Determination of the Relationship of Serum Amino Acid Profile with Sex and Body Weight in Healthy Geese by Liquid Chromatography-Tandem Mass Spectrometry

Yavuz, E; Irak, K; Çelik, ÖY; Bolacali, M; Ergiden, Y; Gürgöze, S

doi:10.1590/1806-9061-2021-1569

ABSTRACT

The aim of this study is to determine the serum amino acid profile using Liquid Chromatography-Tandem Mass Spectrometry (LC-MS / MS) in healthy male and female geese of the same age that were raised in similar care and feeding conditions. The animal material of the study consisted of a total of 41 geese, 18 male, and 23 female of the same age (9 months). After a 12h fasting period of the geese, blood samples were taken from V. subcutanaeulnaris into tubes without anticoagulant. After separating the serums, the samples were preserved at -20 ^O C degrees until Methylglutaryl (Met-Glu), Valine (Val), Leucyl-Isoleucine (Leu-Ile), Methionine (Met), Phenylalanine (Phe), Argininosuccinate (ASA), Tyrosine (Tyr), Aspartic acid (Asp), Alanine (Ala), Arginine (Arg), Citrulline (Cit), Glycine (Gly), Ornithine (Orn), Glutamic acid (Glu) were analyzed. The Val, Asp, Arg, Cit, Gly, and Orn levels of male geese were higher compared to female geese in the research (p<0.05). It was determined that Asp, Arg, Cit, and Gly levels increased as the body weights of the geese increased (p<0.05). It was also determined that the effect of Gender x Body Weight interaction on Val, Cit, and Orn levels was significant (p<0.05). As a result; it has been concluded that the serum amino acid profile of healthy geese can vary according to gender and live weight, and more studies are needed to elucidate the reasons for these changes.

Keywords:
Amino Acid Profile; Goose; LC-MS / MS

INTRODUCTION

Protein molecules are polymers of amino acid (AA) residues, linearly linked by peptide bonds. Although there are more than 500 naturally occurring amino acids (AAs) (Wagner & Musso, 1983Wagner I, Musso H. New naturally occurring amino acids. Angewandte Chemie International 1983;22(11):816-28.) only 20 of these are found in plant and animal proteins. These 20 amino acids classified as Proteinogenic amino acids (Wu et al., 2016Wu G, Cross H, Gehring K, Savell J, Arnold A, McNeill S. Composition of free and peptide-bound amino acids in beef chuck, loin, and round cuts. Journal of Animal Science 2016;94(6):2603-13.) are; alanine, arginine, asparagine, aspartic acid, cysteine, glutamic acid, glutamine, glycine, histidine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, serine, threonine, tryptophan, tyrosine, and valine (Lewis, 2001Lewis A. Amino acids in swine nutrition. In: Lewis A, editor. Swine nutrition. Boca Raton: CRC Press; 2001. p.131-50.; NRC, 2012NRC. Proteins and amino acids. Nutrient requirements of swine. Washington: National Academies Press; 2012. v.11, p.15-44.). Beyond being the building blocks for protein synthesis, different AAs have different biochemical functions (Hou & Wu, 2017Hou Y, Wu G. Nutritionally nonessential amino acids:a misnomer in nutritional sciences. Advances in Nutrition 2017;8(1):137-9.).

The skeletal muscle, which is the main reservoir of protein or AAs in the body, is a dynamic tissue. Protein molecules in muscle mass constantly go through a natural intracellular life process called the protein cycle, where old or damaged proteins are broken down and new proteins are synthesized (Wu, 2013Wu G. Amino acids: biochemistry and nutrition. Boca Raton: CRC Press; 2013,; Liao et al., 2015Liao SF, Wang T, Regmi N. Lysine nutrition in swine and the related monogastric animals:muscle protein biosynthesis and beyond. Springer Plus 2015;4(1):147.). Alongside muscle cells, all other living cells in an animal’s body have an intracellular protein cycle. The intracellular fluids must take in and remove free AAs through the extracellular fluids and blood circulation, based on the metabolic state of the cells, for this cycle to continue. Free AAs present in plasma in different concentrations are intermediates of the whole-body protein cycle and nutrient metabolism, and play very important roles during the protein transfer process (Abumrad & Miller, 1983Abumrad NN, Miller B. The physiologic and nutritional significance of plasma - free amino acid levels. Journal of Parenteral and Enteral Nutrition 1983;7(2):163-70.; Liao et al., 2018).

Comparison of reference plasma AA concentrations (at starvation) with current plasma AA concentrations (after feed intake) can provide important information about the bioavailability of dietary AAs (Wu, 2013Wu G. Amino acids: biochemistry and nutrition. Boca Raton: CRC Press; 2013,). The profiles of digestible or bioavailable AAs in a diet, especially for those that cannot be synthesized in animal cells, are the most important factors determining the nutritional value of dietary proteins or the efficiency of dietary protein for metabolic us (Hou et al., 2015Hou Y, Yin Y, Wu G. Dietary essentiality of "nutritionally non-essential amino acids" for animals and humans. Experimental Biology and Medicine 2015;240(8):997-1007.; Hou et al., 2016). Studies have shown that the plasma free amino acid (PFAA) profile can be used as an effective biomarker in the detection of lifestyle-related diseases (Wang et al., 2011Wang TJ, Larson MG, Vasan RS, Cheng S, Rhee EP, McCabe E, et al. Metabolite profiles and the risk of developing diabetes. Nature Medicine 2011;17(4):448-53.; Würtz et al., 2012Würtz P, Mäkinen V-P, Soininen P, Kangas AJ, Tukiainen T, Kettunen J, et al. Metabolic signatures of insulin resistance in 7,098 young adults. Diabetes 2012;61(6):1372-80.; McCormack et al., 2013McCormack SE, Shaham O, McCarthy MA, Deik AA, Wang TJ, Gerszten RE, et al. Circulating branched - chain amino acid concentrations are associated with obesity and future insulin resistance in children and adolescents. Pediatric Obesity 2013;8(1):52-61.; Würtz et al., 2013).

The analysis of amino acids is thought to play an extremely important role in detecting disorders called aminoacidopathies. Today, various analytical methods such as high-performance liquid chromatography (HPLC), gas chromatography (GC), and mass spectrometry (MS) are used for amino acid analysis (Uaariyapanichkul et al., 2018Uaariyapanichkul J, Chomtho S, Suphapeetiporn K, Shotelersuk V, Punnahitananda S, Chinjarernpan P, et al. Age-related reference intervals for blood amino acids in Thai pediatric population measured by liquid chromatography tandem mass spectrometry. Journal of Nutrition and Metabolism 2018;2018.). Using liquid chromatography-tandem mass spectrometry (LC-MS / MS), each sample can be analyzed quickly within 2 minutes. Furthermore, multiple analytes can be tested by using a small amount of blood sample. In this method, the false positive rate is about 0.05%, and the accuracy is more than 90% (Jones & Bennett, 2002Jones PM, Bennett MJ. The changing face of newborn screening:diagnosis of inborn errors of metabolism by tandem mass spectrometry. Clinical Chimica Acta 2002;324(1-2):121-8.; Fingerhut et al., 2014Fingerhut R, Silva Polanco ML, Silva Arevalo GDJ, Swiderska MA. First experience with a fully automated extraction system for simultaneous on - line direct tandem mass spectrometric analysis of amino acids and (acyl - ) carnitines in a newborn screening setting. Rapid Commun Mass Spectrom 2014;28(8):965-73.).

In this study, the aim is to determine the serum amino acid profile using Liquid Chromatography-Tandem Mass Spectrometry in healthy male and female geese of the same age that were raised in similar care and feeding conditions.

MATERIAL AND METHODS

The animal material of the study consisted of a total of 41 geese, 18 male, and 23 female of the same age (9 months). The geese were clinically healthy, had similar care and feeding conditions, and were raised in the Bozova district of Şanlıurfa province (Figure 1). After a 12hfasting period of the geese, blood samples were taken from V. subcutaneaulnaris into tubes without anticoagulant. After separating the serums, the samples were preserved at -20 ºC degrees until Methylglutaryl (Met-Glu), Valine (Val), Leucyl-Isoleucine (Leu-Ile), Methionine (Met), Phenylalanine (Phe), Argininosuccinate (ASA), Tyrosine (Tyr), Aspartic acid (Asp), Alanine (Ala), Arginine (Arg), Citrulline (Cit), Glycine (Gly), Ornithine (Orn), Glutamic acid (Glu) were analyzed.

Ethical Approval

Ethical approval for this study was obtained from the Harran University Local Ethics Committee for Animal Experiments (Decision number: 2020/006/15).

Figure 1
The map of Şanlıurfa province, in which the study was performed.

Tandem Mass Spectrometry

Each sample was extracted by dispensing 300 lL of an extraction solution consisting of a mixture of methanol and an aqueous solution of 3 mmol/L hydrate hydrazine, at approximate relative volume/volume ratios of 66.6 % and 33.3%, respectively. In the extract solution, stable heavy isotope analogues of several amino acids were used for internal standards. Samples obtained from the extract were injected into an LCMS-8040 device (Shimadzu Corporation, Japan). The percentage of each analyte was defined compared to a standard including each analyte. The standard concentrations for amino acids were in the range of 500-2500 lmol/L.

Statistical Analysis

The data were analyzed with a factorial model of the general linear model procedure using SPSS software (SPSS version 23.0; IBM Corp., Armonk, NY, USA). The interaction of live body weight and sex on Met-Glu, Val, Leu-Ile, Met, Phe, ASA, Tyr, Asp, Ala, Arg, Cit, Gly, Orn, and Glu parameters were determined using the PROC GLM procedure.

Y_{i j k} = µ + L B W_{I} + G_{j} + {(L B W \times G)}_{i j} + e_{i j k}

Where: Y_ijk is the response variable (MethylGlutaryl, Val, Leu_Ile, Met, Phe, ASA, Tyr, Asp, Ala, Arg, Cit, Gly, Orn, and Glu); µ is the overall mean common to all observation; LBW_I is the fixed effect of live weight (i = 4); G_j is the fixed effect of gender (j = 2), (LBW × G)_ij is the first-order interaction and e_ijk is the random residual error. Statistical significance was set at p≤0.05. Post hoc tests were performed, using Duncan’s Multiple Range Test.

RESULTS

The serum amino acid profiles of male and female geese with different body weights are given in Table 1. The Val, Asp, Arg, Cit, Gly, and Orn levels of male geese were higher compared to female geese’s in the research (p<0.05). It was determined that Asp, Arg, Cit, and Gly levels increased as the body weights of the geese increased (p<0.05).

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Table 1
Serum amino acid profile in healthy female and male geese.

It was also determined that the effect of Gender x Body Weight interaction on Val, Cit, and Orn levels was significant (p<0.05). Another finding is that the highest value in terms of Val, Cit, and Orn levels was in the male geese group of 3.5 kg and above. The lowest values were determined in the male geese of 2.60-2.89 kg group is for valine, in the female geese of 2.90-3.19 kg group is for Cit, and in the female geese of 3.50 kg and above group is for Orn. It was determined that valine, Cit, and Orn values increased as the bodyweight increased in males (except for the 3.20-3.49kg group), while the increase in body weight in females had fluctuating values.

It was also determined that body weight, sex, and Gender x Body Weight interaction did not affect Leu_Ile, Met, Phe, ASA, Tyr, Ala, and Glu values (p>0.05).

DISCUSSION

Amino acids have different biochemical functions beyond serving as building blocks in protein synthesis (Hou & Wu, 2017Hou Y, Wu G. Nutritionally nonessential amino acids:a misnomer in nutritional sciences. Advances in Nutrition 2017;8(1):137-9.). Protein molecules in muscle mass constantly go through a normal intracellular life process called the protein cycle, old or damaged proteins are broken down and new proteins are synthesized during this process (Wu, 2013; Liao et al., 2015Liao SF, Wang T, Regmi N. Lysine nutrition in swine and the related monogastric animals:muscle protein biosynthesis and beyond. Springer Plus 2015;4(1):147.). Comparison of available plasma AA concentrations (after feed intake) with reference plasma AA concentrations (at fasting) can provide important information about the bioavailability of dietary AAs (Wu, 2013). For this purpose; several studies have been conducted to determine limiting AAs in rats (McLaughlan & Illman, 1967McLaughlan J, Illman W. Use of free plasma amino acid levels for estimating amino acid requirements of the growing rat. The Journal of Nnutrition 1967;93(1):21-4.), pigs (Mitchell et al., 1968Mitchell J, Becker D, Jensen A, Harmon B, Norton H. Determination of amino acid needs of the young pig by nitrogen balance and plasma-free amino acids. Journal of Animal Science 1968;27(5):1327-31.), and poultry (Fernández-Fígares et al., 1997Fernández-Fígares I, Prieto C, Nieto R, Aguilera J. Free amino acid concentrations in plasma, muscle and liver as indirect measures of protein adequacy in growing chickens. Animal Science 1997;64 (3):529-39.) diets, and on the AA requirements of these animals. Profiles of AAs that cannot be synthesized in animal cells are the most important factor determining the nutritional value and efficiency of dietary proteins (Hou et al., 2015; Hou et al., 2016).

Generally; an animal’s plasma AA concentrations increase in proportion to the levels of the respective AAs after dietary intake of a protein-rich feed. For example, there is a linear relationship between dietary level and plasma concentration of AAs such as leucine, isoleucine, or valine (Johnson & Anderson, 1982Johnson D, Anderson G. Prediction of plasma amino acid concentration from diet amino acid content. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology 1982;243(1):R99-R103.). Adibi & Mercer (1973Adibi SA, Mercer DW. Protein digestion in human intestine as reflected in luminal, mucosal, and plasma amino acid concentrations after meals. The Journal of Clinical Investigation 1973;52(7):1586-94.) found that in humans, total free AA concentrations in blood plasma increased significantly after a protein-rich meal. However, these simple correlations are not always correct, and the plasma concentrations of most AAs are not linearly related to dietary intakes. The relationship between plasma and dietary AA concentrations may be influenced by interactions or antagonism between structurally related AAs competing for intestinal absorption (Matthews, 2000Matthews J. Amino acid and peptide transport systems. In: D'Mello J, editor. Farm animal metabolism and nutrition. Wallingford: CAB International; 2000. p.3-23.). Liu et al. (2019Liu SY, Naranjo VD, Chrystal PV, Buyse J, Selle PH. Box-Behnken optimisation of growth performance, plasma metabolites and carcass traits as influenced by dietary energy, amino acid and starch to lipid ratios in broiler chickens. PLoS One 2019;14(3):1-19.) reported that body weight gain of modern broilers is more sensitive to amino acid concentrations.

Davey et al. (1973Davey R, Phelps J, Thomas C. Plasma free amino acids of swine as influenced by diet protein level, animal age and time of sampling. Journal of Animal Science 1973;37(1):81-6.) performed a study in pigs to determine the effect of dietary protein level, animal age, and sampling time on plasma concentrations of baseline amino acids. Their results showed that the concentrations of valine, isoleucine and leucine in the plasma of pigs fed a 20% crude protein diet were significantly higher than those fed a 13% crude protein diet, while the opposite was found for threonine. No difference was found for methionine, phenylalanine, lysine, histidine, arginine.

Gender is an important determinant of body composition and energy expenditure in humans. Protein oxidation has been reported to be lower in women than in men in the basal postprandial state (Volpi et al., 1998Volpi E, Lucidi P, Bolli GB, Santeusanio F, De Feo P. Gender differences in basal protein kinetics in young adults. The Journal of Clinical Endocrinology & Metabolism 1998;83(12):4363-4367.). The gender differences in protein metabolism are of great interest since Gonadotropic hormones (Follicle-stimulating hormone-FSH and Luteinizing hormone-LH) are known to affect metabolism (Jensen et al., 1994Jensen MD, Martin ML, Cryer PE, Roust LR. Effects of estrogen on free fatty acid metabolism in humans. American Journal of Physiology-Endocrinology And Metabolism 1994;266(6):E914-E920.). Bancel et al. (1994Bancel E, Strubel D, Bellet H, Polge A, Peray P. Effet de l'âge et du sexe sur les concentrations des acides aminés plasmatiques. Annale de Biologie Clinique 1994;52:667-70.) showed that plasma concentrations of valine, leucine, isoleucine, proline, glutamine, glutamate, and phenylalanine are higher in men.

In this study, serum Val, Asp, Arg, Cit, Gly, and Orn levels of male geese were higher than females’. This can be explained by gender-related differences in protein metabolism. In a study investigating serum amino acid concentrations in aging men and women, men have been reported to have higher concentrations of essential amino acids and branched-chain amino acids compared to women (Pitkänen et al., 2003Pitkänen H, Oja S, Kemppainen K, Seppä J, Mero A. Serum amino acid concentrations in aging men and women. Amino Acids 2003;24(4):413-21.).

Bancel et al. (1994Bancel E, Strubel D, Bellet H, Polge A, Peray P. Effet de l'âge et du sexe sur les concentrations des acides aminés plasmatiques. Annale de Biologie Clinique 1994;52:667-70.) reported that concentrations of total plasma amino acids, citrulline, cysteine, histidine, glutamine, glutamate, lysine, ornithine, and phenylalanine, were higher in the blood plasma of elderly individuals (80-100 years) than younger adults (20 -25 years). Pitkänen et al. (2003Pitkänen H, Oja S, Kemppainen K, Seppä J, Mero A. Serum amino acid concentrations in aging men and women. Amino Acids 2003;24(4):413-21.) reported that significant interactions between sex and age were observed in 7 of 22 single amino acids.

It was also determined that the effect of Gender x Body Weight interaction on Val, Cit, and Orn levels was significant (p<0.05). The small intestine is the main source of circulating citrulline, which is synthesized from proline and then converted to arginine (Dillon et al., 1999Dillon EL, Knabe DA, Wu G. Lactate inhibits citrulline and arginine synthesis from proline in pig enterocytes. American Journal of Physiology-Gastrointestinal and Liver Physiology 1999;276(5):G1079-G1086.). In addition, citrulline has a role in the formation of urea (Di Pasquale, 1997Di Pasquale M. Amino acids and proteins for the athlete. Boca Raton: CRC Press; 1997.).

As a result; it has been concluded that the serum amino acid profile of healthy geese can vary according to gender and live weight, and more studies are needed to elucidate the reasons for these changes.

REFERENCES

Abumrad NN, Miller B. The physiologic and nutritional significance of plasma - free amino acid levels. Journal of Parenteral and Enteral Nutrition 1983;7(2):163-70.
Adibi SA, Mercer DW. Protein digestion in human intestine as reflected in luminal, mucosal, and plasma amino acid concentrations after meals. The Journal of Clinical Investigation 1973;52(7):1586-94.
Bancel E, Strubel D, Bellet H, Polge A, Peray P. Effet de l'âge et du sexe sur les concentrations des acides aminés plasmatiques. Annale de Biologie Clinique 1994;52:667-70.
Davey R, Phelps J, Thomas C. Plasma free amino acids of swine as influenced by diet protein level, animal age and time of sampling. Journal of Animal Science 1973;37(1):81-6.
Di Pasquale M. Amino acids and proteins for the athlete. Boca Raton: CRC Press; 1997.
Dillon EL, Knabe DA, Wu G. Lactate inhibits citrulline and arginine synthesis from proline in pig enterocytes. American Journal of Physiology-Gastrointestinal and Liver Physiology 1999;276(5):G1079-G1086.
Fernández-Fígares I, Prieto C, Nieto R, Aguilera J. Free amino acid concentrations in plasma, muscle and liver as indirect measures of protein adequacy in growing chickens. Animal Science 1997;64 (3):529-39.
Fingerhut R, Silva Polanco ML, Silva Arevalo GDJ, Swiderska MA. First experience with a fully automated extraction system for simultaneous on - line direct tandem mass spectrometric analysis of amino acids and (acyl - ) carnitines in a newborn screening setting. Rapid Commun Mass Spectrom 2014;28(8):965-73.
Hou Y, Wu G. Nutritionally nonessential amino acids:a misnomer in nutritional sciences. Advances in Nutrition 2017;8(1):137-9.
Hou Y, Yao K, Yin Y, Wu G. Endogenous synthesis of amino acids limits growth, lactation, and reproduction in animals. Advances in Nutrition 2016;7(2):331-42.
Hou Y, Yin Y, Wu G. Dietary essentiality of "nutritionally non-essential amino acids" for animals and humans. Experimental Biology and Medicine 2015;240(8):997-1007.
Jensen MD, Martin ML, Cryer PE, Roust LR. Effects of estrogen on free fatty acid metabolism in humans. American Journal of Physiology-Endocrinology And Metabolism 1994;266(6):E914-E920.
Johnson D, Anderson G. Prediction of plasma amino acid concentration from diet amino acid content. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology 1982;243(1):R99-R103.
Jones PM, Bennett MJ. The changing face of newborn screening:diagnosis of inborn errors of metabolism by tandem mass spectrometry. Clinical Chimica Acta 2002;324(1-2):121-8.
Lewis A. Amino acids in swine nutrition. In: Lewis A, editor. Swine nutrition. Boca Raton: CRC Press; 2001. p.131-50.
Liao SF, Regmi N, Wu G. Homeostatic regulation of plasma amino acid concentrations. Front Biosci 2018;23:640-655.
Liao SF, Wang T, Regmi N. Lysine nutrition in swine and the related monogastric animals:muscle protein biosynthesis and beyond. Springer Plus 2015;4(1):147.
Liu SY, Naranjo VD, Chrystal PV, Buyse J, Selle PH. Box-Behnken optimisation of growth performance, plasma metabolites and carcass traits as influenced by dietary energy, amino acid and starch to lipid ratios in broiler chickens. PLoS One 2019;14(3):1-19.
Matthews J. Amino acid and peptide transport systems. In: D'Mello J, editor. Farm animal metabolism and nutrition. Wallingford: CAB International; 2000. p.3-23.
McCormack SE, Shaham O, McCarthy MA, Deik AA, Wang TJ, Gerszten RE, et al. Circulating branched - chain amino acid concentrations are associated with obesity and future insulin resistance in children and adolescents. Pediatric Obesity 2013;8(1):52-61.
McLaughlan J, Illman W. Use of free plasma amino acid levels for estimating amino acid requirements of the growing rat. The Journal of Nnutrition 1967;93(1):21-4.
Mitchell J, Becker D, Jensen A, Harmon B, Norton H. Determination of amino acid needs of the young pig by nitrogen balance and plasma-free amino acids. Journal of Animal Science 1968;27(5):1327-31.
NRC. Proteins and amino acids. Nutrient requirements of swine. Washington: National Academies Press; 2012. v.11, p.15-44.
Pitkänen H, Oja S, Kemppainen K, Seppä J, Mero A. Serum amino acid concentrations in aging men and women. Amino Acids 2003;24(4):413-21.
Uaariyapanichkul J, Chomtho S, Suphapeetiporn K, Shotelersuk V, Punnahitananda S, Chinjarernpan P, et al. Age-related reference intervals for blood amino acids in Thai pediatric population measured by liquid chromatography tandem mass spectrometry. Journal of Nutrition and Metabolism 2018;2018.
Volpi E, Lucidi P, Bolli GB, Santeusanio F, De Feo P. Gender differences in basal protein kinetics in young adults. The Journal of Clinical Endocrinology & Metabolism 1998;83(12):4363-4367.
Wagner I, Musso H. New naturally occurring amino acids. Angewandte Chemie International 1983;22(11):816-28.
Wang TJ, Larson MG, Vasan RS, Cheng S, Rhee EP, McCabe E, et al. Metabolite profiles and the risk of developing diabetes. Nature Medicine 2011;17(4):448-53.
Wu G. Amino acids: biochemistry and nutrition. Boca Raton: CRC Press; 2013,
Wu G, Cross H, Gehring K, Savell J, Arnold A, McNeill S. Composition of free and peptide-bound amino acids in beef chuck, loin, and round cuts. Journal of Animal Science 2016;94(6):2603-13.
Würtz P, Mäkinen V-P, Soininen P, Kangas AJ, Tukiainen T, Kettunen J, et al. Metabolic signatures of insulin resistance in 7,098 young adults. Diabetes 2012;61(6):1372-80.
Würtz P, Soininen P, Kangas AJ, Rönnemaa T, Lehtimäki T, Kähönen M, et al. Branched-chain and aromatic amino acids are predictors of insulin resistance in young adults. Diabetes Care 2013;36(3):648-55.

Publication Dates

Publication in this collection
08 Aug 2022
Date of issue
2022

History

Received
15 Nov 2021
Accepted
13 Apr 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abumrad NN, Miller B. The physiologic and nutritional significance of plasma - free amino acid levels. Journal of Parenteral and Enteral Nutrition 1983;7(2):163-70.

[2] Adibi SA, Mercer DW. Protein digestion in human intestine as reflected in luminal, mucosal, and plasma amino acid concentrations after meals. The Journal of Clinical Investigation 1973;52(7):1586-94.

[3] Bancel E, Strubel D, Bellet H, Polge A, Peray P. Effet de l'âge et du sexe sur les concentrations des acides aminés plasmatiques. Annale de Biologie Clinique 1994;52:667-70.

[4] Davey R, Phelps J, Thomas C. Plasma free amino acids of swine as influenced by diet protein level, animal age and time of sampling. Journal of Animal Science 1973;37(1):81-6.

[5] Di Pasquale M. Amino acids and proteins for the athlete. Boca Raton: CRC Press; 1997.

[6] Dillon EL, Knabe DA, Wu G. Lactate inhibits citrulline and arginine synthesis from proline in pig enterocytes. American Journal of Physiology-Gastrointestinal and Liver Physiology 1999;276(5):G1079-G1086.

[7] Fernández-Fígares I, Prieto C, Nieto R, Aguilera J. Free amino acid concentrations in plasma, muscle and liver as indirect measures of protein adequacy in growing chickens. Animal Science 1997;64 (3):529-39.

[8] Fingerhut R, Silva Polanco ML, Silva Arevalo GDJ, Swiderska MA. First experience with a fully automated extraction system for simultaneous on - line direct tandem mass spectrometric analysis of amino acids and (acyl - ) carnitines in a newborn screening setting. Rapid Commun Mass Spectrom 2014;28(8):965-73.

[9] Hou Y, Wu G. Nutritionally nonessential amino acids:a misnomer in nutritional sciences. Advances in Nutrition 2017;8(1):137-9.

[10] Hou Y, Yao K, Yin Y, Wu G. Endogenous synthesis of amino acids limits growth, lactation, and reproduction in animals. Advances in Nutrition 2016;7(2):331-42.

[11] Hou Y, Yin Y, Wu G. Dietary essentiality of "nutritionally non-essential amino acids" for animals and humans. Experimental Biology and Medicine 2015;240(8):997-1007.

[12] Jensen MD, Martin ML, Cryer PE, Roust LR. Effects of estrogen on free fatty acid metabolism in humans. American Journal of Physiology-Endocrinology And Metabolism 1994;266(6):E914-E920.

[13] Johnson D, Anderson G. Prediction of plasma amino acid concentration from diet amino acid content. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology 1982;243(1):R99-R103.

[14] Jones PM, Bennett MJ. The changing face of newborn screening:diagnosis of inborn errors of metabolism by tandem mass spectrometry. Clinical Chimica Acta 2002;324(1-2):121-8.

[15] Lewis A. Amino acids in swine nutrition. In: Lewis A, editor. Swine nutrition. Boca Raton: CRC Press; 2001. p.131-50.

[16] Liao SF, Regmi N, Wu G. Homeostatic regulation of plasma amino acid concentrations. Front Biosci 2018;23:640-655.

[17] Liao SF, Wang T, Regmi N. Lysine nutrition in swine and the related monogastric animals:muscle protein biosynthesis and beyond. Springer Plus 2015;4(1):147.

[18] Liu SY, Naranjo VD, Chrystal PV, Buyse J, Selle PH. Box-Behnken optimisation of growth performance, plasma metabolites and carcass traits as influenced by dietary energy, amino acid and starch to lipid ratios in broiler chickens. PLoS One 2019;14(3):1-19.

[19] Matthews J. Amino acid and peptide transport systems. In: D'Mello J, editor. Farm animal metabolism and nutrition. Wallingford: CAB International; 2000. p.3-23.

[20] McCormack SE, Shaham O, McCarthy MA, Deik AA, Wang TJ, Gerszten RE, et al. Circulating branched - chain amino acid concentrations are associated with obesity and future insulin resistance in children and adolescents. Pediatric Obesity 2013;8(1):52-61.

[21] McLaughlan J, Illman W. Use of free plasma amino acid levels for estimating amino acid requirements of the growing rat. The Journal of Nnutrition 1967;93(1):21-4.

[22] Mitchell J, Becker D, Jensen A, Harmon B, Norton H. Determination of amino acid needs of the young pig by nitrogen balance and plasma-free amino acids. Journal of Animal Science 1968;27(5):1327-31.

[23] NRC. Proteins and amino acids. Nutrient requirements of swine. Washington: National Academies Press; 2012. v.11, p.15-44.

[24] Pitkänen H, Oja S, Kemppainen K, Seppä J, Mero A. Serum amino acid concentrations in aging men and women. Amino Acids 2003;24(4):413-21.

[25] Uaariyapanichkul J, Chomtho S, Suphapeetiporn K, Shotelersuk V, Punnahitananda S, Chinjarernpan P, et al. Age-related reference intervals for blood amino acids in Thai pediatric population measured by liquid chromatography tandem mass spectrometry. Journal of Nutrition and Metabolism 2018;2018.

[26] Volpi E, Lucidi P, Bolli GB, Santeusanio F, De Feo P. Gender differences in basal protein kinetics in young adults. The Journal of Clinical Endocrinology & Metabolism 1998;83(12):4363-4367.

[27] Wagner I, Musso H. New naturally occurring amino acids. Angewandte Chemie International 1983;22(11):816-28.

[28] Wang TJ, Larson MG, Vasan RS, Cheng S, Rhee EP, McCabe E, et al. Metabolite profiles and the risk of developing diabetes. Nature Medicine 2011;17(4):448-53.

[29] Wu G. Amino acids: biochemistry and nutrition. Boca Raton: CRC Press; 2013,

[30] Wu G, Cross H, Gehring K, Savell J, Arnold A, McNeill S. Composition of free and peptide-bound amino acids in beef chuck, loin, and round cuts. Journal of Animal Science 2016;94(6):2603-13.

[31] Würtz P, Mäkinen V-P, Soininen P, Kangas AJ, Tukiainen T, Kettunen J, et al. Metabolic signatures of insulin resistance in 7,098 young adults. Diabetes 2012;61(6):1372-80.

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Group	Live Weight	MethylGlutaryl	Val	Leu_Ile	Met	Phe	ASA	Tyr	Asp	Ala	Arg	Cit	Gly	Orn	Glu
Female	2.60-2.89 kg	0.026	688.046^b	594.058	99.524	240.167	0.134	350.888	53.586	856.876	584.850	20.615^b	516.589	71.148^b	377.949
	2.90-3.19 kg	0.036	543.255^b	520.050	83.183	212.190	0.123	338.138	57.357	886.922	556.889	18.713^b	455.339	73.812^b	403.390
	3.20-3.49 kg	0.024	739.939^b	644.409	106.171	252.574	0.151	436.404	89.408	912.831	742.523	32.319^b	583.513	92.775^b	491.425
	3.50 and up	0.032	567.142^b	449.197	103.673	226.322	0.223	302.849	78.005	1139.163	663.458	28.710^b	539.705	55.349^b	461.349
Male	2.60-2.89 kg	0.029	538.893^b	459.221	80.570	190.552	0.167	250.794	61.872	833.117	471.728	19.419^b	432.047	60.371^b	360.998
	2.90-3.19 kg	0.022	879.632^ab	767.354	114.217	238.584	0.246	361.950	105.728	1119.585	878.893	36.087^b	677.651	127.601^b	578.488
	3.20-3.49 kg	0.029	864.675^ab	700.142	111.921	260.440	0.214	403.945	100.093	1087.599	814.880	29.300^b	673.005	97.636^b	476.669
	3.50 and up	0.022	1215.308^a	828.127	170.642	382.404	0.280	548.537	170.278	1190.852	1384.971	71.233^a	1099.938	239.608^a	633.131
SEM		0.009	133.027	95.801	15.947	40.755	0.063	66.827	22.230	155.074	149.058	7.252	107.736	29.672	82.267
Live Weight
2.60-2.89 kg		0.027	613.470	526.639	90.047	215.360	0.150	300.841	57.729^b	844.997	528.289^b	20.017^b	474.318^b	65.760	369.473
2.90-3.19 kg		0.029	711.443	643.702	98.700	225.387	0.185	350.044	81.542^ab	1003.253	717.891^ab	27.400^b	566.495^b	100.707	490.939
3.20-3.49 kg		0.026	802.307	672.275	109.046	256.507	0.183	420.175	94.751^ab	1000.215	778.702^ab	30.810^b	628.259^ab	95.206	484.047
3.50 and up		0.027	891.225	638.662	137.158	304.363	0.251	425.693	124.141^a	1165.007	1024.215^a	49.971^a	819.821^a	147.479	547.240
SEM		0.006	94.064	67.742	11.276	28.818	0.045	47.253	15.719	109.654	105.400	5.128	76.181	20.981	58.171
Gender
Female		0.029	634.595	551.928	98.137	232.813	0.158	357.070	69.589	948.948	636.930	25.089	523.787	73.271	433.528
Male		0.025	874.627	688.711	119.338	267.995	0.227	391.306	109.493	1057.788	887.618	39.010	720.660	131.304	512.321
SEM		0.005	68.098	49.041	8.164	20.863	0.032	34.209	11.380	79.384	76.304	3.712	55.151	15.189	42.113
Source of Variation
Gender		0.556	0.020	0.060	0.079	0.245	0.145	0.486	0.021	0.342	0.029	0.014	0.019	0.012	0.198
Live Weight		0.988	0.188	0.275	0.069	0.216	0.537	0.134	0.048	0.266	0.028	0.008	0.042	0.104	0.151
Gender * Live Weight		0.646	0.048	0.062	0.091	0.163	0.897	0.144	0.302	0.789	0.081	0.034	0.064	0.035	0.469

Brasil