References
- Aherne SA, Daly T, Jiwan MA, O’Sullivan L, O’Brien NM. 2010. Bioavailability of β-carotene isomers from raw and cooked carrots using an in vitro digestion model coupled with a human intestinal Caco-2 cell model. Food Res Int. 43:1449–1454.
- Amalraj A, Pius A. 2015. Bioavailability of calcium and its absorption inhibitors in raw and cooked green leafy vegetables commonly consumed in India-an in vitro study. Food Chem. 170:430–436.
- Argyri K, Theophanidi E, Kapna A, Staikidou C, Pounis G, Komaitis M, Georgiou C, Kapsokefalou M. 2011. Iron or zinc dialyzability obtained from a modified in vitro digestion procedure compare well with iron or zinc absorption from meals. Food Chem. 127:716–721.
- Armah CN, Sharp P, Mellon FA, Pariagh S, Lund EK, Dainty JR, Teucher B, Fairweather-Tait SJ. 2008. L-alpha-glycerophosphocholine contributes to meat's enhancement of nonheme iron absorption. J Nutr. 138:873–877.
- Artimo P, Jonnalagedda M, Arnold K, Baratin D, Csardi G, de Castro E, Duvaud S, Flegel V, Fortier A, Gasteiger E, et al. 2012. ExPASy: SIB bioinformatics resource portal. Nucleic Acids Res. 40:W597–W603.
- Cámara F, Amaro MA, Barberá R, Clemente G. 2005. Bioaccessibility of minerals in school meals: comparison between dialysis and solubility methods. Food Chem. 92:481–489.
- Casgrain A, Collings R, Harvey LJ, Boza JJ, Fairweather-Tait SJ. 2010. Micronutrient bioavailability research priorities. Am J Clin Nutr. 91:1423S–1429S.
- Chow RB, Kassel B. 1968. Bovine pepsinogen and pepsin. I. Isolation, purification, and some properties of the pepsinogenJ Biol Chem. 243:1718–1724.
- Cupp-Enyard C. 2008. Sigma’s non-specific protease activity assay-casein as a substrate. J Vis Exp. 19:e899.
- Ekmekcioglu C. 2002. A physiological approach for preparing and conducting intestinal bioavailability studies using experimental systems. Food Chem. 76:225–230.
- Ekmekcioglu C, Strauss‐Blasche G, Marktl W. 1998. The plasma membrane Fe3‐reductase activity of Caco‐2 cells is modulated during differentiation. IUBMB Life. 46:951–961.
- Erfanian A, Rasti B, Manap Y. 2017. Comparing the calcium bioavailability from two types of nano-sized enriched milk using in-vivo assay. Food Chem. 214:606–613.
- Frontela C, Ros G, Martínez C. 2011. Phytic acid content and “in vitro” iron, calcium and zinc bioavailability in bakery products: the effect of processing. J Cereal Sci. 54:173–179.
- García-Nebot MJ, Barberá R, Alegría A. 2013. Iron and zinc bioavailability in Caco-2 cells: influence of caseinophosphopeptides. Food Chem. 138:1298–1303.
- Glahn RP, Lee OA, Yeung A, Goldman MI, Miller DD. 1998. Caco-2 cell ferritin formation predicts nonradiolabeled food iron availability in an in vitro digestion/Caco-2 cell culture model. J Nutr. 128:1555–1561.
- Glahn RP, Rassier M, Goldman MI, Lee OA, Cha J. 2000. A comparison of iron availability from commercial iron preparations using an in vitro digestion/Caco-2 cell culture model. J Nutr Biochem. 11:62–68.
- Glahn RP, Wien EM, Van Campen DR, Miller DD. 1996. Caco-2 cell iron uptake from meat and casein digests parallels in vivo studies: use of a novel in vitro method for rapid estimation of iron bioavailability. J Nutr. 126:332.
- Gordon DT, Godber JS. 1989. The enhancement of nonheme iron bioavailability by beef protein in the rat. J Nutr. 119:446–452.
- Gritti I, Banfi G, Roi G. 2000. Pepsinogens: physiology, pharmacology pathophysiology and exercise. Pharmacol Res. 41:265–281.
- Huh EC, Hotchkiss A, Brouillette J, Glahn RP. 2004. Carbohydrate fractions from cooked fish promote iron uptake by Caco-2 cells. J Nutr. 134:1681–1689.
- Hur SJ, Lim BO, Decker EA, McClements DJ. 2011. In vitro human digestion models for food applications. Food Chem. 125:1–12.
- Lung'aho MG, Glahn RP. 2009. In vitro estimates of iron bioavailability in some Kenyan complementary foods. Food Nutr Bull. 30:145–152.
- Miller D, Berner L. 1989. Is solubility in vitro a reliable predictor of iron bioavailability? Biol Trace Elem Res. 19:11–24.
- Miller DD, Schricker BR, Rasmussen RR, Van Campen D. 1981. An in vitro method for estimation of iron availability from meals. Am J Clin Nutr. 34:2248–2256.
- Minekus M, Alminger M, Alvito P, Ballance S, Bohn T, Bourlieu C, Carrière F, Boutrou R, Corredig M, Dupont D, et al. 2014. A standardised static in vitro digestion method suitable for food – an international consensus. Food Funct. 5:1113–1124.
- Patterson JK, Rutzke MA, Fubini SL, Glahn RP, Welch RM, Lei X, Miller DD. 2009. Dietary inulin supplementation does not promote colonic iron absorption in a porcine model. J Agric Food Chem. 57:5250–5256.
- Pynaert I, Armah C, Fairweather-Tait S, Kolsteren P, Van Camp J, De Henauw S. 2006. Iron solubility compared with in vitro digestion-Caco-2 cell culture method for the assessment of iron bioavailability in a processed and unprocessed complementary food for Tanzanian infants (6-12 months). Br J Nutr. 95:721–726.
- Qiao Y, Gumpertz M. 2002. Stability of pepsin (EC 3.4. 23.1) during in vitro protein digestibility assay. J Food Biochem. 26:355–375.
- Qiao Y, Gumpertz M, Van Kempen T. 2005. Stability of a pancreatic enzyme cocktail during in vitro protein digestibility assays. J Food Biochem. 29:205–220.
- Sandberg A-S, Svanberg U. 1991. Phytate hydrolysis by phytase in cereals; effects on In vitro estimation of iron availability. J Food Sci. 56:1330–1333.
- Storcksdieck G, Bonsmann S, Hurrell RF. 2007. Iron-binding properties, amino acid composition, and structure of muscle tissue peptides from in vitro digestion of different meat sources. J Food Sci. 72:S019–S029.
- Swain JH, Tabatabai LB, Reddy MB. 2002. Histidine content of low-molecular-weight beef proteins influences nonheme iron bioavailability in Caco-2 cells. J Nutr. 132:245–251.
- Tako E, Glahn R. 2012. Intra-amniotic administration and dietary inulin affect the iron status and intestinal functionality of iron-deficient broiler chickens. Poult Sci. 96:1361–1370.
- Thompson B, Sharp P, Elliott R, Al-Mutairi S, Fairweather-Tait SJ. 2010. Development of a modified Caco-2 cell model system for studying iron availability in eggs. J Agric Food Chem. 58:3833–3839.
- Thumser AE, Rashed AA, Sharp PA, Lodge JK. 2010. Ascorbate enhances iron uptake into intestinal cells through formation of a FeCl3-ascorbate complex. Food Chem. 123:281–285.
- Van Campen DR. 1973. Enhancement of iron absorption from ligated segments of rat intestine by histidine, cysteine, and lysine: effects of removing ionizing groups and of stereoisomerism. J Nutr. 103:139–142.
- Van Campen DR, Glahn RP. 1999. Micronutrient bioavailability techniques: accuracy, problems and limitations. F Crop Res. 60:93–113.
- Vaz-Tostes MG, Verediano TA, de Mejia EG, Brunoro Costa NM. 2016. Evaluation of iron and zinc bioavailability of beans targeted for biofortification using in vitro and in vivo models and their effect on the nutritional status of preschool children. J Sci Food Agric. 96:1326–1332.
- Vertzoni M, Dressman J, Butler J, Hempenstall J, Reppas C. 2005. Simulation of fasting gastric conditions and its importance for the in vivo dissolution of lipophilic compounds. Eur J Pharm Biopharm. 60:413–417.
- Worthington K, Worthington V. 2011. Worthington enzyme manual. New Jersey: Worthington Biochemical Corporation; 2017 (http://www.worthington-biochem.com/pap/default.html).
- Yeung CK, Zhu L, Glahn RP, Miller DD. 2014. Iron absorption from NaFeEDTA is downregulated in iron-loaded rats. J. Nutr. 134:2270–2274.
- Zhu L, Glahn RP, Nelson D, Miller DD. 2009. Comparing soluble ferric pyrophosphate to common iron salts and chelates as sources of bioavailable iron in a Caco-2 cell culture model. J Agric Food Chem. 57:5014–5019.