The Determination of Nutritional Requirements in Rats: Mathematical Modeling of Sigmoidal, Inhibited Nutrient-Response Curves

Mercer, L. Preston; May, Hubert E.; Dodds, Steven J.

doi:10.1093/jn/119.10.1465

Cited by 59 publications

(37 citation statements)

References 10 publications

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“…There is the need to determine the basic principles which underlie the de®nition of the upper limit of intake of protein or amino acids which can be metabolised effectively without adverse effect and how this might translate into patterns of food consumption. What is clear from the studies in humans is that we have only a rudimentary understanding of the nature of the dose response to variations in dietary protein or amino acids, from one situation to another, as needed to model the kind of mathematical analysis developed by Mercer (Mercer et al, 1989). In order to achieve their objective, to characterise a dose response curve, which identi®es levels that map to threshold, de®cient, adequate, optimal, and toxic levels of intake, there is the need for a limited range of outcome measures, which characterise desirable function.…”

Section: The Metabolic Demand For Amino Acids and Nitrogenmentioning

confidence: 99%

Limits of adaptation to high dietary protein intakes

1999

Eur J Clin Nutr

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Ingested protein is made available to the body following digestion and absorption as amino acids and contributes to the body's demand for amino acids for protein synthesis and other metabolic pathways. As the pattern of amino acids required for metabolism is substantially different from that ingested, extensive metabolic interchange serves to improve the match. As a matter of course oxidation of amino acids contributes to satisfying the energy needs of the body. Amino acids in excess of immediate requirements follow degradative pathways and if the capacity of these pathways is exceeded adverse consequences ensue. In pathological states, such as inborn errors of metabolism, there is an obvious constraint on metabolic¯ow with serious sequelae. Pathways may be constrained to a lesser extent due to genetic polymorphisms, metabolic programming, limitation of cofactors or lack of associated substrates. Any of these can result in metabolic derangements, which do not manifest as overt disease, but limit normal function. There is the need to determine the dose response to increases in dietary protein and amino acid availability, using critical metabolic intermediates as outcome indices in order to clarify the upper limit of intake with which the body can cope under a range of physiological and pathological states.

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Section: The Metabolic Demand For Amino Acids and Nitrogenmentioning

confidence: 99%

Limits of adaptation to high dietary protein intakes

1999

Eur J Clin Nutr

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“…Although it is difficult to precisely define the term 'requirement' (Mercer et al, 1989), for growing animals it is usually defined as the minimum supply of an AA that maximizes growth. For monogastric animals, AA requirements are often expressed based on the concept of ideal protein.…”

Section: Introductionmentioning

confidence: 99%

Estimation of the tryptophan requirement in piglets by meta-analysis

Simongiovanni¹,

Corrent²,

Floc'H

et al. 2012

Animal

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There is no consensus concerning the Trp requirement for piglets expressed relative to Lys on a standardized ileal digestible basis (SID Trp : Lys). A meta-analysis was performed to estimate the SID Trp : Lys ratio that maximizes performance of weaned piglets between 7 and 25 kg of BW. A database comprising 130 experiments on the Trp requirement in piglets was established. The nutritional values of the diets were calculated from the composition of feed ingredients. Among all experiments, 37 experiments were selected to be used in the meta-analysis because they were designed to express the Trp requirement relative to Lys (e.g. Lys was the second-limiting amino acid in the diet) while testing at least three levels of Trp. The linear-plateau (LP), curvilinear-plateau (CLP) and asymptotic (ASY) models were tested to estimate the SID Trp : Lys requirement using average daily gain (ADG), average daily feed intake (ADFI) and gain-to-feed ratio (G : F) as response criteria. A multiplicative trial effect was included in the models on the plateau value, assuming that the experimental conditions affected only this parameter and not the requirement or the shape of the response to Trp. Model choice appeared to have an important impact on the estimated requirement. Using ADG and ADFI as response criteria, the SID Trp : Lys requirement was estimated at 17% with the LP model, at 22% with the CLP model and at 26% with the ASY model. Requirement estimates were slightly lower when G : F was used as response criterion. The Trp requirement was not affected by the composition of the diet (corn v. a mixture of cereals). The CLP model appeared to be the best-adapted model to describe the response curve of a population. This model predicted that increasing the SID Trp : Lys ratio from 17% to 22% resulted in an increase in ADG by 8%.

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“…Firstly, the one-slope break-point (broken-line model) analysis used by Coloso et al (1999) to estimate the requirement may have been inappropriate, resulting in underestimation of the requirement. Non-linear models, such as the four-and five-parameter saturation kinetics models, derived from the Michaelis-Menten model for enzyme-catalyzed reaction velocity (Michaelis and Menten, 1913) and developed and described by Mercer and others in a series of reports (Mercer et al, 1975;Mercer, 1980;Mercer et al, 1986;Mercer et al, 1989), are considered to be more accurate representations of biological responses compared with those which "force responses to conform to straight lines" (Pesti et al, 2009). …”

Section: Discussionmentioning

confidence: 99%

“…Broken line spline with ascending linear segment model (Robbins, 1986) Broken line spline with ascending quadratic segment model (Vedenov and Pesti, 2008) 4-Parameter Saturation Kinetics Model (Morgan et al, 1975) 5-Parameter Saturation Kinetics Model adapted from Mercer et al (1989) Three-parameter logistic model (SAS Institute Inc, 1990) Four-parameter logistic model (Gahl et al, 1991) Sigmoidal model (Robbins et al, 1979) Exponential model (Robbins et al, 1979) Compartmental model (Pesti et al, 2009) A C C E P T E D M A N U S C R I P T TSAA; 1.8-2.3% CP Met + 1.1% CP Cys).  Cystine can constitute at least 40% of the TSAA content of the diet of barramundi without significantly affecting growth.…”

Section: A C C E P T E Dmentioning

confidence: 99%

Redefining the requirement for total sulfur amino acids in the diet of barramundi (Lates calcarifer) including assessment of the cystine replacement value

2017

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This study was designed to confirm a previous estimate of the methionine (Met) and total sulfur amino acid (TSAA) requirement of juvenile barramundi (Lates calcarifer) (Coloso et al., 1999) with a view for further study. Triplicate groups of fish (initial weight:18.3g ± 1.5g) were fed diets with graded levels of dietary Met (7.2 -12.8g kg -1 DM), centred around a previously reported requirement, and a constant dietary cystine (Cys) inclusion

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The Determination of Nutritional Requirements in Rats: Mathematical Modeling of Sigmoidal, Inhibited Nutrient-Response Curves

Cited by 59 publications

References 10 publications

Limits of adaptation to high dietary protein intakes

Limits of adaptation to high dietary protein intakes

Estimation of the tryptophan requirement in piglets by meta-analysis

Redefining the requirement for total sulfur amino acids in the diet of barramundi (Lates calcarifer) including assessment of the cystine replacement value

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