Blood 15N:13C Enrichment Ratios Are Proportional to the Ingested Quantity of Protein with the Dual-Tracer Approach for Determining Amino Acid Bioavailability in Humans

Nikkie van der Wielen, Nadezda V Khodorova, Walter J J Gerrits, Claire Gaudichon, Juliane Calvez, Daniel Tomé, Marco Mensink, Nikkie van der Wielen, Nadezda V Khodorova, Walter J J Gerrits, Claire Gaudichon, Juliane Calvez, Daniel Tomé, Marco Mensink

Abstract

Background: Assessment of amino acid bioavailability is of key importance for the evaluation of protein quality; however, measuring ileal digestibility of dietary proteins in humans is challenging. Therefore, a less-invasive dual stable isotope tracer approach was developed.

Objective: We aimed to test the assumption that the 15N:13C enrichment ratio in the blood increases proportionally to the quantity ingested by applying different quantities of 15N test protein.

Methods: In a crossover design, 10 healthy adults were given a semi-liquid mixed meal containing 25 g (low protein) or 50 g (high protein) of 15N-labeled milk protein concentrate simultaneous with 0.4 g of highly 13C-enriched spirulina. The meal was distributed over multiple small portions, frequently provided every 20 min during a period of 160 min. For several amino acids, the blood 15N- related to 13C-isotopic enrichment ratio was determined at t = 0, 30, 60, 90, 120, 180, 240, 300, and 360 min and differences between the 2 meals were compared using paired analyses.

Results: No differences in 13C AUC for each of the measured amino acids in serum was observed when ingesting a low- or high-protein meal, whereas 15N AUC of amino acids was ∼2 times larger on the high-protein meal (P < 0.001). Doubling the intake of 15N-labeled amino acids increased the 15N:13C ratio by a factor of 2.04 ± 0.445 for lysine and a factor between 1.8 and 2.2 for other analyzed amino acids, with only phenylalanine (2.26), methionine (2.48), and tryptophan (3.02) outside this range.

Conclusions: The amino acid 15N:13C enrichment ratio in the peripheral circulation increased proportionally to the quantity of 15N-labeled milk protein ingested, especially for lysine, in healthy adults. However, when using 15N-labeled protein, correction for, e.g., α-carbon 15N atom transamination is advised for determination of bioavailability of individual amino acids. This trial was registered at www.clinicaltrials.gov as NCT02966704.

Keywords: amino acid bioavailability; dual-tracer approach; milk protein; protein digestibility; spriulina; stable isotopes.

Copyright © The Author(s) on behalf of the American Society for Nutrition 2020.

Figures

FIGURE 1
FIGURE 1
Specific amino acid enrichment in blood of healthy subjects receiving a meal containing 25 g (A and C) or 50 g (B and D) of 15N-labeled milk protein concentrate with 0.4 g of 13C-labeled spirulina. The meal was frequently distributed in 9 discrete portions given every 20 min; the time frame is indicated on top of each graph. Values are means ± SDs, n = 10. APE, atom percent excess.

References

    1. Tome D, Jahoor F, Kurpad A, Michaelsen KF, Pencharz P, Slater C, Weisell R. Current issues in determining dietary protein quality and metabolic utilization. Eur J Clin Nutr. 2014;68:537–8.
    1. Tome D. Digestibility issues of vegetable versus animal proteins: protein and amino acid requirements—functional aspects. Food Nutr Bull. 2013;34:272–4.
    1. Fuller MF, Tomé D. In vivo determination of amino acid bioavailability in humans and model animals. J AOAC Int. 2005;88:923–34.
    1. Lee WT, Weisell R, Albert J, Tome D, Kurpad AV, Uauy R. Research approaches and methods for evaluating the protein quality of human foods proposed by an FAO Expert Working Group in 2014. J Nutr. 2016;146:929–32.
    1. van der Wielen N, Moughan PJ, Mensink M. Amino acid absorption in the large intestine of humans and porcine models. J Nutr. 2017;147(8):1493–8.
    1. Engelen MP, Com G, Anderson PJ, Deutz NE. New stable isotope method to measure protein digestibility and response to pancreatic enzyme intake in cystic fibrosis. Clin Nutr. 2014;33:1024–32.
    1. Tome D. Editorial on “Measurement of protein digestibility in humans by a dual tracer method”—a key limiting factor of protein quality. Am J Clin Nutr. 2018;107:855–6.
    1. Devi S, Varkey A, Sheshshayee MS, Preston T, Kurpad AV. Measurement of protein digestibility in humans by a dual-tracer method. Am J Clin Nutr. 2018;107:984–91.
    1. Kashyap S, Shivakumar N, Varkey A, Duraisamy R, Thomas T, Preston T, Devi S, Kurpad AV. Ileal digestibility of intrinsically labeled hen's egg and meat protein determined with the dual stable isotope tracer method in Indian adults. Am J Clin Nutr. 2018;108:980–7.
    1. Kashyap S, Shivakumar N, Varkey A, Preston T, Devi S, Kurpad AV. Co-ingestion of black tea reduces the indispensable amino acid digestibility of hens' egg in Indian adults. J Nutr. 2019;149:1363–8.
    1. Kashyap S, Varkey A, Shivakumar N, Devi S, Reddy BHR, Thomas T, Preston T, Sreeman S, Kurpad AV. True ileal digestibility of legumes determined by dual-isotope tracer method in Indian adults. Am J Clin Nutr. 2019;110(4):873–82.
    1. Gaudichon C, Bos C, Morens C, Petzke KJ, Mariotti F, Everwand J, Benamouzig R, Dare S, Tome D, Metges CC. Ileal losses of nitrogen and amino acids in humans and their importance to the assessment of amino acid requirements. Gastroenterology. 2002;123:50–9.
    1. Shivakumar N, Kashyap S, Kishore S, Thomas T, Varkey A, Devi S, Preston T, Jahoor F, Sheshshayee MS, Kurpad AV. Protein-quality evaluation of complementary foods in Indian children. Am J Clin Nutr. 2019;109:1319–27.
    1. Donkoh A, Moughan PJ. The effect of dietary crude protein content on apparent and true ileal nitrogen and amino acid digestibilities. Br J Nutr. 1994;72:59–68.
    1. Bax ML, Buffiere C, Hafnaoui N, Gaudichon C, Savary-Auzeloux I, Dardevet D, Sante-Lhoutellier V, Remond D. Effects of meat cooking, and of ingested amount, on protein digestion speed and entry of residual proteins into the colon: a study in minipigs. PLoS One. 2013;8:e61252.
    1. Fan MZ, Sauer WC, McBurney MI. Estimation by regression analysis of endogenous amino acid levels in digesta collected from the distal ileum of pigs. J Anim Sci. 1995;73:2319–28.
    1. Deutz NE, Ten Have GA, Soeters PB, Moughan PJ. Increased intestinal amino-acid retention from the addition of carbohydrates to a meal. Clin Nutr. 1995;14:354–64.
    1. Waterlow JC. Protein turnover. Wallingford (England): CABI Publishing; 2006.
    1. Braun A, Vikari A, Windisch W, Auerswald K. Transamination governs nitrogen isotope heterogeneity of amino acids in rats. J Agric Food Chem. 2014;62:8008–13.
    1. Macko SA, Estep MLF, Engel MH, Hare P. Kinetic fractionation of stable nitrogen isotopes during amino acid transamination. Geochim Cosmochim Acta. 1986;50:2143–6.
    1. Jungas RL, Halperin ML, Brosnan JT. Quantitative-analysis of amino-acid oxidation and related gluconeogenesis in humans. Physiol Rev. 1992;72:419–48.
    1. Matthews DE, Bier DM, Rennie MJ, Edwards RH, Halliday D, Millward DJ, Clugston GA. Regulation of leucine metabolism in man: a stable isotope study. Science. 1981;214:1129–31.
    1. Blom HJ, Smulders Y. Overview of homocysteine and folate metabolism: with special references to cardiovascular disease and neural tube defects. J Inherit Metab Dis. 2011;34:75–81.
    1. Boirie Y, Dangin M, Gachon P, Vasson MP, Maubois JL, Beaufrere B. Slow and fast dietary proteins differently modulate postprandial protein accretion. Proc Natl Acad Sci USA. 1997;94:14930–5.
    1. Lacroix M, Leonil J, Bos C, Henry G, Airinei G, Fauquant J, Tome D, Gaudichon C. Heat markers and quality indexes of industrially heat-treated [15N] milk protein measured in rats. J Agric Food Chem. 2006;54:1508–17.

Source: PubMed

Patrocinadores e Colaboradores

Condições médicas

Intervenções de drogas

3
Se inscrever