Application of a precision nutrition tool for growing and finishing pigs

Lovato, Gustavo Dias; Vale, Marcos Martinez do; Oliveira, Vladimir de; Klein, Daniela Regina; Branco, Tatiane

doi:10.1590/S1806-92902017000900007

ABSTRACT

The objective of this study was to evaluate a growth model applied to adjust nutritional programs for growing and finishing pigs, in a commercial production context. The phase I (calibration) was conducted in a commercial pig production unit. The data were collected from a nutritional program, a feed program, and an animal profile. In experimental phase II, these data were entered in the InraPorc^® model for simulations and to propose adjustments to the commercial nutritional program. Afterwards, the conventional nutritional program (CNP) and the adjusted nutritional program (ANP) were compared with InraPorc^® simulation. Animal profile was collected by weighing 30% of pigs per stall and monitoring their feed intake in each stage. Four hundred and thirty-two pigs with an average initial body weight of 21.9 kg were used in a completely randomized design. There were no differences between treatments, the pig performance was affected by temperature conditions, and the fat thickness was 8% higher for CNP than ANP. In conclusion, the model has advantages to adjust growing and finishing pig nutrition programs and improve environmental and economic aspects.

Key Words:
InraPorc^®; modeling; pig production; temperature

Introduction

Precision nutrition is a relevant concept in livestock production that uses different tools and management processes aiming to reduce losses, increase the product quality (Nääs, 2011Nääs, I. A. 2011. Uso de técnicas de precisão na produção animal. Revista Brasileira de Zootecnia 40(supl. especial):358-364.; Pomar et al., 2009Pomar, C.; Hauschild, L.; Zhang, G.-H.; Pomar, J. and Lovatto, P. A. 2009. Applying precision feeding techniques in growing-finishing pig operations. Revista Brasileira de Zootecnia 38(supl. especial):226-237.), reduce uncertainties in decisions, and optimize available resources (Mollo et al., 2009Mollo, M.; Vendrametto, O. and Okano, M. 2009. Precision livestock tools to improve products and processes in broiler production: a review. Revista Brasileira de Ciência Avícola 11:211-218.). The dynamic use of nutrients and the animal response in different production scenarios require a nutrient supply according to the diversity and purposes of production systems, aiming to improve efficiency (Pomar et al., 2009Pomar, C.; Hauschild, L.; Zhang, G.-H.; Pomar, J. and Lovatto, P. A. 2009. Applying precision feeding techniques in growing-finishing pig operations. Revista Brasileira de Zootecnia 38(supl. especial):226-237.).

The InraPorc^® is a precision nutrition tool (Van Milgen et al., 2008Van Milgen, J.; Valancogne, A.; Dubois, S.; Dourmad, J. Y.; Sève, B. and Noblet, J. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Animal Feed Science and Technology 143:387-405.). This model integrates a dynamic, mechanistic, and deterministic approach through different aspects related to nutrition, feeding, genetics, environment, and animal behavior, serving as a decision system for the nutritional adjustment of pigs (Van Milgen et al., 2008Van Milgen, J.; Valancogne, A.; Dubois, S.; Dourmad, J. Y.; Sève, B. and Noblet, J. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Animal Feed Science and Technology 143:387-405.). InraPorc^® estimates nutritional requirements and animal growth, considering the variation among animals, providing greater accuracy in nutrient supply (Quiniou et al., 2009Quiniou, N.; Allain, C. and Vautier, A. 2009. Evaluation zootechnique d'une stratégie alimentaire biphase établie via le logiciel InraPorc® et appliquée sur des porcs issus de verrats Pietrain ou Large White × Piétrain. Journées Recherche Porcine 41:101-108.; Brossard et al., 2010Brossard, L.; Quiniou, N.; Dourmad, J.; Salaün, Y. and Van Milgen, J. 2010. Définir des stratégies alimentaires alliant performance économique et impact environnemental grâce à la modélisation du groupe de porcs en croissance. Journées Recherche Porcine 42:131-132.) and reducing the inclusion of essential amino acids and energy in the diet, reducing diet elaboration costs (Rossi et al., 2013Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.).

The definition of pig nutritional programs in commercial production is guided by recommendations, in which differences between production systems consider a generic form (Rostagno et al., 2005Rostagno, H. S.; Albino, L. F. T. and Donzele, J. L. 2005. Tabelas brasileiras para aves e suínos; composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG.; 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. Editora UFV, Viçosa, MG.), generating situations of over- or undernutrition. The objective of this study was to evaluate a growth model applied to adjust nutritional programs for growing and finishing pigs, in a commercial production context.

Material and Methods

This study was conducted in accordance with ethical standards, in a commercial production unit in two experimental phases.

During the phase I, from November 2011 to January 2012, the data were collected to calibrate the InraPorc^® model to estimate the nutritional requirements. The pigs were a mixed group of 432 animals (barrows and gilts), from an industrial crossbreeding between AGPIC 337 males and Camborough 25 females from Agroceres PIC. Pigs were housed in a conventional shed with 16 stalls and 27 animals each, receiving water and feed ad libitum, using commercial company nutritional programs and nutritional composition calculated according to food composition tables (CNP) of Rostagno et al. (2011)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. Editora UFV, Viçosa, MG.. The collected data were production data [age (days), feed intake (kg), and body weight (kg)] from a sampling of 30% of animals per stall. Pigs and feed were weighted at the end of each phase and daily gain, feed intake, feed conversion, and daily gain were calculated. Also, average, maximum, and minimum daily temperatures were registered.

In the experimental phase II, between March and June of 2012, we compared two nutritional programs: the conventional commercial nutrition program (CNP) and the adjusted nutritional program using the InraPorc^® model (ANP), applying the animal profile from experimental phase I (Table 1). The 432 animals were a mixed group (barrows and gilts) with the same crossbreeding used in phase I. The pigs received water and feed ad libitum. Production data [age (days), feed intake (kg), and body weight (kg)] were collected from a sampling of 30% of animals per stall. Pigs and feed were weighted at the end of each phase to calculate daily gain, feed intake, feed conversion, and daily gain. Average, maximum, and minimum temperatures were registered daily.

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Table 1
Ingredients and nutritional composition of diets in the experimental phases I and II

At the end of the experimental phases I and II, the animals were fasted for 10 h before being transported. Eight pigs were selected randomly per pen before the transport and identified for carcass evaluations. The animals were stunned electrically and bled. After slaughter and evisceration, the hot carcass weight was obtained and the carcass was cooled at 2 °C for 24 h, to obtain cold carcass weight. After this period, carcasses were weighed again to obtain cold carcass weight. Carcass length was measured on left half carcass, from the cranial edge of the pubis symphysis to the cranioventral edge of the atlas. The fat thickness was measured, in the same half carcass, perpendicular to the midline at the last rib. Carcass dressing percentage was estimated by the following equation: CY (%) = [(CCW/BWf) × 100], in which CY = carcass yield, CCW = cold carcass weight (kg), and BWf = final body weight (kg).

The statistical procedure was the MIXED model of SAS (Statistical Analysis System, version 9.0) with fixed effects of nutritional programs and feeding stages (except for carcass traits). A structure selection test was conducted using Bayesian information criterion to determine the best model. Whenever differences were observed, means between nutritional programs and feeding stages were compared using the LSMEANS procedure. Nutritional program × feeding stage interaction was decomposed when significant at the 5% probability level. The estimated values of pig performance obtained by the model were compared with the observed means to evaluate the model accuracy and predict the performance with the t test at the 5% probability level, in which insignificant differences represented adequate model accuracy.

Results

No differences were found (P>0.05) (Table 2) among treatments for the performance variables.

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Table 2
Performance of pig with conventional nutritional program (CNP) and adjusted nutritional program through InraPorc^® model (ANP) during grower and finisher phases

Different temperatures were observed during the experimental phases I and II, which can have influence on the performance of CNP and ANP (Table 3).

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Table 3
Average temperatures observed during experimental phases I and II

The pig performances were similar between the models ANP and CNP (Table 4); however, the model had an adequate accuracy to estimate average body weight in growth stage 1 (grower 1) (P>0.05).

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Table 4
Differences¹ 1 Significantly different by the t test. observed between phase I and phase II diets

The nutritional programs did not influence (P>0.05) the carcass analysis, except for the fat thickness of the pigs fed ANP, which was 1.6 mm lower (P<0.05) as compared with treatment CNP (Table 5).

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Table 5
Carcass traits of pig feed with conventional nutritional program (CNP) in phase I and adjusted nutritional program by InraPorc^® model (ANP) in phase II

Discussion

No differences between treatments agree with other researchers who used the InraPorc^® model as a tool to adjust nutritional programs (Quiniou et al., 2009Quiniou, N.; Allain, C. and Vautier, A. 2009. Evaluation zootechnique d'une stratégie alimentaire biphase établie via le logiciel InraPorc® et appliquée sur des porcs issus de verrats Pietrain ou Large White × Piétrain. Journées Recherche Porcine 41:101-108.; Rossi et al., 2013Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.).

Differences between the observed values and the values estimated by the model for body weight and body weight gain is explained by the fact that average daily feed intake has significant differences in finisher 1 and finisher 2 stages (P<0.01). The variation in feed intake can be attributed to the different environmental conditions between the experimental phases I and II. High environmental temperatures reduce voluntary feed intake in pigs during heat stress (Quiniou et al., 2001Quiniou,N.; Noblet, J.; van Milgen, J. and Dubois, S. 2001. Modelling heat production and energy balance in group-housed growing pigs exposed to low or high ambient temperatures. British Journal of Nutrition 85:97-106.; Huynh et al., 2005Huynh, T. T. T.; Aarnink, A. J. A.; Gerrits, W. J. J.; Heetkamp, M. J. H.; Canh, T. T.; Spoolder, H. A. M.; Kemp, B. and Verstegen, M. W. A. 2005. Thermal behaviour of growing pigs in response to high temperature and humidity. Applied Animal Behaviour Science 91:1-16.; Kiefer et al., 2010Kiefer, C.; Moura, M. S.; Silva, E. A.; Santos, A. P.; Silva, C. M.; Luz, M. F. and Nantes, C. L. 2010. Respostas de suínos em terminação mantidos em diferentes ambientes térmicos. Revista Brasileira de Saúde e Produção Animal 11:496-504.; Batista et al., 2011Batista, R. M.; Oliveira, R. F. M.; Donzele, J. L.; Oliveira, W. P.; Lima, A. L. and Abreu, M. L. T. 2011. Lisina digestível para suínos machos castrados de alta deposição de carne submetidos a estresse por calor dos 30 aos 60 kg. Revista Brasileira de Zootecnia 40:1925-1932.) because the intake mechanisms are regulated for the short and long-term processes, which influence the partition of energy between maintenance and deposition (Hauschild et al., 2010Hauschild, L.; Pomar, C. and Lovatto, P. A. 2010. Systematic comparison of the empirical and factorial methods used to estimate the nutrient requirements of growing pigs. Animal 4:714-723.; Batista et al., 2011Batista, R. M.; Oliveira, R. F. M.; Donzele, J. L.; Oliveira, W. P.; Lima, A. L. and Abreu, M. L. T. 2011. Lisina digestível para suínos machos castrados de alta deposição de carne submetidos a estresse por calor dos 30 aos 60 kg. Revista Brasileira de Zootecnia 40:1925-1932.; Hauschild et al., 2012Hauschild, L.; Lovatto, P. A.; Pomar, J. and Pomar, C. 2012. Development of sustainable precision farming systems for swine: Estimating realtime individual amino acid requirements in growing-finishing pigs. Journal of Animal Science 90:2255-2263.; Rossi et al., 2013Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.; Warpechowski et al., 2014Warpechowski, M. B.; Brossard, L.; Hauptli, L.; Pierozan, E. A.; Quadros, J. A.; Muchalak, D. N. and Machado, M. F. 2014. Evaluation du modèle nutritionnel InraPorc pour un système de finition de porcs lourds du sud du Brésil. Journées Recherche Porcine 46:133-134.). The InraPorc^® deterministic model characterizes the pig in thermal comfort, in heat stress, or under other factors that influence the voluntary feed intake (Van Milgen et al., 2008Van Milgen, J.; Valancogne, A.; Dubois, S.; Dourmad, J. Y.; Sève, B. and Noblet, J. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Animal Feed Science and Technology 143:387-405.; Hauschild et al., 2012Hauschild, L.; Lovatto, P. A.; Pomar, J. and Pomar, C. 2012. Development of sustainable precision farming systems for swine: Estimating realtime individual amino acid requirements in growing-finishing pigs. Journal of Animal Science 90:2255-2263.; Rossi et al., 2013Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.), but does not consider environmental effects directly. However, if the animal profile is adjusted in specific climatic conditions, its requirements and the nutritional adjustment are more accurate.

Analyzing the carcass, nutritional programs only affect fat thickness, indicating efficient adjustment of dietary nutrients, despite the influence of temperature on feed intake; similar results were found by Quiniou et al. (2009)Quiniou, N.; Allain, C. and Vautier, A. 2009. Evaluation zootechnique d'une stratégie alimentaire biphase établie via le logiciel InraPorc® et appliquée sur des porcs issus de verrats Pietrain ou Large White × Piétrain. Journées Recherche Porcine 41:101-108..

The use of a precision tool, such as the InraPorc^® model, can alter the feed formulation, improving environmental and economic aspects. Further studies related to the response of pigs to temperature, in similar production systems to this study, are needed to improve the ability and accuracy of growth models. This requires establishing a methodology to enter the animal profile information to be used in the parameterization of the growth model in studied situations.

Conclusions

Pig performance is not affected with adjusted nutritional programs for growing and finishing pigs, but the adjusted nutritional program is adequate to estimate average body weight in grower phase and decrease fat thickness. The model has advantages to adjust growing and finishing pig nutrition programs and improve environmental and economic aspects.

Acknowledgments

We acknowledge the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for providing scholarships and Dr. Paulo Alberto Lovatto (in memoriam) for the teachings and incentive for the accomplishment of this work.

References

Batista, R. M.; Oliveira, R. F. M.; Donzele, J. L.; Oliveira, W. P.; Lima, A. L. and Abreu, M. L. T. 2011. Lisina digestível para suínos machos castrados de alta deposição de carne submetidos a estresse por calor dos 30 aos 60 kg. Revista Brasileira de Zootecnia 40:1925-1932.
Brossard, L.; Quiniou, N.; Dourmad, J.; Salaün, Y. and Van Milgen, J. 2010. Définir des stratégies alimentaires alliant performance économique et impact environnemental grâce à la modélisation du groupe de porcs en croissance. Journées Recherche Porcine 42:131-132.
Hauschild, L.; Lovatto, P. A.; Pomar, J. and Pomar, C. 2012. Development of sustainable precision farming systems for swine: Estimating realtime individual amino acid requirements in growing-finishing pigs. Journal of Animal Science 90:2255-2263.
Hauschild, L.; Pomar, C. and Lovatto, P. A. 2010. Systematic comparison of the empirical and factorial methods used to estimate the nutrient requirements of growing pigs. Animal 4:714-723.
Huynh, T. T. T.; Aarnink, A. J. A.; Gerrits, W. J. J.; Heetkamp, M. J. H.; Canh, T. T.; Spoolder, H. A. M.; Kemp, B. and Verstegen, M. W. A. 2005. Thermal behaviour of growing pigs in response to high temperature and humidity. Applied Animal Behaviour Science 91:1-16.
Kiefer, C.; Moura, M. S.; Silva, E. A.; Santos, A. P.; Silva, C. M.; Luz, M. F. and Nantes, C. L. 2010. Respostas de suínos em terminação mantidos em diferentes ambientes térmicos. Revista Brasileira de Saúde e Produção Animal 11:496-504.
Mollo, M.; Vendrametto, O. and Okano, M. 2009. Precision livestock tools to improve products and processes in broiler production: a review. Revista Brasileira de Ciência Avícola 11:211-218.
Nääs, I. A. 2011. Uso de técnicas de precisão na produção animal. Revista Brasileira de Zootecnia 40(supl. especial):358-364.
Pomar, C.; Hauschild, L.; Zhang, G.-H.; Pomar, J. and Lovatto, P. A. 2009. Applying precision feeding techniques in growing-finishing pig operations. Revista Brasileira de Zootecnia 38(supl. especial):226-237.
Quiniou,N.; Noblet, J.; van Milgen, J. and Dubois, S. 2001. Modelling heat production and energy balance in group-housed growing pigs exposed to low or high ambient temperatures. British Journal of Nutrition 85:97-106.
Quiniou, N.; Allain, C. and Vautier, A. 2009. Evaluation zootechnique d'une stratégie alimentaire biphase établie via le logiciel InraPorc^® et appliquée sur des porcs issus de verrats Pietrain ou Large White × Piétrain. Journées Recherche Porcine 41:101-108.
Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.
Rostagno, H. S.; Albino, L. F. T. and Donzele, J. L. 2005. Tabelas brasileiras para aves e suínos; composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG.
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. Editora UFV, Viçosa, MG.
Van Milgen, J.; Valancogne, A.; Dubois, S.; Dourmad, J. Y.; Sève, B. and Noblet, J. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Animal Feed Science and Technology 143:387-405.
Warpechowski, M. B.; Brossard, L.; Hauptli, L.; Pierozan, E. A.; Quadros, J. A.; Muchalak, D. N. and Machado, M. F. 2014. Evaluation du modèle nutritionnel InraPorc pour un système de finition de porcs lourds du sud du Brésil. Journées Recherche Porcine 46:133-134.

Publication Dates

Publication in this collection
Sept 2017

History

Received
29 Aug 2016
Accepted
26 June 2017

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] Batista, R. M.; Oliveira, R. F. M.; Donzele, J. L.; Oliveira, W. P.; Lima, A. L. and Abreu, M. L. T. 2011. Lisina digestível para suínos machos castrados de alta deposição de carne submetidos a estresse por calor dos 30 aos 60 kg. Revista Brasileira de Zootecnia 40:1925-1932.

[2] Brossard, L.; Quiniou, N.; Dourmad, J.; Salaün, Y. and Van Milgen, J. 2010. Définir des stratégies alimentaires alliant performance économique et impact environnemental grâce à la modélisation du groupe de porcs en croissance. Journées Recherche Porcine 42:131-132.

[3] Hauschild, L.; Lovatto, P. A.; Pomar, J. and Pomar, C. 2012. Development of sustainable precision farming systems for swine: Estimating realtime individual amino acid requirements in growing-finishing pigs. Journal of Animal Science 90:2255-2263.

[4] Hauschild, L.; Pomar, C. and Lovatto, P. A. 2010. Systematic comparison of the empirical and factorial methods used to estimate the nutrient requirements of growing pigs. Animal 4:714-723.

[5] Huynh, T. T. T.; Aarnink, A. J. A.; Gerrits, W. J. J.; Heetkamp, M. J. H.; Canh, T. T.; Spoolder, H. A. M.; Kemp, B. and Verstegen, M. W. A. 2005. Thermal behaviour of growing pigs in response to high temperature and humidity. Applied Animal Behaviour Science 91:1-16.

[6] Kiefer, C.; Moura, M. S.; Silva, E. A.; Santos, A. P.; Silva, C. M.; Luz, M. F. and Nantes, C. L. 2010. Respostas de suínos em terminação mantidos em diferentes ambientes térmicos. Revista Brasileira de Saúde e Produção Animal 11:496-504.

[7] Mollo, M.; Vendrametto, O. and Okano, M. 2009. Precision livestock tools to improve products and processes in broiler production: a review. Revista Brasileira de Ciência Avícola 11:211-218.

[8] Nääs, I. A. 2011. Uso de técnicas de precisão na produção animal. Revista Brasileira de Zootecnia 40(supl. especial):358-364.

[9] Pomar, C.; Hauschild, L.; Zhang, G.-H.; Pomar, J. and Lovatto, P. A. 2009. Applying precision feeding techniques in growing-finishing pig operations. Revista Brasileira de Zootecnia 38(supl. especial):226-237.

[10] Quiniou,N.; Noblet, J.; van Milgen, J. and Dubois, S. 2001. Modelling heat production and energy balance in group-housed growing pigs exposed to low or high ambient temperatures. British Journal of Nutrition 85:97-106.

[11] Quiniou, N.; Allain, C. and Vautier, A. 2009. Evaluation zootechnique d'une stratégie alimentaire biphase établie via le logiciel InraPorc^® et appliquée sur des porcs issus de verrats Pietrain ou Large White × Piétrain. Journées Recherche Porcine 41:101-108.

[12] Rossi, C. A. R.; Lovatto, P. A.; Lehnen, C. R.; Fraga, C. N.; Lovato, C. D. and Ceron, M. S. 2013. Dietas ajustadas para suínos através do modelo InraPorc®: desempenho, características de carcaça e impacto econômico. Ciência Rural 43:689-695.

[13] Rostagno, H. S.; Albino, L. F. T. and Donzele, J. L. 2005. Tabelas brasileiras para aves e suínos; composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG.

[14] 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. Editora UFV, Viçosa, MG.

[15] Van Milgen, J.; Valancogne, A.; Dubois, S.; Dourmad, J. Y.; Sève, B. and Noblet, J. 2008. InraPorc: A model and decision support tool for the nutrition of growing pigs. Animal Feed Science and Technology 143:387-405.

[16] Warpechowski, M. B.; Brossard, L.; Hauptli, L.; Pierozan, E. A.; Quadros, J. A.; Muchalak, D. N. and Machado, M. F. 2014. Evaluation du modèle nutritionnel InraPorc pour un système de finition de porcs lourds du sud du Brésil. Journées Recherche Porcine 46:133-134.

		Starter (63 to 72 days)		Grower 1 (73 to 91 days)		Grower 2 (92 to 106 days)		Finisher 1 (107 to 121 days)		Finisher 2 (122 to 156 days)
		CNP	ANP	CNP	ANP	CNP	ANP	CNP	ANP	CNP	ANP
Ingredient (g/kg as fed)
	Corn	395.2	439.2	553.2	436.2	621.2	561.2	631.2	612.2	516.9	557.9
	Soybean meal	280	273	260	260	233	225	217	212	231	205
	Broken rice	250	225	100	130	60	93	–	80	80	117
	Rice bran	–	30	–	125	–	83	70	55	90	95
	Meat and bone meal	23	16	40	24	40	20	37	19	38	4
	Soybean oil	26	–	28	9	28	–	26	2	25	2
	Limestone	9.0	7.0	4.5	6.0	4.2	6.0	5.5	8.0	5.0	7.7
	Salt	4.0	4.1	3.9	3.7	4.0	4.1	3.8	4.0	3.9	4.0
	L-lysine HCl	6.0	1.7	4.0	1.7	4.0	3.0	4.0	3.0	3.9	2.9
	DL-methionine	1.4	–	1.3	0.3	1.1	0.6	1.2	0.8	1.3	0.4
	L-treonine	1.4	–	1.3	0.3	0.9	0.5	1.0	0.7	1.2	0.3
	Mineral vitamin¹ 1 Supplied per kg: 55,000 mg Fe; 85,000 mg Cu; 20,000 mg Mn; 250 mg Co; 500 mg I; 150 mg Se; 42,000 mg Zn; 5,000,000 IU vitamin A; 1,300,000 IU vitamin D3; 15,000 IU vitamin E; 1,500 mg vitamin K3; 800 mg vitamin B1; 3,000 mg vitamin B2; 1,200 mg vitamin B6; 15,000 mcg vitamin B12; 250 mg folic acid; 7,000 mg pantothenic acid; 15,000 mg niacin; phytase (50 g/ton of feed) with activity of 10,000 FTU/g.	4.0	4.0	3.8	3.8	3.6	3.6	3.3	3.3	3.5	3.5
	Ractopamine	–	–	–	–	–	–	–	–	0.25	0.25
Calculated composition (g/kg)
	Dry matter	897.0	885.0	892.0	907.0	896.0	911.0	904.0	892.0	902.0	887.0
	Metabolizable energy (ME; kcal/kg)	3,319	3,224	3,343	3,224	3,343	3,200	3,295	3,200	3,295	3,176
	Crude protein	198.0	194.0	198.0	197.0	188.0	181.0	184.0	175.0	191.0	170.0
	Lysine² 2 True ileal digestible amino acid.	11.4	9.7	10.3	9.3	9.7	8.9	9.4	8.6	9.8	8.2
	Lysine:ME (g/kcal)	257.90	229.25	231.64	217.31	217.31	210.14	212.53	200.59	222.08	193.43
	Methionine + cystine² 2 True ileal digestible amino acid.	6.6	5.5	6.4	5.7	6.0	5.6	5.9	5.6	6.2	5.2
	Methionine² 2 True ileal digestible amino acid.	3.8	2.7	3.7	2.9	3.4	3.0	3.4	3.1	3.6	2.6
	Cystine² 2 True ileal digestible amino acid.	2.7	2.8	2.7	2.7	2.6	2.6	2.4	2.5	2.6	2.5
	Treonine² 2 True ileal digestible amino acid.	7.2	6.0	7.0	6.3	6.5	6.0	6.5	6.0	6.8	5.4
	Calcium	7.9	6.1	7.4	6.5	7.4	6.0	7.4	6.6	7.4	5.1
	Total phosphorus	5.5	4.9	5.6	6.5	5.5	5.7	6.3	5.3	6.6	5.4
	Digestible phosphorus² 2 True ileal digestible amino acid.	3.7	2.8	3.9	3.4	3.9	3.1	3.9	3.0	4.0	2.4

Variable	Nutritional program		SME	P-value¹ 1 Probability at 5% of significance.
Variable	CNP	ANP	SME	P-value¹ 1 Probability at 5% of significance.
Initial body weight (kg)	21.90	21.80	0.490	0.97
	63 to 72 days
Body weight (kg)	29.20	29.10	0.399	0.99
ADFI (kg/day)	1.25	1.21	0.091	0.42
ADG (kg/day)	0.80	0.81	0.093	0.98
F:G (kg/kg)	1.58	1.52	0.112	0.55
	73 to 91 days
Body weight (kg)	48.40	47.70	0.888	0.36
ADFI (kg/day)	1.94	1.91	0.056	0.58
ADG (kg/day)	1.07	1.03	0.051	0.39
F:G (kg/kg)	1.82	1.87	0.063	0.45
	92 to 106 days
Body weight (kg)	67.40	67.10	0.702	0.61
ADFI (kg/day)	2.39	2.48	0.053	0.11
ADG (kg/day)	1.27	1.29	0.072	0.68
F:G (kg/kg)	1.91	1.92	0.087	0.83
	107 to 121 days
Body weight (kg)	91.80	91.30	1.468	0.73
ADFI (kg/day)	2.84	2.87	0.083	0.71
ADG (kg/day)	1.28	1.27	0.068	0.91
F:G (kg/kg)	2.23	2.27	0.103	0.63
	122 to 156 days
Body weight (kg)	121.60	120.90	1.409	0.33
ADFI (kg/day)	2.99	2.98	0.063	0.86
ADG (kg/day)	0.93	0.90	0.043	0.48
F:G (kg/kg)	3.23	3.35	0.181	0.51

Temperature (°C)	Phase I	Phase II
Minimum	19.2	13.5
Average	25.6	19.5
Maximum	32.1	25.6

Variable² 2 At the end of phase.	Starter (63 to72 days)	Grower 1 (73 to 91 days)	Grower 2 (92 to 106 days)	Finisher 1 (107 to 121 days)	Finisher 2 (122 to 156 days)
BW (kg)	–0 99^* ***** P<0.001.	–0.27	3.39^* ***** P<0.001.	5.32^ P<0.01.	3.65^* * P<0.05.
ADFI (kg/day)	–0.04	–0.08	0.01	0.21^ P<0.01.	0.26^ P<0.01.
ADG (kg/day)	–0.06^ P<0.01.	–0.01	0.07^ P<0.01.	0.08^ P<0.01.	–0.01

Variable	Nutritional program		SEM	P-value¹ 1 Probability at 5% of significance.
Variable	CNP	ANP	SEM	P-value¹ 1 Probability at 5% of significance.
Hot carcass weight (kg)	89.50	88.60	1.56	0.57
Cold carcass weight (kg)	87.10	86.20	1.45	0.55
Losses during cooling (kg)	2.37	2.35	0.24	0.93
Carcass yield (%)	72.00	72.10	1.09	0.91
Carcass length (cm)	98.90	98.50	0.72	0.62
Fat thickness (mm)	20.50	18.90	3.44	0.04^* * Significantly different at P<0.05.