting traits of Ochrobactrum and Pantoea species, responsible for solubilization of different P sources, are ensured by genes encoding enzymes of multiple P-releasing pathways. Microbiological research, 2021, Volume: 246 Topics: 6-Phytase; Bacterial Proteins; Glucose 1-Dehydrogenase; Ochrobactrum; Pantoea; Phosphates; Phosphoric Monoester Hydrolases; Phosphorus; Phylogeny; Phytic Acid; Plant Roots; Rhizosphere; Seedlings; Soil; Soil Microbiology; Triticum	2021
RNAi-mediated down-regulation of Journal of biosciences, 2021, Volume: 46 Topics: Edible Grain; Germination; Hordeum; Inositol; Minerals; Oryza; Phosphorus; Phosphotransferases (Alcohol Group Acceptor); Phytic Acid; Plants, Genetically Modified; Promoter Regions, Genetic; RNA Interference	2021
Determination of phytic acid in wheat products by complete methyl esterification and liquid chromatography-mass spectrometry analysis. Journal of separation science, 2021, Volume: 44, Issue:14 Topics: Chromatography, High Pressure Liquid; Chromatography, Liquid; Esterification; Phosphorus; Phytic Acid; Solid Phase Extraction; Tandem Mass Spectrometry; Triticum	2021
Effects and interaction of dietary calcium and non-phytate phosphorus for slow-growing yellow-feathered broilers during the starter phase. Animal : an international journal of animal bioscience, 2021, Volume: 15, Issue:5 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Calcium, Dietary; Chickens; Diet; Dietary Supplements; Female; Phosphorus; Phosphorus, Dietary; Phytic Acid	2021
A single nucleotide substitution in the SPDT transporter gene reduced phytic acid and increased mineral bioavailability from Rice grain (Oryza sativa L.). Journal of food biochemistry, 2021, Volume: 45, Issue:7 Topics: Biological Availability; Edible Grain; Humans; Minerals; Nucleotides; Oryza; Phosphorus; Phytic Acid	2021
Perspective: Plant-based Whole-Grain Foods for Chronic Kidney Disease: The Phytate-Phosphorus Conundrum. Advances in nutrition (Bethesda, Md.), 2021, 12-01, Volume: 12, Issue:6 Topics: Animal Feed; Animals; Diet; Humans; Nuts; Phosphorus; Phytic Acid; Renal Insufficiency, Chronic	2021
Influence of a novel consensus bacterial 6-phytase variant on mineral digestibility and bone ash in young growing pigs fed diets with different concentrations of phytate-bound phosphorus. Journal of animal science, 2021, Aug-01, Volume: 99, Issue:8 Topics: 6-Phytase; Animal Feed; Animals; Consensus; Diet; Dietary Supplements; Digestion; Gastrointestinal Tract; Minerals; Phosphorus; Phosphorus, Dietary; Phytic Acid; Sus scrofa; Swine	2021
Role of metal complexation on the solubility and enzymatic hydrolysis of phytate. PloS one, 2021, Volume: 16, Issue:8 Topics: Aluminum; Cadmium; Coordination Complexes; Copper; Ions; Iron; Magnesium; Manganese; Metals; Phosphorus; Phytic Acid; Potassium; Sodium; Zinc	2021
Evaluation of the responses of broiler chickens to varying concentrations of phytate phosphorus and phytase. Ⅰ. Starter phase (day 1-11 post hatching). Poultry science, 2021, Volume: 100, Issue:10 Topics: 6-Phytase; Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Chickens; Diet; Dietary Supplements; Digestion; Phosphorus; Phytic Acid	2021
Phytate as a Phosphorus Nutrient with Impacts on Iron Stress-Related Gene Expression for Phytoplankton: Insights from the Diatom Applied and environmental microbiology, 2022, 01-25, Volume: 88, Issue:2 Topics: Animals; Diatoms; Iron; Nutrients; Phosphorus; Phytic Acid; Phytoplankton; Transcriptome	2022
Effect of phytic acid and morphology on Fe (oxyhydr)oxide transport under saturated flow condition. Journal of hazardous materials, 2022, 02-15, Volume: 424, Issue:Pt D Topics: Adsorption; Ferric Compounds; Iron; Minerals; Oxides; Phosphorus; Phytic Acid	2022
Phytate-mediated phosphorylation of starch by dry heating with rice bran extract. Carbohydrate polymers, 2022, Apr-15, Volume: 282 Topics: Hot Temperature; Oryza; Phosphorus; Phosphorylation; Phytic Acid; Plant Extracts; Polyphosphates; Starch; Zea mays	2022
Distribution of Culturable Phosphate-Solubilizing Bacteria in Soil Aggregates and Their Potential for Phosphorus Acquisition. Microbiology spectrum, 2022, 06-29, Volume: 10, Issue:3 Topics: Bacteria; Clay; Ecosystem; Phosphates; Phosphorus; Phytic Acid; Pseudomonas; Soil; Soil Microbiology	2022
Adsorption of recalcitrant phosphorus compounds using the phosphate-selective binding-protein PstS. Chemosphere, 2022, Volume: 304 Topics: Adsorption; Hydrogen-Ion Concentration; Kinetics; Phosphate-Binding Proteins; Phosphates; Phosphorus; Phytic Acid; Wastewater; Water Pollutants, Chemical	2022
X-ray absorption near edge structure spectroscopy reveals phosphate minerals at surface and agronomic sampling depths in agricultural Ultisols saturated with legacy phosphorus. Chemosphere, 2022, Volume: 308, Issue:Pt 2 Topics: Aluminum; Aluminum Hydroxide; Calcium; Calcium Phosphates; Copper; Fertilizers; Iron; Manganese; Manure; Minerals; Phosphates; Phosphorus; Phytic Acid; Soil; X-Ray Absorption Spectroscopy	2022
Plant growth stimulation by high CO Current biology : CB, 2022, 10-24, Volume: 32, Issue:20 Topics: Arabidopsis; Carbon Dioxide; Chloroplasts; Genome-Wide Association Study; Homeostasis; Phosphorus; Phytic Acid; Plants; Sugars	2022
Biogeochemical dynamics of particulate organic phosphorus and its potential environmental implication in a typical "algae-type" eutrophic lake. Environmental pollution (Barking, Essex : 1987), 2022, Dec-01, Volume: 314 Topics: China; Dust; Ecosystem; Environmental Monitoring; Eutrophication; Geologic Sediments; Lakes; Particulate Matter; Phosphorus; Phytic Acid; Sodium Hydroxide; Water Pollutants, Chemical	2022
Composted invasive plant Ageratina adenophora enhanced barley (Hordeum vulgare) growth and soil conditions. PloS one, 2022, Volume: 17, Issue:9 Topics: Ageratina; Chlorophyll; Composting; Edible Grain; Fertilizers; Hordeum; Nitrate Reductases; Nitrogen; Oxidoreductases; Phosphorus; Phytic Acid; Plant Extracts; Potassium; Seedlings; Soil; Starch	2022
The Potential of Frontiers in bioscience (Landmark edition), 2022, 10-14, Volume: 27, Issue:10 Topics: Mutation; Phosphorus; Phytic Acid; Seeds; Zea mays	2022
Dephytinization of wheat and rice bran by cross-linked enzyme aggregates of Mucor indicus phytase: a viable prospect for food and feed industries. Journal of the science of food and agriculture, 2023, Mar-15, Volume: 103, Issue:4 Topics: 6-Phytase; Animal Feed; Diet; Dietary Fiber; Oryza; Phosphorus; Phytic Acid	2023
Phytate and Kidney Health: The Roles of Dietary Phytate in Inhibiting Intestinal Phosphorus Absorption and Intravenous Phytate in Decreasing Soft Tissue Calcification. Journal of renal nutrition : the official journal of the Council on Renal Nutrition of the National Kidney Foundation, 2023, Volume: 33, Issue:2 Topics: Animal Feed; Diet; Humans; Intestinal Absorption; Kidney; Phosphorus; Phosphorus, Dietary; Phytic Acid	2023
High-Efficient Flame-Retardant Finishing of Cotton Fabrics Based on Phytic Acid. International journal of molecular sciences, 2023, Jan-06, Volume: 24, Issue:2 Topics: Cotton Fiber; Flame Retardants; Phosphorus; Phytic Acid; Textiles	2023
Arbuscular mycorrhizal fungi enhance plant phosphorus uptake through stimulating hyphosphere soil microbiome functional profiles for phosphorus turnover. The New phytologist, 2023, Volume: 238, Issue:6 Topics: Bacteria; Fungi; Microbiota; Mycorrhizae; Phosphorus; Phytic Acid; Plant Roots; Soil; Soil Microbiology	2023
A novel green phosphorus-containing flame retardant finishing on polysaccharide-modified polyamide 66 fabric for improving hydrophilicity and durability. International journal of biological macromolecules, 2023, Jun-01, Volume: 239 Topics: Ammonia; Chitosan; Flame Retardants; Nylons; Phosphorus; Phytic Acid; Textiles	2023
Effect of phytase and limestone particle size on mineral digestibility, performance, eggshell quality, and bone mineralization in laying hens. Poultry science, 2023, Volume: 102, Issue:5 Topics: 6-Phytase; Animal Feed; Animals; Calcification, Physiologic; Calcium Carbonate; Chickens; Diet; Dietary Supplements; Egg Shell; Female; Minerals; Ovum; Particle Size; Phosphorus; Phytic Acid	2023
Impaired glycosylation of GmPAP15a, a root-associated purple acid phosphatase, inhibits extracellular phytate-P utilization in soybean. Plant, cell & environment, 2024, Volume: 47, Issue:1 Topics: Glycine max; Glycosylation; Phosphorus; Phytic Acid; Plant Proteins; Plant Roots; Soil	2024
Phosphorus nutrition strategies in a Symbiodiniacean species: Implications in coral-alga symbiosis facing increasing phosphorus deficiency in future warmer oceans. Global change biology, 2023, Volume: 29, Issue:23 Topics: Animals; Anthozoa; Coral Reefs; Dinoflagellida; Oceans and Seas; Phosphates; Phosphorus; Phytic Acid; Symbiosis	2023
Spectroscopic Investigation of Phosphorus Mineralization as Affected by the Calcite-Water Interfacial Chemistry. Environmental science & technology, 2023, 10-31, Volume: 57, Issue:43 Topics: 6-Phytase; Calcium Carbonate; Minerals; Phosphorus; Phytic Acid; Soil; Water	2023
Arabidopsis inositol pentakisphosphate 2-kinase, AtIPK1, is required for growth and modulates phosphate homeostasis at the transcriptional level. The Plant journal : for cell and molecular biology, 2014, Volume: 80, Issue:3 Topics: Arabidopsis; Arabidopsis Proteins; Gene Expression Profiling; Gene Expression Regulation, Plant; Homeostasis; Inositol Phosphates; Mutation; Phenotype; Phosphates; Phosphorus; Phosphotransferases (Alcohol Group Acceptor); Plant Roots; Seeds; Transcription Factors	2014