Alternative procedure for determining lysine maintenance requirement in poultry

Dorigam, Juliano Cesar de Paula; Silva, Edney Pereira da; Sakomura, Nilva Kazue; Peruzzi, Nelson José; Lima, Michele Bernardino de; Fernandes, João Batista Kochenborger

doi:10.37496/rbz4920180183

ABSTRACT

The objective with this study was to determine the lysine maintenance requirements (LMR) of male and female broilers as animal models. A total of 252 birds were used for nitrogen balance trials during three periods (I: 6-21, II: 22-37, and III: 38-53 days). Six lysine levels were used (2.76, 5.88, 8.99, 12.1, 15.2, and 18.3 g kg⁻¹) with six replications. A control group also included, totalizing seven treatments for males and females for each assay. The experimental period was 15 days. The response variables included nitrogen intake (NI) and excretion (NEX), and their difference was assumed to be deposited as nitrogen. An exponential regression between NEX and lysine intake (LI) was fitted, and LMR was estimated when LI = 0. The daily values for LMR were 9.29, 33.4, and 40.2 mg BW^0.67 kg⁻¹ for males and 9.36, 30.0, and 39.4 mg BW^0.67 kg⁻¹ for females. The final value for both sexes were 10.1 (period I), 31.5 (period II), and 39.8 mg BW^0.67 kg⁻¹ (period III). Expressed as body protein weight at maturity (BPm), the LMR were 172 and 148 (period I), 216 and 207 (period II), and 189 and 180 mg BPm^0.73 kg⁻¹ (period III) for males and females, respectively. The results provided ranges of LMR values recommended in previous studies, validating this procedure. The procedure to estimate the requirements presented here provides new insights into the model of amino acid requirement estimations.

Keywords:
amino acid; exponential model; likelihood ratio; maintenance; nitrogen balance

Introduction

The concept of maintenance has been defined as the state of balance between the intake of nutrients and their inevitable losses (Siqueira et al., 2011Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
https://doi.org/10.1590/S1516-3598201100... ; Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ; Soares et al., 2019Soares, L.; Sakomura, N. K.; Dorigam, J. C. P.; Liebert, F.; Nascimento, M. Q. and Kochenborger, J. B. K. 2019. Nitrogen maintenance requirements and potential for nitrogen retention of pullets in growth phase. Journal of Animal Physiology and Animal Nutrition 103:1168-1173. https://doi.org/10.1111/jpn.13117
https://doi.org/10.1111/jpn.13117... ). That contributes to an understanding of the differences in responses between individuals of a population and enhances the requirements concept. Different methodologies have been developed to estimate nitrogen and amino acid requirements for maintenance (Burnham and Gous, 1992Burnham, D. and Gous, R. M. 1992. Isoleucine requirements of the chicken: requirement for maintenance. British Poultry Science 33:59-69. https://doi.org/10.1080/00071669208417444
https://doi.org/10.1080/0007166920841744... ; Siqueira et al., 2011Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
https://doi.org/10.1590/S1516-3598201100... ; Samadi and Liebert, 2006Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
https://doi.org/10.1093/ps/85.8.1421... ; Dorigam et al., 2014Dorigam, J. C. P.; Sakomura, N. K.; Silva, E. P. and Fernandes, J. B. F. 2014. Modelling the maximum potential of nitrogen deposition and requirements of lysine for broilers. Animal Production Science 54:1953-1959. https://doi.org/10.1071/AN14536
https://doi.org/10.1071/AN14536... ; Dos Santos et al., 2014Dos Santos, P. A.; Rabello, C. B. V.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Dos Santos, M. J. B. and Lorena-Rezende, I. M. B. 2014. Modelling of the nitrogen deposition and dietary lysine requirements of Redbro broilers. Animal Production Science 54:1946-1952. https://doi.org/10.1071/AN14543
https://doi.org/10.1071/AN14543... ; Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ). Some of these studies employed procedures that use a nitrogen-free diet and assume a linear relationship between nitrogen balance (NB) and nitrogen intake (NI), but these procedures have been criticized in the literature (Samadi and Liebert, 2006Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
https://doi.org/10.1093/ps/85.8.1421... ).

Traditionally, the use of a nitrogen-free diet enables the quantification of inevitable nitrogen losses and results in a negative NB of the bird. A negative NB is essential to estimate the maintenance requirement using the linear relationship between NB and NI. However, this procedure has been questioned because the deprivation of nitrogen or protein intake enhances the catabolism of body protein (Mitchell, 1924Mitchell, H. H. 1924. A method of determining the biological value of protein. The Journal of Biological Chemistry 58:873-903.), and this physiological state does not correspond to practical farm conditions (Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ). Most maintenance requirements used in factorial models are assumed to vary with body weight or metabolic body weight (Lima et al., 2016Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
https://doi.org/10.3382/ps/pev380... ; Reis et al., 2018Reis, M. P.; Sakomura, N. K.; Teixeira, I. A. M. A.; Silva, E. P. and Kebreab, E. 2018. Partitioning the efficiency of utilization of amino acids in growing broilers: multiple linear regression and multivariate approaches. PLoS One 13:e0208488. https://doi.org/10.1371/journal.pone.0208488
https://doi.org/10.1371/journal.pone.020... ; Silva et al., 2019Silva, E. P.; Sakomura, N. K.; Sarcinelli, M. F; Dorigam, J. C. P.; Venturini, K. S. and Lima, M. B. 2019. Modeling the response of Japanese quail hens to lysine intake. Livestock Science 224:69-74. https://doi.org/10.1016/j.livsci.2019.04.005
https://doi.org/10.1016/j.livsci.2019.04... ; Melaré et al., 2019Melaré, M. C.; Sakomura, N. K.; Reis, M. D. P.; Peruzzi, N. J. and Goncalves, C. A. 2019. Factorial models to estimate isoleucine requirements for broilers. Journal of Animal Physiology and Animal Nutrition 103:1107-1115. https://doi.org/10.1111/jpn.13101
https://doi.org/10.1111/jpn.13101... ). However, it has been suggested that amino acid and protein requirements for maintenance are better related to body protein content (Emmans and Fisher, 1986Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London.; Siqueira et al., 2011Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
https://doi.org/10.1590/S1516-3598201100... ; Lima et al., 2016Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
https://doi.org/10.3382/ps/pev380... ).

A procedure published by Samadi and Liebert (2006)Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
https://doi.org/10.1093/ps/85.8.1421... enables the determination of the nitrogen maintenance requirement (NMR) in birds with a positive NB using an exponential relationship between nitrogen excretion (NEX) and NI. The estimated intercept (NMR when NI = 0) corresponds to the NEX of a bird that receives a nitrogen-free diet (Samadi and Liebert, 2006Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
https://doi.org/10.1093/ps/85.8.1421... ). In addition, the NMR can be interpreted as the inevitable losses of nitrogen or endogenous protein, which reflects the catabolism of the amino acids that contribute to the inefficient use of dietary amino acids for protein deposition in growing animals (Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ; Ekmay et al., 2016Ekmay, R. D.; Mei, S. J.; Sakomura, N. K. and Coon, C. N. 2016. The cysteine, total sulfur amino acid, tyrosine, phenylalanine + tyrosine, and non-essential amino acid maintenance requirements of broiler breeders. Poultry Science 95:1341-1347. https://doi.org/10.3382/ps/pew031
https://doi.org/10.3382/ps/pew031... ). Adapting this concept and using experimental conditions in which lysing (Lys) is the first-limiting amino acid for protein deposition, the LMR can be determined using an exponential relationship between NEX and Lys intake (LI).

The objective of this study was to determine the Lys maintenance requirements of male and female using broilers as animal models.

Material and Methods

This study was approved by the local Ethics Committee on Animal Use (no. 007125-08). The experiments were conducted in Jaboticabal, SP, Brazil (21°15'16" S; 48°19'19" W, altitude 607 m).

Nitrogen balance trials were conducted in periods from 6 to 21 (I), 22 to 37 (II), and 38 to 53 (III) days of age, and 84 broiler chickens (Cobb500^® genotype; 42 males and 42 females) were used in each trial. The birds were housed individually in metabolic cages and were distributed in a complete randomised design with seven treatments and six replicates of males and six females per experimental unit.

The treatments consisted of six graded lysine levels of 2.76 (L1), 5.88 (L2), 8.99 (L3), 12.1 (L4), 15.2 (L5), and 18.3 g kg⁻¹ (L6) of diet in which the Lys:CP remained constant (4.91 g 16 g N⁻¹) and Lys was assumed to be the first-limiting amino acid for growth. A seventh treatment (L7) was obtained by the addition of 4 g of L-Lys HCl (78%) kg⁻¹ of feed to a diet similar to L1 that contained 2.76 g Lys kg⁻¹ of diet (as fed) as a control diet. This diet was used to verify whether Lys was actually the first limiting amino acid in the diets. The experimental diets were obtained via diluting a summit diet with a dilution diet (Tables 1 and 2). The proportions used in the summit diet (L6) and the dilution diet (L0) to prepare the experimental diets were L1 = 15:85, L2 = 32:68, L3 = 49:51, L4 = 66:34, L5 = 83:17, and L6 = 100:0.

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Table 1
Ingredients and nutritional composition of the basal diets used in the formulation of the experimental diets using the dilution technique (g kg⁻¹)

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Table 2
Nutritional composition (as fed) of the experimental diets (g kg⁻¹)

Three NB trials within period (6 to 21, 22 to 37, and 38 to 53 days of age) were conducted using six birds per diet and sex. The individual experimental period was divided into five days of adaptation and two consecutive excreta collection periods of five days each. Birds were fed ad libitum during the adaptation period and were restrictively fed during the collection period based on the feed intake measured in the adaptation period. At the end of the experimental period, the data from those two collection periods were combined to increase the number of replications. This procedure was used to compensate for the effects of age on feed intake as proposed by Samadi and Liebert (2006)Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
https://doi.org/10.1093/ps/85.8.1421... . The excreta were collected in trays and weighed at the end of each period and then frozen. At the end of each period, two birds per replication were killed to determine Lys content in the body.

The excreta samples obtained from each experimental unit during each period were thawed and homogenised. To determine body Lys content, the carcasses were processed in a meat mill. Representative quantities of the samples (excreta and carcass) were weighed in Petri dishes and frozen again (−20 °C) for freeze-drying. The samples were re-frozen and lyophilised for 72 h at −80 °C under 800 mbar of pressure (Edwards^® 501 Modulyo freeze drier, West Sussex, United Kingdom). The samples were weighed to quantify the dry matter content and ground in a Micro Mill (IKA^® A11 Basic Analytical Mill, Staufen, Germany). The total nitrogen content of the diets, excreta, and carcasses were analysed in a nitrogen distiller (Kjeltec™ 8400 Foss, Foss, Hillerod, Denmark) using the Kjeldahl method (Method No. 2001.11) according to AOAC (2004AOAC - Association of Official Analytical Chemistry. 2004. Official methods of analysis. 18th ed. AOAC, Gaithersburg.). The factor 6.25 was used to convert the nitrogen content to crude protein (CP). The total amino acid contents of the carcasses and the diets were analysed by Ajinomoto Ltd. using high-performance liquid chromatography (HPLC). The correction of the total amino acid content in the diets for digestible amino acids was performed using the tabulated digestibility coefficients (Rostagno et al., 2011Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos: Composição de alimentos e exigências nutricionais. 3.ed. UFV, Viçosa, MG.).

The data were analysed for one-way ANOVA using SAS software (Statistical Analysis System, version 9.1). The value of 0.67 data was used as the exponent for BW to eliminate the influence of BW on NB according to a basic model for growing animals (Gebhardt, 1980Gebhardt, G. 1980. Eiweiβ-und Aminosäurenverwertung in Beziehung zum Stoffwechsel der limitierenden Aminosäure. Archives of Animal Nutrition 30:63-71. https://doi.org/10.1080/17450398009441181
https://doi.org/10.1080/1745039800944118... ). The LI (mg BW^0.67 kg⁻¹ per day) was obtained considering the Lys concentration (c, g Lys 16 g N⁻¹) in NI as suggested by Samadi and Liebert (2008)Samadi and Liebert, F. 2008. Modelling the optimal lysine to threonine ratio in growing chickens depending on age and efficiency of dietary amino acid utilization. British Poultry Science 49:45-54. https://doi.org/10.1080/00071660701821667
https://doi.org/10.1080/0007166070182166... :

(1)

LI = (NI \times c) / 16

A regression analysis between LI (mg BW^0.67 kg⁻¹ per day) and NEX (mg BW^0.67 kg⁻¹ per day) was used to fit an exponential function for males and females. The average Lys concentration analysed in body protein (BLys, as a % of body protein) was used as a constant value, so NEX at zero LI can be converted to the Lys maintenance requirement (LMR). The resulting equation from this relation can be described as:

(2)

NEX = (LMR \times e^{b \times LI}) / (6.25 \times BLys)

From equation 2, the LMR (mg BW^0.67 kg⁻¹ per day) was estimated as the intercept of the model when LI = 0. The value 6.25 is used to convert nitrogen to protein.

The fitted models for males and females were compared using a statistical analysis to verify the similarity of model parameters. The following hypotheses were tested:

$H_{0} : {LMR}_{male} = {LMR}_{female} = {LMR}_{general}$ vs. H₁: not all LMRs are equal;
$H_{0} : b_{male} = b_{female} = b_{general}$ vs. H₁: not all b are equal;
$H_{0} : {LMR}_{male} = {LMR}_{female} = {LMR}_{general}$ and $b_{male} = b_{female} = b_{general}$ vs. H₁: at least one parameter is not equal (LMR or b).

Based on these hypotheses, the following models were adjusted: Ω = unrestricted model, in which the two parameters (LMR and b) were adjusted to males and females; ω₁ = restricted model, in which the LMR parameter is common for males and females (this model was verified by the hypothesis H₀ (1)); ω₂ = restricted model, in which the b parameter is common to males and females (this model was verified by the hypothesis H₀ (2)); ω₃ = restricted model, with all parameters common to males and females (general) (this model was verified by the hypothesis H₀ – (3)).

The likelihood ratio test was used to test these hypotheses. Considering the samples of n observations, the distribution of the likelihood function (– 2 ln (L)) was approximately a chi-square distribution (χ²) with ν degrees of freedom (Regazzi, 2003Regazzi, A. J. 2003. Teste para verificar a igualdade de parâmetros e a identidade de modelos de regressão não-linear. Revista Ceres 50:9-26.) calculated as:

(3)

χ^{2}_{calculated} = - n \times l n ({RSS}_{Ω} / {RSS}_{ω})

in which n is the number of observations; RSS_Ω is the residual sum of squares for Ω; and RSS_ω is the residual sum of squares for ω₁, ω₂, or ω₃. The probability value was subsequently subjected to a chi-square distribution with ν degrees of freedom.

To analyse the intercept of the exponential function, the models were chosen based on the significance degree of the statistical analysis (P-value). The first step was to analyse if one model could describe the response for males and females (ω₃, P>0.05). If a general model was not possible (ω₃, P<0.05), the next step was to analyse a model that described the same intersection point (in this case LMR) for both males and females (ω₁, P>0.05). Thus, although the model for males and females describes different slope rates, an adequate model has LMR parameters that do not differ between males and females. If these cases were not possible, the models must be considered separately for males and females.

A Gompertz function (Gompertz, 1825Gompertz, B. 1825. On the nature of the function expressive of the law of human mortality, and on a new mode of determining the value of life contingencies. Philosophical Transactions of the Royal Society of London 115:513-583. http://www.jstor.org/stable/107756
http://www.jstor.org/stable/107756... ) was fitted to the NB data to describe the body protein weight (BP_t) as a function of time (t) for males and females:

(4)

{BP}_{t} = {BP}_{m} \times e^{(- e (- B \times (t - t*)))}

in which BP_m is the mature body protein weight (kg), t* is the is the age when the growth rate is maximum (days), t is the time after hatching (days), and B is the rate of maturing of body protein (day⁻¹). The LMR was recalculated from metabolic body weight (BW^0.67) to metabolic protein weight at maturity (BPm^0.73 × u), as suggested by Emmans and Fisher (1986)Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London.. The BPm^0.73 value is the metabolic protein weight at maturity (kg) and u is the degree of maturity of the protein at time t (u = BPt/BPm,), which corrects the requirements for age. An important distinction in the scaling here is that 0.73 is used only for mature weight and should not be used as BW^0.73 in which BW is an immature body weight (Taylor, 1980Taylor, C. S. 1980. Genetic size-scaling rules in animal growth. Animal Production 30:161-165. https://doi.org/10.1017/S0003356100023941
https://doi.org/10.1017/S000335610002394... ).

Results

The N deposition was greater for birds receiving the control treatment (L7) compared with those receiving L1 diet, which confirms that Lys was the first limiting amino acid in the diet.

Both males (Table 3) and females (Table 4) responded significantly (P<0.001) in N deposition because of the graded dietary Lys supply in L1-L6 diets. In addition, N excretion significantly increased (P<0.001) with increasing N intake, exceeding the observed N deposition data for L6 diet for males in period III (Table 3) and females fed L6 diet in periods II and fed L5-L6 diets in period III. Although a response was observed in N deposition data, both males and females did not respond significantly (P>0.05) in body weight and feed intake, except for feed intake in period III. However, it can be observed that body weight and feed intake were lower in birds fed the lowest Lys level than in those fed diets L2-L6.

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Table 3
Effects of the experimental diets (limiting in lysine) on the nitrogen (N) balance data (±SD)¹ 1 Standard deviation. in male birds in each period

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Table 4
Effects of the experimental diets (limiting in lysine) on nitrogen (N) balance data (±SD)¹ 1 Standard deviation. in female birds in each period

The average body lysine content (BLys) was determined as 6.4% of the body protein, and this value was used in equation 2 for modelling lysine maintenance requirements.

The exponential regression between LI and NEX were fitted according to equation 2, and the daily values for LMR were 9.29, 33.4, and 40.2 mg BW^0.67 kg⁻¹ per day for males and 9.36, 30.0, and 39.4 mg BW^0.67 kg⁻¹ per day for females. The estimated values of the intercept for LI = 0 were similar in each period studied for both sexes. Therefore, the similarity test of the models was used for the hypothesis of similarity of the model parameters b and LMR in each phase for both sexes (Table 5).

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Table 5
Estimate of the parameters (±SD) of the unrestricted (Ω) and restricted (ω₁ to ω₃) exponential models from nitrogen balance data for male and female birds in each period

The similarity test of the models did not indicate differences between the LMR (P>0.05) for male and female birds in period I. However, the obtained models in periods II and III are different for males and females (P<0.05). The LMR was not different for both sexes in periods II and III (P>0.05) and were estimated at 10.1, 31.5, and 39.8 mg BW^0.67 kg⁻¹ per day for periods I, II, and III, respectively. There was a good fit of the exponential model for the LI and NEX data, with R² values higher than 0.89 (Figure 1).

Figure 1
Estimation of lysine maintenance requirement (LMR) via the exponential fit between lysine intake (LI) and nitrogen excretion (NEX) for male and female broilers.

The BPm values used in the calculations were obtained from the Gompertz function (equation 4) and were 1.07 kg for males and 0.70 kg for females. The estimated t* values were 43 days for males and 37 days for females, and the B values were 0.04 day⁻¹ for males and 0.05 day⁻¹ for females. Using these coefficients for males and females in equation 4, the BPt were estimated as 30.2 and 29.6 g at 14 days, 188 and 169 g at 30 days, and 458 and 369 g at 46 days of age for males and females, respectively. Dividing BPt by BPm resulted in values of u: 0.03 and 0.04 (14 days), 0.18 and 0.24 (30 days), and 0.43 and 0.53 (46 days) for males and females, respectively. Recalculating the LMR from metabolic body weight (10.1, 31.5, and 39.8 mg BW^0.67 kg⁻¹ per day) to a metabolic protein weight at maturity (BPm^0.73 × u) resulted in the following Lys maintenance requirements: 172 and 148 mg BPm^0.73 kg⁻¹ (period I); 216 and 207 mg BPm^0.73 kg⁻¹ (period II); 189 and 180 mg BPm^0.73 kg⁻¹ (period III) for males and females, respectively.

Discussion

The concept of maintenance has been widely accepted in animal nutrition. However, it is difficult to make reliable comparisons because of divergences in the mathematical procedures and response criteria used by authors to assess maintenance requirements. For example, Edwards et al. (1999)Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
https://doi.org/10.1093/ps/78.10.1412... determined LMR by considering Lys and protein accretion equal to zero in the linear equations. However, considering zero daily Lys accretion (32.3 mg d⁻¹ or 89.1 mg BW^0.67 kg⁻¹ per day) resulted in higher maintenance requirement estimates than zero daily protein accretion (2.50 mg d⁻¹ or 6.90 mg BW^0.67 kg⁻¹ per day) for birds from 10 to 20 days of age. On the other hand, the estimates obtained from the exponential function in the present study indicated that a LMR of 9.29 and 9.36 mg BW^0.67 kg⁻¹ per day is equivalent to 4.69 and 4.48 mg BW^0.67 kg⁻¹ per day for males and females, respectively, for the period of 6 to 21 days of age, and thus similar to those obtained for zero daily protein accretion reported by Edwards et al. (1999)Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
https://doi.org/10.1093/ps/78.10.1412... . This implies that LMR for birds is not as high as suggested by Edwards et al. (1999)Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
https://doi.org/10.1093/ps/78.10.1412... and is in line with those suggested by others (Emmert and Baker, 1997Emmert, J. L. and Baker, D. H. 1997. Use of the ideal protein concept for precision formulation of amino acid levels in broiler diets. Journal of Applied Poultry Research 6:462-470. https://doi.org/10.1093/japr/6.4.462
https://doi.org/10.1093/japr/6.4.462... ).

The LMR reflects the physical losses via endogenous protein in the intestine and integuments (Silva et al., 2011Silva, E. P.; Rabello, C. B. V.; Lima, M. B.; Lima, S. B. P.; Lima, R. B. and Lima, T. S. 2011. Efeito da idade sobre as perdas endógenas e metabólicas de frangos de corte industrial e caipira. Ciência Animal Brasileira 12:37-47. https://doi.org/10.5216/cab.v12i1.5096
https://doi.org/10.5216/cab.v12i1.5096... ; Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ; Ekmay et al., 2016Ekmay, R. D.; Mei, S. J.; Sakomura, N. K. and Coon, C. N. 2016. The cysteine, total sulfur amino acid, tyrosine, phenylalanine + tyrosine, and non-essential amino acid maintenance requirements of broiler breeders. Poultry Science 95:1341-1347. https://doi.org/10.3382/ps/pew031
https://doi.org/10.3382/ps/pew031... ). The inefficient utilisation of dietary Lys for protein deposition and the inevitable endogenous losses resulted in daily LMR, which were estimated by the exponential relationship between LI and NEX as 9.29, 33.4, and 40.2 mg BW^0.67 kg⁻¹ per day for males and 9.36, 30.0, and 39.4 mg BW^0.67 kg⁻¹ per day for females during periods I, II, and III, respectively. This was expected because the proportion of the total daily requirement of amino acids necessary for maintenance is minimal during the initial period, but this requirement increases as the bird grows (Emmert and Baker, 1997Emmert, J. L. and Baker, D. H. 1997. Use of the ideal protein concept for precision formulation of amino acid levels in broiler diets. Journal of Applied Poultry Research 6:462-470. https://doi.org/10.1093/japr/6.4.462
https://doi.org/10.1093/japr/6.4.462... ; Silva et al., 2014Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
https://doi.org/10.1590/S0103-8478201400... ; Araujo et al., 2014Araujo, J. A.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Donato, D. C. Z.; Silva, J. H. V. and Fernandes, J. B. K. 2014. Response of pullets to digestible lysine intake. Czech Journal of Animal Science 59:208-218. https://doi.org/10.17221/7401-CJAS
https://doi.org/10.17221/7401-CJAS... ). The efficiency of Lys utilisation for protein deposition decreases with increasing weight of the bird combined with an increase in the maintenance (Eits et al., 2002Eits, R. M.; Kwakkel, R. P. and Verstegen, M. W. A. 2002. Nutrition affects fat-free body composition in broiler chickens. The Journal of Nutrition 132:2222-2228. https://doi.org/10.1093/jn/132.8.2222
https://doi.org/10.1093/jn/132.8.2222... ; Araujo et al., 2014Araujo, J. A.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Donato, D. C. Z.; Silva, J. H. V. and Fernandes, J. B. K. 2014. Response of pullets to digestible lysine intake. Czech Journal of Animal Science 59:208-218. https://doi.org/10.17221/7401-CJAS
https://doi.org/10.17221/7401-CJAS... ; Dorigam et al., 2014Dorigam, J. C. P.; Sakomura, N. K.; Silva, E. P. and Fernandes, J. B. F. 2014. Modelling the maximum potential of nitrogen deposition and requirements of lysine for broilers. Animal Production Science 54:1953-1959. https://doi.org/10.1071/AN14536
https://doi.org/10.1071/AN14536... ; Donato et al., 2016Donato, D. C. Z.; Sakomura, N. K.; Silva, E. P.; Troni, A. R.; Vargas, L.; Guagnoni, M. A. N. and Meda, B. 2016. Manipulation of dietary methionine+cysteine and threonine in broilers significantly decreases environmental nitrogen excretion. Animal 10:903-910. https://doi.org/10.1017/S175173111500289X
https://doi.org/10.1017/S175173111500289... ).

The efficiency with which absorbed Lys is used for protein deposition in growing young chicks is between 70 and 80% (Edwards et al., 1999Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
https://doi.org/10.1093/ps/78.10.1412... ; Fatufe et al., 2004Fatufe, A. A.; Timmler, R. and Rodehutscord, M. 2004. Response to lysine intake in composition of body weight gain and efficiency of lysine utilization of growing male chickens from two genotypes. Poultry Science 83:1314-1324. https://doi.org/10.1093/ps/83.8.1314
https://doi.org/10.1093/ps/83.8.1314... ; Araujo et al., 2014Araujo, J. A.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Donato, D. C. Z.; Silva, J. H. V. and Fernandes, J. B. K. 2014. Response of pullets to digestible lysine intake. Czech Journal of Animal Science 59:208-218. https://doi.org/10.17221/7401-CJAS
https://doi.org/10.17221/7401-CJAS... ). According to this information, between 20 and 30% of Lys could be used for maintenance, which could explain the lower Lys maintenance requirement found in period I in relation to the requirement of Lys observed for growth (Baker, 1997Baker, D. H. 1997. Ideal amino acid profiles for swine and poultry and their applications in feed formulation. BioKyowa Technical Review 9:1-24.). In this study, the tested models for period I are similar and can be used as a single model to describe the response in both sexes ( $NEX = 10.1 \times e^{0.00252 \times LI}$ , P>0.05). The model similarity (P>0.05) to describe the response for both males and females indicates that these birds exhibit the same pattern of initial growth regardless of sex (Table 5). According to the results of Marcato et al. (2008)Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
https://doi.org/10.1590/S1516-635X200800... , protein deposition is similar for male and female birds up to 21 days (11.3 vs. 12.3 g/day) and become different thereafter. However, a single model was not able to represent the metabolic pattern of these birds during the other periods, as noted in the similarity test of the models (Table 5). The females in this study had lower LMR in period II (30.0 mg BW^0.67 kg⁻¹ per day) compared with the males (33.4 mg BW^0.67 kg⁻¹ per day).

The LMR estimated in period III were very similar for both sexes (40.2 and 39.4 mg BW^0.67 kg⁻¹ per day for males and females, respectively). In this period, the birds are close to the maximum protein deposition rate, which corresponds to 43 days for males and 37 days for females, calculated by equation 4. These values were similar because the ratios between the amino acid deposition in the carcass and catabolism remain fairly constant throughout the growth period after reaching the maximum protein deposition at this age (Sklan and Noy, 2004Sklan, D. and Noy, Y. 2004. Catabolism and deposition of amino acids in growing chicks: effect of dietary supply. Poultry Science 83:952-961. https://doi.org/10.1093/ps/83.6.952
https://doi.org/10.1093/ps/83.6.952... ). Although these values are similar, one model is not sufficient to describe the responses of both sexes at this age, as demonstrated by the likelihood test (Table 5). One point on the axis of ordinates is capable of representing the LMR parameters for both sexes (P>0.05), according to the test proposed by Regazzi (2003)Regazzi, A. J. 2003. Teste para verificar a igualdade de parâmetros e a identidade de modelos de regressão não-linear. Revista Ceres 50:9-26.. Therefore, we adopted the daily values of 31.5 (period II) and 39.8 mg BW^0.67 kg⁻¹ per day (period III).

According to the coefficients estimated from Gompertz function, the maximum protein deposition rate corresponds to 43 days for males and 37 days for females (equation 4). In relation to these estimations, these birds presented a delay of six days to reach maturity in comparison to the estimates of 37 days for males and 31 days for females of Marcato et al. (2008)Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
https://doi.org/10.1590/S1516-635X200800... . This delay could be explained by the limiting effect in the response of birds feeding the experimental diets, which were limiting in Lys. Therefore, the birds took longer to express their maximum potential for protein deposition, different from that observed by Marcato et al. (2008)Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
https://doi.org/10.1590/S1516-635X200800... , wherein birds were fed diets not limiting in nutrients. However, the BPm values of 1.07 kg for males and 0.70 kg for females were close to the values estimated by Siqueira et al. (2010)Siqueira, J. C.; Sakomura, N. K.; Gous, R. M.; Teixeira, I. A. M. A.; Fernandes, J. B. K. and Malheiros, E. B. 2010. Model to estimate lysine requirements of broilers. p.306-314. In: 7th International Workshop on Modelling Nutrient Digestion and Utilisation in Farm Animals. Sauvant, D.; van Milgen, J.; Faverdin, P. and Friggens, N., eds. Wageningen Academic Publisher, Paris. of 1.09 kg for males and the values estimated by Marcato et al. (2008)Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
https://doi.org/10.1590/S1516-635X200800... of 1.04 kg for males and 0.67 kg for females of the Cobb500^® genotype.

The energy from dietary protein that cannot be retained as body protein can be used for fat deposition. Providing a diet deficient in amino acids will thus increase fat deposition (Gous et al., 1990Gous, R. M.; Emmans, G. C.; Broadbent, L. A. and Fisher, C. 1990. Nutritional effects on the growth and fatness of broilers. British Poultry Science 31:495-505. https://doi.org/10.1080/00071669008417281
https://doi.org/10.1080/0007166900841728... ). Moreover, the fat deposition ratio of males and females are different (Sakomura et al., 2005Sakomura, N. K.; Longo, F. A.; Oviedo-Rondon, E. O.; Boa-Viagem, C. and Ferraudo, A. 2005. Modeling energy utilization and growth parameter description for broiler chickens. Poultry Science 84:1363-1369. https://doi.org/10.1093/ps/84.9.1363
https://doi.org/10.1093/ps/84.9.1363... ). The change in body fat content represents a difficulty in the estimation of the maintenance requirement using traditional methods because there is little or no demand for amino acids for the maintenance of lipid reserves (Siqueira et al., 2011Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
https://doi.org/10.1590/S1516-3598201100... ; Lima et al., 2016Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
https://doi.org/10.3382/ps/pev380... ; Soares et al., 2019Soares, L.; Sakomura, N. K.; Dorigam, J. C. P.; Liebert, F.; Nascimento, M. Q. and Kochenborger, J. B. K. 2019. Nitrogen maintenance requirements and potential for nitrogen retention of pullets in growth phase. Journal of Animal Physiology and Animal Nutrition 103:1168-1173. https://doi.org/10.1111/jpn.13117
https://doi.org/10.1111/jpn.13117... ). As the amino acid requirement is more related to body protein deposition and given that at same body weight the birds could have different chemical body composition, Lys maintenance requirements are expressed more appropriately relative to body protein than to body weight (Lima et al., 2016Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
https://doi.org/10.3382/ps/pev380... ).

According to Taylor (1980)Taylor, C. S. 1980. Genetic size-scaling rules in animal growth. Animal Production 30:161-165. https://doi.org/10.1017/S0003356100023941
https://doi.org/10.1017/S000335610002394... and Emmans and Fisher (1986)Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London., the maintenance requirement should be related to protein weight and maturity of body protein (u), given by the relation between protein weight at time and protein weight at maturity. The scale used by these authors does not consider the fat content, which may eliminate the imprecision in determining the amino acid requirements due to variation of the fat content that vary widely in birds of the same genotype and similar body weight (Lima et al., 2016Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
https://doi.org/10.3382/ps/pev380... ).

Therefore, the daily estimates in this study are more appropriately expressed as 172, 216, and 189 mg BPm^0.73 kg⁻¹ × u for males and 148, 207, and 180 mg BPm^0.73 kg⁻¹ × u for females in periods I, II, and III, respectively. The requirements expressed in this manner enable more refined comparisons between birds of different body weight across different studies; they also enable the recommendations to be extrapolated to birds of different ages and degrees of maturity of body protein.

In this research, we showed a way to correct the maintenance values determined with growing animals. When we use the system of protein weight at maturity and metabolic protein weight at maturity (BPm^0.73 kg⁻¹ × u), it is possible to extrapolate the recommendation even determined with young animals.

Siqueira et al. (2011)Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
https://doi.org/10.1590/S1516-3598201100... determined values between 141 to 174 and an average of 158 kg of BPm^0.73 × u for adult roosters. In this research, the average value was 185 (148-216) mg per kg of BPm^0.73 × u. The use of metabolic protein weight (Emmans and Fisher, 1986Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London.) and scale (Taylor, 1980Taylor, C. S. 1980. Genetic size-scaling rules in animal growth. Animal Production 30:161-165. https://doi.org/10.1017/S0003356100023941
https://doi.org/10.1017/S000335610002394... ) can be used to decrease the influence of growth on the estimate of maintenance. The values found were close to those determined with adult animals, especially when considering the variability. However, there is still an overall average effect when comparing young animal values of 185 versus 158 for adult animals, showing the influence of growth. However, this difference may have the influence of the studied amino acid lysine that has important effect on broiler growth (Dorigam et al., 2016Dorigam, J. C. P.; Sakomura, N. K.; Lima, M. B.; Sarcinelli, M. F. and Suzuki, R. M. 2016. Establishing an essential amino acid profile for maintenance in poultry using deletion method. Journal of Animal Physiology and Animal Nutrition 100:884-892. https://doi.org/10.1111/jpn.12403
https://doi.org/10.1111/jpn.12403... ), and future studies can be developed with other amino acids to confirm our hypothesis.

Conclusions

The lysine maintenance requirements for both sexes are 10.1 (period I: 6-21 days), 31.5 (period II: 22-37 days), and 39.8 mg BW^0.67 kg⁻¹ (period III: 38-53 days). The results provided ranges of lysine maintenance requirements values recommended in previous studies, validating this procedure. The procedure to estimate the requirements presented here provides new insights into the model of amino acid requirement estimations.

Acknowledgments

The authors gratefully acknowledge Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) for financial support (grant number no. 2011/04313-8) and Ajinomoto Ltd., for crystalline amino acid donation and amino acid analysis.

References

AOAC - Association of Official Analytical Chemistry. 2004. Official methods of analysis. 18th ed. AOAC, Gaithersburg.
Araujo, J. A.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Donato, D. C. Z.; Silva, J. H. V. and Fernandes, J. B. K. 2014. Response of pullets to digestible lysine intake. Czech Journal of Animal Science 59:208-218. https://doi.org/10.17221/7401-CJAS
» https://doi.org/10.17221/7401-CJAS
Baker, D. H. 1997. Ideal amino acid profiles for swine and poultry and their applications in feed formulation. BioKyowa Technical Review 9:1-24.
Burnham, D. and Gous, R. M. 1992. Isoleucine requirements of the chicken: requirement for maintenance. British Poultry Science 33:59-69. https://doi.org/10.1080/00071669208417444
» https://doi.org/10.1080/00071669208417444
Donato, D. C. Z.; Sakomura, N. K.; Silva, E. P.; Troni, A. R.; Vargas, L.; Guagnoni, M. A. N. and Meda, B. 2016. Manipulation of dietary methionine+cysteine and threonine in broilers significantly decreases environmental nitrogen excretion. Animal 10:903-910. https://doi.org/10.1017/S175173111500289X
» https://doi.org/10.1017/S175173111500289X
Dorigam, J. C. P.; Sakomura, N. K.; Lima, M. B.; Sarcinelli, M. F. and Suzuki, R. M. 2016. Establishing an essential amino acid profile for maintenance in poultry using deletion method. Journal of Animal Physiology and Animal Nutrition 100:884-892. https://doi.org/10.1111/jpn.12403
» https://doi.org/10.1111/jpn.12403
Dorigam, J. C. P.; Sakomura, N. K.; Silva, E. P. and Fernandes, J. B. F. 2014. Modelling the maximum potential of nitrogen deposition and requirements of lysine for broilers. Animal Production Science 54:1953-1959. https://doi.org/10.1071/AN14536
» https://doi.org/10.1071/AN14536
Dos Santos, P. A.; Rabello, C. B. V.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Dos Santos, M. J. B. and Lorena-Rezende, I. M. B. 2014. Modelling of the nitrogen deposition and dietary lysine requirements of Redbro broilers. Animal Production Science 54:1946-1952. https://doi.org/10.1071/AN14543
» https://doi.org/10.1071/AN14543
Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
» https://doi.org/10.1093/ps/78.10.1412
Eits, R. M.; Kwakkel, R. P. and Verstegen, M. W. A. 2002. Nutrition affects fat-free body composition in broiler chickens. The Journal of Nutrition 132:2222-2228. https://doi.org/10.1093/jn/132.8.2222
» https://doi.org/10.1093/jn/132.8.2222
Ekmay, R. D.; Mei, S. J.; Sakomura, N. K. and Coon, C. N. 2016. The cysteine, total sulfur amino acid, tyrosine, phenylalanine + tyrosine, and non-essential amino acid maintenance requirements of broiler breeders. Poultry Science 95:1341-1347. https://doi.org/10.3382/ps/pew031
» https://doi.org/10.3382/ps/pew031
Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London.
Emmert, J. L. and Baker, D. H. 1997. Use of the ideal protein concept for precision formulation of amino acid levels in broiler diets. Journal of Applied Poultry Research 6:462-470. https://doi.org/10.1093/japr/6.4.462
» https://doi.org/10.1093/japr/6.4.462
Fatufe, A. A.; Timmler, R. and Rodehutscord, M. 2004. Response to lysine intake in composition of body weight gain and efficiency of lysine utilization of growing male chickens from two genotypes. Poultry Science 83:1314-1324. https://doi.org/10.1093/ps/83.8.1314
» https://doi.org/10.1093/ps/83.8.1314
Gebhardt, G. 1980. Eiweiβ-und Aminosäurenverwertung in Beziehung zum Stoffwechsel der limitierenden Aminosäure. Archives of Animal Nutrition 30:63-71. https://doi.org/10.1080/17450398009441181
» https://doi.org/10.1080/17450398009441181
Gompertz, B. 1825. On the nature of the function expressive of the law of human mortality, and on a new mode of determining the value of life contingencies. Philosophical Transactions of the Royal Society of London 115:513-583. http://www.jstor.org/stable/107756
» http://www.jstor.org/stable/107756
Gous, R. M.; Emmans, G. C.; Broadbent, L. A. and Fisher, C. 1990. Nutritional effects on the growth and fatness of broilers. British Poultry Science 31:495-505. https://doi.org/10.1080/00071669008417281
» https://doi.org/10.1080/00071669008417281
Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
» https://doi.org/10.3382/ps/pev380
Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
» https://doi.org/10.1590/S1516-635X2008000200007
Melaré, M. C.; Sakomura, N. K.; Reis, M. D. P.; Peruzzi, N. J. and Goncalves, C. A. 2019. Factorial models to estimate isoleucine requirements for broilers. Journal of Animal Physiology and Animal Nutrition 103:1107-1115. https://doi.org/10.1111/jpn.13101
» https://doi.org/10.1111/jpn.13101
Mitchell, H. H. 1924. A method of determining the biological value of protein. The Journal of Biological Chemistry 58:873-903.
Regazzi, A. J. 2003. Teste para verificar a igualdade de parâmetros e a identidade de modelos de regressão não-linear. Revista Ceres 50:9-26.
Reis, M. P.; Sakomura, N. K.; Teixeira, I. A. M. A.; Silva, E. P. and Kebreab, E. 2018. Partitioning the efficiency of utilization of amino acids in growing broilers: multiple linear regression and multivariate approaches. PLoS One 13:e0208488. https://doi.org/10.1371/journal.pone.0208488
» https://doi.org/10.1371/journal.pone.0208488
Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos: Composição de alimentos e exigências nutricionais. 3.ed. UFV, Viçosa, MG.
Sakomura, N. K.; Longo, F. A.; Oviedo-Rondon, E. O.; Boa-Viagem, C. and Ferraudo, A. 2005. Modeling energy utilization and growth parameter description for broiler chickens. Poultry Science 84:1363-1369. https://doi.org/10.1093/ps/84.9.1363
» https://doi.org/10.1093/ps/84.9.1363
Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
» https://doi.org/10.1093/ps/85.8.1421
Samadi and Liebert, F. 2008. Modelling the optimal lysine to threonine ratio in growing chickens depending on age and efficiency of dietary amino acid utilization. British Poultry Science 49:45-54. https://doi.org/10.1080/00071660701821667
» https://doi.org/10.1080/00071660701821667
Silva, E. P.; Rabello, C. B. V.; Lima, M. B.; Lima, S. B. P.; Lima, R. B. and Lima, T. S. 2011. Efeito da idade sobre as perdas endógenas e metabólicas de frangos de corte industrial e caipira. Ciência Animal Brasileira 12:37-47. https://doi.org/10.5216/cab.v12i1.5096
» https://doi.org/10.5216/cab.v12i1.5096
Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
» https://doi.org/10.1590/S0103-84782014000200022
Silva, E. P.; Sakomura, N. K.; Sarcinelli, M. F; Dorigam, J. C. P.; Venturini, K. S. and Lima, M. B. 2019. Modeling the response of Japanese quail hens to lysine intake. Livestock Science 224:69-74. https://doi.org/10.1016/j.livsci.2019.04.005
» https://doi.org/10.1016/j.livsci.2019.04.005
Siqueira, J. C.; Sakomura, N. K.; Gous, R. M.; Teixeira, I. A. M. A.; Fernandes, J. B. K. and Malheiros, E. B. 2010. Model to estimate lysine requirements of broilers. p.306-314. In: 7th International Workshop on Modelling Nutrient Digestion and Utilisation in Farm Animals. Sauvant, D.; van Milgen, J.; Faverdin, P. and Friggens, N., eds. Wageningen Academic Publisher, Paris.
Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
» https://doi.org/10.1590/S1516-35982011000400015
Sklan, D. and Noy, Y. 2004. Catabolism and deposition of amino acids in growing chicks: effect of dietary supply. Poultry Science 83:952-961. https://doi.org/10.1093/ps/83.6.952
» https://doi.org/10.1093/ps/83.6.952
Soares, L.; Sakomura, N. K.; Dorigam, J. C. P.; Liebert, F.; Nascimento, M. Q. and Kochenborger, J. B. K. 2019. Nitrogen maintenance requirements and potential for nitrogen retention of pullets in growth phase. Journal of Animal Physiology and Animal Nutrition 103:1168-1173. https://doi.org/10.1111/jpn.13117
» https://doi.org/10.1111/jpn.13117
Taylor, C. S. 1980. Genetic size-scaling rules in animal growth. Animal Production 30:161-165. https://doi.org/10.1017/S0003356100023941
» https://doi.org/10.1017/S0003356100023941

Publication Dates

Publication in this collection
11 May 2020
Date of issue
2020

History

Received
05 Sept 2018
Accepted
02 Jan 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AOAC - Association of Official Analytical Chemistry. 2004. Official methods of analysis. 18th ed. AOAC, Gaithersburg.

[2] Araujo, J. A.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Donato, D. C. Z.; Silva, J. H. V. and Fernandes, J. B. K. 2014. Response of pullets to digestible lysine intake. Czech Journal of Animal Science 59:208-218. https://doi.org/10.17221/7401-CJAS
» https://doi.org/10.17221/7401-CJAS

[3] Baker, D. H. 1997. Ideal amino acid profiles for swine and poultry and their applications in feed formulation. BioKyowa Technical Review 9:1-24.

[4] Burnham, D. and Gous, R. M. 1992. Isoleucine requirements of the chicken: requirement for maintenance. British Poultry Science 33:59-69. https://doi.org/10.1080/00071669208417444
» https://doi.org/10.1080/00071669208417444

[5] Donato, D. C. Z.; Sakomura, N. K.; Silva, E. P.; Troni, A. R.; Vargas, L.; Guagnoni, M. A. N. and Meda, B. 2016. Manipulation of dietary methionine+cysteine and threonine in broilers significantly decreases environmental nitrogen excretion. Animal 10:903-910. https://doi.org/10.1017/S175173111500289X
» https://doi.org/10.1017/S175173111500289X

[6] Dorigam, J. C. P.; Sakomura, N. K.; Lima, M. B.; Sarcinelli, M. F. and Suzuki, R. M. 2016. Establishing an essential amino acid profile for maintenance in poultry using deletion method. Journal of Animal Physiology and Animal Nutrition 100:884-892. https://doi.org/10.1111/jpn.12403
» https://doi.org/10.1111/jpn.12403

[7] Dorigam, J. C. P.; Sakomura, N. K.; Silva, E. P. and Fernandes, J. B. F. 2014. Modelling the maximum potential of nitrogen deposition and requirements of lysine for broilers. Animal Production Science 54:1953-1959. https://doi.org/10.1071/AN14536
» https://doi.org/10.1071/AN14536

[8] Dos Santos, P. A.; Rabello, C. B. V.; Sakomura, N. K.; Silva, E. P.; Dorigam, J. C. P.; Dos Santos, M. J. B. and Lorena-Rezende, I. M. B. 2014. Modelling of the nitrogen deposition and dietary lysine requirements of Redbro broilers. Animal Production Science 54:1946-1952. https://doi.org/10.1071/AN14543
» https://doi.org/10.1071/AN14543

[9] Edwards, H. M.; Fernandez, S. R. and Baker, D. H. 1999. Maintenance lysine requirement and efficiency of using lysine for accretion of whole-body lysine and protein in young chicks. Poultry Science 78:1412-1417. https://doi.org/10.1093/ps/78.10.1412
» https://doi.org/10.1093/ps/78.10.1412

[10] Eits, R. M.; Kwakkel, R. P. and Verstegen, M. W. A. 2002. Nutrition affects fat-free body composition in broiler chickens. The Journal of Nutrition 132:2222-2228. https://doi.org/10.1093/jn/132.8.2222
» https://doi.org/10.1093/jn/132.8.2222

[11] Ekmay, R. D.; Mei, S. J.; Sakomura, N. K. and Coon, C. N. 2016. The cysteine, total sulfur amino acid, tyrosine, phenylalanine + tyrosine, and non-essential amino acid maintenance requirements of broiler breeders. Poultry Science 95:1341-1347. https://doi.org/10.3382/ps/pew031
» https://doi.org/10.3382/ps/pew031

[12] Emmans, G. C. and Fisher, C. 1986. Problems in nutritional theory. p.9-39. In: Nutrient requirements of poultry and nutritional research. Fisher, C. and Boorman K. N., eds. Butterwordths, London.

[13] Emmert, J. L. and Baker, D. H. 1997. Use of the ideal protein concept for precision formulation of amino acid levels in broiler diets. Journal of Applied Poultry Research 6:462-470. https://doi.org/10.1093/japr/6.4.462
» https://doi.org/10.1093/japr/6.4.462

[14] Fatufe, A. A.; Timmler, R. and Rodehutscord, M. 2004. Response to lysine intake in composition of body weight gain and efficiency of lysine utilization of growing male chickens from two genotypes. Poultry Science 83:1314-1324. https://doi.org/10.1093/ps/83.8.1314
» https://doi.org/10.1093/ps/83.8.1314

[15] Gebhardt, G. 1980. Eiweiβ-und Aminosäurenverwertung in Beziehung zum Stoffwechsel der limitierenden Aminosäure. Archives of Animal Nutrition 30:63-71. https://doi.org/10.1080/17450398009441181
» https://doi.org/10.1080/17450398009441181

[16] Gompertz, B. 1825. On the nature of the function expressive of the law of human mortality, and on a new mode of determining the value of life contingencies. Philosophical Transactions of the Royal Society of London 115:513-583. http://www.jstor.org/stable/107756
» http://www.jstor.org/stable/107756

[17] Gous, R. M.; Emmans, G. C.; Broadbent, L. A. and Fisher, C. 1990. Nutritional effects on the growth and fatness of broilers. British Poultry Science 31:495-505. https://doi.org/10.1080/00071669008417281
» https://doi.org/10.1080/00071669008417281

[18] Lima, M. B.; Sakomura, N. K.; Dorigam, J. C. P.; Silva, E. P.; Ferreira, N. T. and Fernandes, J. B. K. 2016. Maintenance valine, isoleucine, and tryptophan requirements for poultry. Poultry Science 95:842-850. https://doi.org/10.3382/ps/pev380
» https://doi.org/10.3382/ps/pev380

[19] Marcato, S. M.; Sakomura, N. K.; Munari, D. P.; Fernandes, J. B. K.; Kawauchi, I. M. and Bonato, M. A. 2008. Growth and body nutrient deposition of two broiler commercial genetic lines. Brazilian Journal of Poultry Science 10:117-123. https://doi.org/10.1590/S1516-635X2008000200007
» https://doi.org/10.1590/S1516-635X2008000200007

[20] Melaré, M. C.; Sakomura, N. K.; Reis, M. D. P.; Peruzzi, N. J. and Goncalves, C. A. 2019. Factorial models to estimate isoleucine requirements for broilers. Journal of Animal Physiology and Animal Nutrition 103:1107-1115. https://doi.org/10.1111/jpn.13101
» https://doi.org/10.1111/jpn.13101

[21] Mitchell, H. H. 1924. A method of determining the biological value of protein. The Journal of Biological Chemistry 58:873-903.

[22] Regazzi, A. J. 2003. Teste para verificar a igualdade de parâmetros e a identidade de modelos de regressão não-linear. Revista Ceres 50:9-26.

[23] Reis, M. P.; Sakomura, N. K.; Teixeira, I. A. M. A.; Silva, E. P. and Kebreab, E. 2018. Partitioning the efficiency of utilization of amino acids in growing broilers: multiple linear regression and multivariate approaches. PLoS One 13:e0208488. https://doi.org/10.1371/journal.pone.0208488
» https://doi.org/10.1371/journal.pone.0208488

[24] Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos: Composição de alimentos e exigências nutricionais. 3.ed. UFV, Viçosa, MG.

[25] Sakomura, N. K.; Longo, F. A.; Oviedo-Rondon, E. O.; Boa-Viagem, C. and Ferraudo, A. 2005. Modeling energy utilization and growth parameter description for broiler chickens. Poultry Science 84:1363-1369. https://doi.org/10.1093/ps/84.9.1363
» https://doi.org/10.1093/ps/84.9.1363

[26] Samadi and Liebert, F. 2006. Estimation of nitrogen maintenance requirements and potential for nitrogen deposition in fast-growing chickens depending on age and sex. Poultry Science 85:1421-1429. https://doi.org/10.1093/ps/85.8.1421
» https://doi.org/10.1093/ps/85.8.1421

[27] Samadi and Liebert, F. 2008. Modelling the optimal lysine to threonine ratio in growing chickens depending on age and efficiency of dietary amino acid utilization. British Poultry Science 49:45-54. https://doi.org/10.1080/00071660701821667
» https://doi.org/10.1080/00071660701821667

[28] Silva, E. P.; Rabello, C. B. V.; Lima, M. B.; Lima, S. B. P.; Lima, R. B. and Lima, T. S. 2011. Efeito da idade sobre as perdas endógenas e metabólicas de frangos de corte industrial e caipira. Ciência Animal Brasileira 12:37-47. https://doi.org/10.5216/cab.v12i1.5096
» https://doi.org/10.5216/cab.v12i1.5096

[29] Silva, E. P.; Sakomura, N. K.; Bonato, M. A.; Donato, D. C. Z.; Peruzzi, N. J. and Fernandes, J. B. K. 2014. Descrição do potencial de retenção de nitrogênio em frangas de postura por diferentes metodologias: mínima retenção. Ciência Rural 44:333-340. https://doi.org/10.1590/S0103-84782014000200022
» https://doi.org/10.1590/S0103-84782014000200022

[30] Silva, E. P.; Sakomura, N. K.; Sarcinelli, M. F; Dorigam, J. C. P.; Venturini, K. S. and Lima, M. B. 2019. Modeling the response of Japanese quail hens to lysine intake. Livestock Science 224:69-74. https://doi.org/10.1016/j.livsci.2019.04.005
» https://doi.org/10.1016/j.livsci.2019.04.005

[31] Siqueira, J. C.; Sakomura, N. K.; Gous, R. M.; Teixeira, I. A. M. A.; Fernandes, J. B. K. and Malheiros, E. B. 2010. Model to estimate lysine requirements of broilers. p.306-314. In: 7th International Workshop on Modelling Nutrient Digestion and Utilisation in Farm Animals. Sauvant, D.; van Milgen, J.; Faverdin, P. and Friggens, N., eds. Wageningen Academic Publisher, Paris.

[32] Siqueira, J. C.; Sakomura, N. K.; Rostagno, H. S.; Bonato, M. A.; Pinheiro, S. R. F. and Nascimento, D. C. N. 2011. Exigência de lisina para mantença determinada com galos de diferentes genótipos. Revista Brasileira de Zootecnia 40:812-820. https://doi.org/10.1590/S1516-35982011000400015
» https://doi.org/10.1590/S1516-35982011000400015

[33] Sklan, D. and Noy, Y. 2004. Catabolism and deposition of amino acids in growing chicks: effect of dietary supply. Poultry Science 83:952-961. https://doi.org/10.1093/ps/83.6.952
» https://doi.org/10.1093/ps/83.6.952

[34] Soares, L.; Sakomura, N. K.; Dorigam, J. C. P.; Liebert, F.; Nascimento, M. Q. and Kochenborger, J. B. K. 2019. Nitrogen maintenance requirements and potential for nitrogen retention of pullets in growth phase. Journal of Animal Physiology and Animal Nutrition 103:1168-1173. https://doi.org/10.1111/jpn.13117
» https://doi.org/10.1111/jpn.13117

[35] Taylor, C. S. 1980. Genetic size-scaling rules in animal growth. Animal Production 30:161-165. https://doi.org/10.1017/S0003356100023941
» https://doi.org/10.1017/S0003356100023941

Ingredient	Basal diet
Ingredient	Summit diet (L6)	Dilution diet (L0)
Soybean meal (45%)	540.3
Corn	170.0
Corn gluten meal (60%)	165.0
Soybean oil	80.7	65.0
Dicalcium phosphate	19.0	27.0
Limestone	7.2	3.4
Salt	5.1	5.2
DL-methionine (99%)	4.5
L-lysine HCl (78%)	3.5
L-threonine (99%)	1.5
Vitamin supplement¹ 1 Vitamin mixture (content per kg of the supplement): vitamin A, 7,000,000 IU; vitamin D3, 2,200,000 IU; vitamin E, 11,000 mg; vitamin K3, 1,600 mg; vitamin B1, 2,000 mg; vitamin B2, 5,000 mg; vitamin B12, 12,000 µg; niacin, 35,000 mg; pantothenic acid, 13,000 mg; folic acid, 800 mg.	1.0	1.0
Choline chloride (70%)	0.7	0.7
Mineral supplement² 2 Mineral mixture (content per kg of the supplement): iron, 10,000 mg; copper, 16,000 mg; iodine, 2,400 mg; zinc, 100,000 mg; manganese, 140,000 mg; selenium, 400 mg.	1.0	1.0
Anticoccidial³ 3 Salinomycin sodium 12%.	0.5	0.5
Potassium chloride		12.8
Corn starch		595.0
Inert (Sand)		59.6
Rice husk		128.8
Sugar		100.0

Analysed composition	Experimental diet¹ 1 Diets formulated via the dilution technique by mixing summit (L6) and nitrogen-free (L0) diets in the respective proportions (%): L1 = 15:85, L2 = 32:68, L3 = 49:51, L4 = 66:34, L5 = 83:17, and L6 = 100:0. Calculated composition: calcium, 9.3 g kg−1; available phosphorus, 4.7 g kg−1; potassium, 10.6 g kg−1; and apparent metabolisable energy corrected for nitrogen, 13.2 MJ kg−1.
Analysed composition	L1	L2	L3	L4	L5	L6	L7² 2 The seventh treatment (L7) was obtained via the addition of 4 g of L-lysine HCl (78%) kg−1 of feed to a diet with a similar composition of L1 diet.
Crude protein	61.0	124.0	183.0	239.0	295.0	364.0	61.0
Digestible lysine	2.8	5.9	9.0	12.1	15.2	18.4	5.9
Digestible methionine + cystine	2.2	4.7	7.3	9.8	12.3	14.8	2.2
Digestible methionine	1.5	3.3	5.0	6.7	8.5	10.2	1.5
Digestible threonine	2.1	4.4	6.7	9.0	11.3	13.6	2.1
Digestible valine	2.3	5.0	7.6	10.3	12.9	15.5	2.3
Digestible tryptophan	0.5	1.1	1.7	2.4	3.0	3.6	0.5
Digestible arginine	3.2	6.7	10.3	13.9	17.4	21.0	3.2
Digestible leucine	5.4	11.5	17.6	23.7	29.8	35.8	5.4
Digestible phenylalanine	2.8	5.9	9.1	12.2	15.3	18.5	2.8
Digestible phenylalanine + tyrosine	4.8	10.2	15.6	21.1	26.5	31.9	4.8
Digestible glycine + serine	4.8	10.3	15.7	21.2	26.6	29.4	4.8
Digestible histidine	1.3	2.7	4.1	5.5	7.0	8.4	1.3
Digestible isoleucine	2.2	4.7	7.2	9.8	12.3	14.8	2.2

Variable	Lysine level² 2 Lysine levels were 2.76, 5.88, 8.99, 12.11, 15.23, 18.35, and 5.88 g kg−1 of diet (as fed) for L1 to L7, respectively.							P-value³ 3 Probability of significance: not significant (ns) for P>0.05; P<0.01; *P<0.001.
Variable	L1	L2	L3	L4	L5	L6	L7
Daily N balance data (period I, 6 to 21 days)
Mean body weight (g)⁴ 4 Average of two data collections per period.	261±42	348±62	381±63	405±63	402±60	417±65	254±41	ns
Feed intake (g d⁻¹)	32±3	48±6	45±6	49±5	48±5	47±5	40±5	ns
N intake (mg BW^0.67 kg⁻¹)	787±26	1941±18	2518±49	3493±30	4238±65	5043±73	1226±26	***
N excretion (mg BW^0.67 kg⁻¹)	225±15	475±46	741±67	1163±22	1622±67	2294±42	335±39	***
N deposition (mg BW^0.67 kg⁻¹)	562±28	1466±37	1777±31	2330±32	2616±61	2749±47	891±14	***
Lysine intake (mg BW^0.67 kg⁻¹)	246±19	637±26	859±52	1234±36	1531±69	1787±48	530±32	***
Daily N balance data (period II, 22 to 37 days)
Mean body weight (g)⁴	1211±98	1381±106	1490±98	1579±119	1420±119	1533±164	1201±122	ns
Feed intake (g d⁻¹)	105±4	113±5	111±3	113±4	106±4	106±5	114±2	ns
N intake (mg BW^0.67 kg⁻¹)	918±58	1826±73	2503±84	3193±28	4006±150	4652±48	1265±57	***
N excretion (mg BW^0.67 kg⁻¹)	324±30	669±77	812±18	1229±20	1834±144	2303±54	512±32	***
N deposition (mg BW^0.67 kg⁻¹)	594±36	1157±19	1691±68	1964±28	2172±11	2349±20	753±26	***
Lysine intake (mg BW^0.67 kg⁻¹)	287±24	599±69	855±21	1128±25	1447±121	1648±37	666±30	***
Daily N balance data (period III, 38 to 53 days)
Mean body weight (g)⁴	2902±97	3039±147	3166±117	3249±84	3198±95	3103±94	2874±118	ns
Feed intake (g d⁻¹)	131±4	156±5	155±3	150±4	155±4	147±5	133±2	**
N intake (mg BW^0.67 kg⁻¹)	625±20	1474±30	2102±56	2607±50	3363±99	4024±146	811±21	***
N excretion (mg BW^0.67 kg⁻¹)	261±18	575±35	789±39	1139±49	1647±73	2232±137	285±11	***
N deposition (mg BW^0.67 kg⁻¹)	364±14	899±26	1313±40	1468±19	1716±43	1792±32	526±13	***
Lysine intake (mg BW^0.67 kg⁻¹)	195±19	484±33	717±41	921±42	1215±32	1426±92	427±23	***

Variable	Lysine level² 2 Lysine levels were 2.76, 5.88, 8.99, 12.11, 15.23, 18.35, and 5.88 g kg−1 of diet (as fed) for L1 to L7, respectively.							P-value³ 3 Probability of significance: not significant (ns) for P>0.05; P<0.01; *P<0.001.
Variable	L1	L2	L3	L4	L5	L6	L7
Daily N balance data (period I, 6 to 21 days)
Mean body weight (g)⁴ 4 Average of two data collections per period.	254±38	312±53	342±56	373±52	383±62	363±45	270±40	ns
Feed intake (g d⁻¹)	36±4	46±6	47±5	45±4	49±5	47±4	40±4	ns
N intake (mg BW^0.67 kg⁻¹)	895±12	2025±29	2876±36	3379±31	4461±45	5409±43	1210±16	***
N excretion (mg BW^0.67 kg⁻¹)	241±17	573±33	763±28	1092±41	1801±48	2591±37	360±16	***
N deposition (mg BW^0.67 kg⁻¹)	654±19	1452±27	2113±40	2287±34	2660±35	2818±55	850±28	***
Lysine intake (mg BW^0.67 kg⁻¹)	280±14	665±27	982±34	1194±46	1612±40	1917±42	637±12	***
Daily N balance data (period II, 22 to 37 days)
Mean body weight (g)⁴ 4 Average of two data collections per period.	1192±83	1314±78	1398±87	1491±79	1381±81	1437±119	1235±114	ns
Feed intake (g d⁻¹)	103±2	109±3	109±2	112±2	108±6	112±5	106±3	ns
N intake (mg BW^0.67 kg⁻¹)	903±50	1806±39	2573±57	3282±64	4129±107	5121±81	1150±41	***
N excretion (mg BW^0.67 kg⁻¹)	304±18	574±23	871±15	1261±33	1903±99	2661±53	347±20	***
N deposition (mg BW^0.67 kg⁻¹)	599±33	1232±24	1702±50	2021±33	2226±35	2460±44	803±28	***
Lysine intake (mg BW^0.67 kg⁻¹)	282±22	593±26	878±20	1160±42	1492±54	1815±47	606±35	***
Daily N balance data (period III, 38 to 53 days)
Mean body weight (g)⁴ 4 Average of two data collections per period.	2270±108	2427±104	2589±96	2530±79	2530±78	2600±117	2342±113	ns
Feed intake (g d⁻¹)	123±4	138±5	139±3	137±4	138±3	133±6	146±3	**
N intake (mg BW^0.67 kg⁻¹)	693±19	1517±29	2153±61	2819±86	3510±83	4080±110	1023±36	***
N excretion (mg BW^0.67 kg⁻¹)	292±15	554±32	897±59	1264±77	1890±86	2319±118	311±10	***
N deposition (mg BW^0.67 kg⁻¹)	401±15	963±26	1256±28	1555±33	1620±35	1761±43	712±26	***
Lysine intake (mg BW^0.67 kg⁻¹)	217±12	498±29	735±47	996±52	1268±37	1446±41	539±22	***

Adjusted model¹ 1 Adjusted models: Ω = unrestricted exponential model, in which the two parameters (LMR and b) were adjusted to males and females; ω1 = restricted exponential model, in which the LMR parameter was common to males and females (H0:LMRgeneral=LMRmale=LMRfemale); ω2 = restricted exponential model, in which the b parameter was common to males and females (H0:bgeneral=bmale=bfemale); ω3 = restricted exponential model, in which the LMR and b parameters were common to males and females (H0:LMRgeneral=LMRmale=LMRfemale and bgeneral=bmale=bfemale).	Exponential model parameter						Statistics
	Males		Females		Males and females		Statistics
	LMR_males	b _males	LMR_females	b _females	LMR_general	b _general	P-value^† † Probability of significance for the hypothesis tested (H0 vs. H1): not significant (ns) for P>0.05; *P<0.05.
Period I, 6 to 21 days
Ω	9.3±0.6	0.00263±0.00004	9.4±0.6	0.00252±0.00003
ω₁		0.00262±0.00003		0.00252±0.00003	9.4±0.4		ns
ω₂	10.5±0.4		8.7±0.4			0.00256±0.00003	ns
ω₃					10.1±0.4	0.00252±0.00003	ns
Period II, 22 to 37 days
Ω	33.4±0.6	0.00210±0.00004	30.0±0.5	0.00205±0.00003
ω₁		0.00214±0.00003		0.00202±0.00002	31.5±0.4		ns
ω₂	35.0±0.4		29.0±0.4			0.00207±0.00002	ns
ω₃					32.7±0.4	0.00204±0.00002	*
Period III, 38 to 53 days
Ω	40.2±0.6	0.00221±0.00004	39.4±0.6	0.00228±0.00004
ω₁		0.00222±0.00003		0.00227±0.00003	39.8±0.4		ns
ω₂	38.5±0.4		41.6±0.4			0.00224±0.00003	ns
ω₃					38.9±0.4	0.00226±0.00003	*