Net Postprandial Utilization of [15N]-Labeled Milk Protein Nitrogen Is Influenced by Diet Composition in Humans

Gaudichon, Claire; Mahé, Sylvain; Bénamouzig, Robert; Luengo, Catherine; Fouillet, Hélène; Daré, Sophie; Oycke, Marc Van; Ferrière, Françoise; Rautureau, J; Tomé, Daniel

doi:10.1093/jn/129.4.890

Cited by 108 publications

(80 citation statements)

References 28 publications

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“…Carbohydrates are known to reduce amino acid catabolism during the postprandial phase, both directly and through their insulin-releasing effect. In a previous study with 15 N-labeled milk protein, we showed that glucose diverts some dietary nitrogen from postprandial deamination (9). There are many reasons dietary and endogenous amino acids, which follow different routes and metabolic kinetics, may not be similarly affected by the addition of carbohydrates.…”

Section: Introductionmentioning

confidence: 89%

“…Breath samples were collected every 30 min and stored until later determination of 13 CO 2 isotopic enrichment. Urine was collected over a 29-h period (0-2, 2-4, 4-6, 6-8, [8][9][10][11][12][12][13][14][15][16][17][18][19][20], and 20-29 h after meal ingestion), treated with thymol crystals and liquid paraffin as preservatives, and stored at 4 ЊC until analyzed.…”

Section: Clinical Protocolmentioning

confidence: 99%

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Postprandial modulation of dietary and whole-body nitrogen utilization by carbohydrates in humans

Mariotti

Mahé

Luengo

et al. 2000

The American Journal of Clinical Nutrition

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Background: Sucrose exerts a sparing effect on whole-body protein metabolism, mainly during the absorptive phase. Objective: We aimed to characterize the acute postprandial effect of addition of sucrose on deamination of dietary and endogenous nitrogen, with particular consideration being given to the effects of bioavailability. Design: Twenty-one subjects equipped with ileal tubes ingested 15 N-labeled soy protein combined with [13 C]glycine, with (n = 10) or without (n = 11) sucrose. Dietary and endogenous ileal flow of nitrogen were determined from the ileal effluents. The kinetics of dietary amino acid transfer to the blood were characterized by 13 CO 2 enrichment in breath and 15 N enrichment in plasma amino acids. Deamination of dietary and endogenous amino acid was determined from body urea, urinary nitrogen, and 15 N enrichment. Results:13 CO 2 recovery in breath and 15 N plasma amino acid enrichments were highly correlated (R 2 ≥ 0.95, P < 0.001, for both meals) and markedly delayed by sucrose (half-13 CO 2 recovery: 274 min compared with 167 min), whereas exogenous and endogenous ileal nitrogen kinetics and balances remained unchanged. Addition of sucrose halved the early (0-2 h) deamination peak of dietary nitrogen and reduced endogenous nitrogen oxidation over the first 4 h. Both were reduced by 18-24% over the 8-h period after the meal. Conclusions: Without changing the nitrogen absorptive balance, sucrose markedly affected the bioavailability profile, which is governed by gastric emptying. Endogenous and dietary nitrogen were not spared in the same way and over the same periods, showing that the metabolism of endogenous and dietary nitrogen may be affected differently by nutritional modulation, even if the effects are of a similar magnitude over the entire postprandial period.Am J Clin Nutr 2000;72:954-62.

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Section: Introductionmentioning

confidence: 89%

Section: Clinical Protocolmentioning

confidence: 99%

Postprandial modulation of dietary and whole-body nitrogen utilization by carbohydrates in humans

Mariotti

Mahé

Luengo

et al. 2000

The American Journal of Clinical Nutrition

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“…Although the digestion of alimentary protein is very efficient, approximately 90% efficiency, some nitrogenous material originating from non-digested proteins are transferred from the small intestine to the large intestine [7] and are degraded by the microbiota and by residual pancreatic enzymes to produce numeral metabolites and gases. These gases, especially, can be beneficial or deleterious for the intestinal epithelium in a concentrationdependent way [8,9].…”

Section: Introductionmentioning

confidence: 99%

Colon epithelial cells luminal environment and physiopathological consequences: impact of nutrition and exercise

Blachier

Resende

Leite

et al. 2018

Nutrire

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The colonic epithelial cells represent a border between the colon luminal content, containing notably bacteria and a complex mixture of compounds, and the "milieu interieur" as defined by the French physiologist Claude Bernard. The physical-chemical composition of the luminal content, including luminal pH and bacterial metabolite, that obviously is not constant, is modified for instance according to the diet. Data obtained recently indicate that physical exercise may also modify the colonic luminal content. Evidence has indicated that modification of the luminal content characteristics has, indeed, consequences for the colonic epithelial cells, notably in terms of energy metabolism and DNA integrity. Although such alterations impact presumably the homeostatic process of the colonic epithelium renewal and the epithelial barrier function, their contribution to pathological processes like mucosal inflammation, pre-neoplasia, and neoplasia remains partly elusive. Open questions remain regarding the individual and collective roles of luminal changes, particularly in a long-term perspective. These questions are related particularly to the capacity of the bacterial metabolites to cross the mucus layer before entering the colonocytes, to the concentrations of metabolites in proximity of the colonic crypt stem cells, and to the capacity of colonocytes to detoxicate deleterious compounds, to take up and utilize beneficial compounds.

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“…However, these studies are generally conducted at steady state for practical reasons (i.e., during the fasting period when no proteins are administered or in an artificial fed state, where steady-state is achieved through the constant intragastric administration of a meal). Only a few studies have been conducted under physiological conditions in the fed state (i.e., the meal being ingested as a bolus) and have thus provided a valuable insight into the dynamic and adaptative features of protein metabolism [6,20,21].…”

Section: Introductionmentioning

confidence: 99%

Development and calibration of a modeling tool for the analysis of clinical data in human nutrition

et al. 2005

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Abstract. This paper addresses the problem of calibrating a compartmental model which describes the postprandial distribution of dietary nitrogen in humans after the ingestion of a protein meal. This type of problem (i.e., a classic inverse problem) requires optimization of an objective function that measures the goodness-of-fit of the model predictions to a given set of experimental data. In our particular case, traditional local, gradient-based optimization methods have failed to arrive at satisfactory solutions of the inverse problem because of the large number of parameters to be estimated, the high non-linearity of the objective function and the few experimental data accessible in humans. To overcome these limitations, we have developed a calibration method that uses all available information on the system behavior so as to divide the large inverse problem into many smaller sub-problems, on which a variant of the Nelder-Mead (NM) simplex search procedure was proven to be successful. This calibration method makes it possible to obtain solutions that are close to the optimal values of most of the model parameters, even when noisy experimental data are introduced in the objective function. Using these estimated parameters, it is now possible to correctly simulate the temporal evolution of all compartments of the physiological model, which constitutes a useful, explanatory tool to describe the different dynamic processes involved in the metabolic utilization of dietary proteins in humans.Résumé. Nous abordons ici le problème de l'estimation des paramètres d'un modèle compartimental qui décrit la distribution postprandiale de l'azote alimentaire chez l'homme après l'ingestion d'un repas protéique. Un tel problème (i.e., un problème inverse classique) nécessite l'optimisation d'une fonctionnelle de coût mesurant la qualité de l'ajustement des prédictions du modèleà un jeu de données expérimentales. Dans notre cas particulier, les techniques classiques d'optimisation locale par méthodes de gradient s'avèrent incapables de trouver une solution satisfaisante au problème inverse, en raison du grand nombre de paramètresà estimer, de la forte non-linéarité de la fonctionnelle de coût et du peu de données expérimentales accessibles chez l'homme. Dans ce contexte, notre stratégie a consistéà développer une méthode de calibration qui utilise le maximum d'information disponible sur le comportement du système, de manièreà diviser le problème inverse de grande taille en plusieurs sous-problèmes de taille plus réduite, pour lesquels une variante de la méthode du simplexe de NelderMead (NM) s'avère efficace. Cette méthode de calibration permet d'obtenir des valeurs proches des valeurs optimales pour la plupart des paramètres du modèle, que les données expérimentales injectées dans la fonction objectif soient bruitées ou non. A partir des valeurs de paramètres ainsi estimées, il est désormais possible de simuler de manière satisfaisante l'évolution temporelle de tous les compartiments du modèle physiologique, lequel constitue u...

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Net Postprandial Utilization of [15N]-Labeled Milk Protein Nitrogen Is Influenced by Diet Composition in Humans

Cited by 108 publications

References 28 publications

Postprandial modulation of dietary and whole-body nitrogen utilization by carbohydrates in humans

Postprandial modulation of dietary and whole-body nitrogen utilization by carbohydrates in humans

Colon epithelial cells luminal environment and physiopathological consequences: impact of nutrition and exercise

Development and calibration of a modeling tool for the analysis of clinical data in human nutrition

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