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Metabolizable Energy Levels for Meat-Type Quails at Starter Phase

ABSTRACT

This experiment was conducted to evaluate the effects of dietary nitrogen-corrected apparent metabolizable energy (AMEn) levels on meat-type quail performance and carcass traits from 1 to 14d of age. A total of 1120 not sexed meat-type quails were randomly distributed to seven treatments, with eight replicates with 20 quails each. A basal corn and soybean meal-based diet was formulated to meet or exceed quail nutritional requirements, except for ME. Graded levels of soybean oil were added to the basal diet in replacement, to sand, to obtain dietary treatments (2,600; 2,700; 2,800; 2,900; 3,000; 3,100 and 3,200 KcalAMEn/kg diet). Data were analyzed as one-way ANOVA and optimum AMEn levels were estimated using polynomial regression model. Increasing in dietary AMEn levels elicited a linear decrease (p<0.01) in feed intake and nutrient intake (AMEn, protein and lysine). Quail weight gain and final body weight exhibited a quadratic response (p<0.03) to increased AMEn levels, being both optimized at 2820 KcalAMEn/kg diet. Graded AMEn levels elicited a linear increase (p<0.01) in carcass dry matter and fat content, whereas moisture content was linearly decreased (p<0.01). The protein content of the carcasses was not influenced (p>0.05) by AMEn. Based on the results, the dietary AMEn level that warrants adequate performance and carcass traits of meat-type quails from 1 to 14d of age is 2,820 Kcal/kg diet.

Keywords:
Carcass traits; Coturnix coturnix coturnix; performance

INTRODUCTION

In the past, the commercialization of quail meat in Brazil was restricted to the slaughter of male and female Japanese quails, which due to age, had their fertility reduced and therefore, were no longer useful to reproduction. In general, the carcasses had a small size and the meat a poor quality, mainly regarding tenderness. However, over the last years, this scenario has changed due to the introduction of meat-type quails in the Brazilian market. Despite the increasing in meat-type quail production, little research efforts have been put forward on establishing meat-type quail nutritional requirements.

Nutrition is well acknowledged as the major input in production cost, and energy represents the most costly nutrient in poultry diets. Thus, in order to optimize feeding programs, knowing the energy content of feedstuffs as well as establishing the ideal energy intake for poultry is essential to warrant the maximum economic returns (Suida et al., 2001). In general, quail diet formulation is guided by nutritional recommendations from other countries such as NRC (1994) e INRA (1999) recommendations. Despite useful, such literature does not contain recommendations for meat-type quail, but rather for broilers, turkeys and hens (Barreto et al., 2006), which do not allow formulating diets for meat-type quails (Furlan et al., 1996).

Comparing research findings obtained with meat-type quails is difficult since the most part of published literature refers to Japanese quail nutrition (Barreto et al., 2006). Moreover, few information on meat-type quail requirement in the initial (from 1d to 14d) and growing-finishing phase (from 15d to 35d), in separate, are found in literature. The conduction of trials to establish quail nutrient needs is crucial to update the existing tables of quail nutritional requirements. Thus, this study was conducted to estimate the AMEn level for optimum meat-type quail performance and carcass trait in the starter phase.

MATERIALS AND METHODS

All the procedures adopted in this study, involving animal care and use, were previously approved by the Ethics Animal Care and Use Committee of the Universidade Federal de Viçosa (protocol no. 37/2012), which is consistent with the ethical principles of animal experimentation established by the Brazilian College of Animal Experimentation (COBEA, 1991).

Animal husbandry, experimental design, and diets

One-day-old meat-type quails, vaccinated for Marek disease were obtained from a local commercial hatchery and housed in curtain sided room thermally controlled. A total of one thousand one hundred twenty quails (average body weight 9.53g), was randomly assigned into fifty-six 50×50×5 cm (width×length×height) stain-less steel cages placed over a masonry countertop (120 cm height), previously covered by wood shavings. Each cage was equipped with one incandescent light, one nipple drinker and one trough feeder, where twenty quails were allotted. A basal diet, based on corn and soybean meal, was formulated to meet or exceed Silva & Costa (2009Silva JHV, Costa FGP. Tabela de exigência nutricional de codornas japonesas e europeias. 2nd ed. Jaboticabal: Fundação de Apoio à Pesquisa, Ensino e Extensão; 2009.). Nutritional composition of feedstuffs used in experimental diets corresponded to those described by Rostagno (2011Rostagno HS, Albino LFT, Donzele JL, Gomes PC, Oliveira RF, Lopes DC, et al. Tabelas brasileiras para aves e suínos. composição de alimentos e exigências nutricionais. 3rd ed. Viçosa: Editora UFV; 2011.). Experimental treatments (Table 1) consisted of seven levels of metabolizable energy (2.600, 2.700, 2.800, 2.900, 3.000, 3.100 and 3.200 kcal/kg), which were obtained through graded replacement of sand, by soybean oil. Throughout the feeding trial birds had free access to water and feed. Lighting program consisted of 24 h of light (natural + artificial). The minimum and maximum average daily room temperatures recorded throughout the experiment were 25.30 ± 1.2 and 37.63 ± 2.8, respectively.

Table 1
Composition of experimental diets.

Performance and carcass trait measurements

At 14 d of age, birds and feeders were weighed to obtain feed intake (g) and body weight (g). Weight gain (g) was obtained by the difference between the average of the final and initial body weight, whereas feed conversion (g/g) were calculated through the division between feed intake and weight gain. The intake of AMEn (kcal), crude protein (g) and lysine (g) were calculated by multiplying feed intake by the respective concentrations of the afore mentioned nutrients in diets. Mortality was daily recorded to adjust feed intake and feed conversion. After weighing birds and feeders, two birds were selected according to body weight for further carcass trait measurements. After four hours of feed withdrawal period, the selected birds were humanely slaughtered by cervical dislocation between the atlas and the occipital bone. After the slaughter, birds were immediately frozen. Then, frozen samples were ground in an industrial meat grinder, lyophilized and stored for further analyses of carcass composition, according to Silva & Queiroz (2004Silva DJ, Queiroz ACD. Análises de alimentos: métodos químicos e biológicos. 3rd ed. Viçosa: Editora UFV; 2004.).

Statistical analysis

Data were analyzed by one-way ANOVA using Sistema para Análises Estatísticas (SAEG, 2007) software package. Ideal AMEn level for performance data assessed was estimated by polynomial (linear or quadratic) regression model. Significant effects were considered when p≤0.05.

RESULTS AND DISCUSSION

Feed intake exhibited a linear decrease (p<0.05) as dietary AMEn levels increased, showing a reduction by 7.50 g for every increase in 100 kcal in AMEn (Table 2). These results support those found by Reis (2010), Ton (2011Ton APS, Furlan AC, Martins EN, Toledo JB, Scherer C, Conti ACM. Exigências de lisina digestível e de energia metabolizável para codornas de corte em crescimento. Revista Brasileira de Zootecnia 2011;40(3):593-601.) and Scherer (2011Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.), who observed a linear decrease in quail feed intake from 1 to 14 d of age in response to increasing dietary AMEn. These findings confirm the hypothesis that, indeed, energy plays an important role in feed consumption; and that poultry tend to regulate feed intake to maintain constant energy intake. Indeed, AMEn is the nutrient responsible for driving feed intake, but excessive energy supply may promote failure in feed intake control (Mbajiorgu 2011Mbajiorgu CA, Ng`ambi JW, Norris DD. Voluntary feed intake and nutrient composition in chickens. Asian Journal of Animal and Veterinary Advances 2011;6(1):20-28.). Such assumption may explain the linear decrease (p<0.05) in AMEn intake observed in the current study as dietary AMEn increased. As a consequence of the depression in quail feed intake, crude protein and lysine intake were also linearly decreased (p<0.05) by graded dietary AMEn.

Table 2
Growth performance of meat-type quails fed increasing dietary metabolizable energy levels from 1 to 14 d of age.

Final body weight and weight gain exhibited a quadratic response (p<0.05) to increasing AMEn levels. Optimum body weight (88.30 g) and weight gain (78.80) were reached at 2,820 kcal AMEn/kg diet, which corresponded to an energy-to-protein ratio of 108.60. Similarly, Scherer (2011Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.) verified optimum performance in starter meat-type quails fed energy-to-protein of 108.90. Dietary energy, derived from carbohydrates, lipids, and protein provides conditions for adequate poultry growth. Nevertheless, based on its influence on feed intake, excessive dietary energy supply may limit nutrients intake (e.g. amino acids) and consequently compromise bird performance (Maiorka et al., 2004Maiorka A, Dahlke F, Santin E, Kessler AM, Penz Jr. AM. Effect of energy levels of diets formulated on total or digestible amino acid basis on broiler performance. Brazilian Journal of Poultry Science 2004;6(2):87-91.). In the current study, increasing in dietary AMEn decreased protein and lysine intake, which might explain the quadratic responses observed on FBW and WG.

Starter phase is marked by the immaturity of the gastrointestinal tract, which presents limited nutrient digestion and absorption capacity (Lima 2016Lima VBS, Dourado LRB, Machado LP, Biagiotti D, Lima SBPL, Ferreira GJBC, et al. Cottonseed oil in diets for broilers in the pre-starter and starter phases. Plos One 2016;11(1):147-152.). Lipids, in particular, appear to have its digestion and absorption more compromised among nutrients. Reports indicate low pancreatic lipase activity in pre-starter broiler chicks after hatching, which is graded enhanced until 15d of age when it reaches maximum activity (Nir 1993Nir I, Nitsan Z, Mahagua M. Comparative growth and development of the digestive organs and of some enzymes in broiler and egg type chicks after hatching. British Poultry Science 1993;34(3):523-532.). Macari (2002) reported that broiler chick enterocytes reach total development approximately 2-3 weeks after hatching. Presumably, diets containing higher AMEn levels, due to high soybean oil inclusion, might have supplanted gut capacity of lipids digestion and absorption, which might have contributed to the decrease in BW and WG in quails in the current study. Ton (2011Ton APS, Furlan AC, Martins EN, Toledo JB, Scherer C, Conti ACM. Exigências de lisina digestível e de energia metabolizável para codornas de corte em crescimento. Revista Brasileira de Zootecnia 2011;40(3):593-601.) reported a linear decrease in meat-type quail WG and BW at 14 d of age by increasing dietary AMEn levels from 2,800 to 3,100 Kcal/kg. Contrary to our results, however, Corrêa (2007Corrêa GSS, Silva MA, Corrêa AB, Fontes DO, Torres RA, Dionello NJL, et al. Níveis de proteína bruta para codornas de corte durante o período de crescimento. Arquivo Brasileiro de Medicina Veterinária e Zootecnia 2007;60(3):797-804.) did not observe detrimental effects of AMEn levels on 7-to-21-day-old meat-type quail BW and WG by ranging dietary AMEn from 2,900 to 3,100 Kcal/kg.

Feed conversion was linearly improved (p<0.05) in response to increasing AMEn levels, decreasing by 0.1 points for every increase in 100 Kcal in AMEn (Table 2). Feed intake decreased 33.50% when dietary AMEn ranged from 2,600 to 3,200 Kcal/kg, whereas the WG was 7.98% lower in birds fed the higher AMEn level. The effects of AMEn in feed intake explain the improvement in feed conversion. On the other hand, Scherer (2011Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.) observed a quadratic response in meat-type quail feed conversion at the initial phase which were optimized at 2,997 kcal/kg.

Dry matter content in quail carcass was linearly increased (p<0.01) as AMEn intake increased and hence carcass moisture content decreased (p<0.01) as detailed in Table 3. These findings are in agreement with those reported by Scherer et al. (2011Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.) for meat-type quails in the initial phase. Contrary to fat deposition, body protein accretion is positively associated with moisture content. Boekholt et al. (1994Boekholt HA, Van der Grinten P, Schreurs VV, Los MJ, Leffering CP. Effect of dietary energy restriction on retention of protein, fat and energy in broilers chickens. British Poultry Science 1994;35(4):603-614.) demonstrated that for each 1g of crude protein retained, approximately an amount of 3g of water was deposited in muscle tissue. The response observed on dry matter content as a function of increasing AMEn levels may be explained by fat content in carcass, which were linearly increased (p<0.01) by the increase in dietary AMEn supply. In turn, the increase observed on carcass fat content may be explained by the increase in the energy:protein ratio and as a consequence of the increase in soybean oil inclusion when AMEn content increased. According to Sakomura et al. (2004), the inclusion of vegetable oils decrease heat increment which result in a higher net energy content of diets. Fat deposition is more efficient when the organism uses dietary lipids and endogenous synthesis from glycerol and fatty acids. When fat sources are included in diets, the endogenous synthesis of fatty acids are down regulated, which result in higher amounts of energy available for productive purposes (Franco, 1998).

Table 3
Carcass traits of meat-type quails fed increasing dietary metabolizable energy levels from 1 to 14 d of age.

Protein content in carcass was unaffected (p>0.05) by AMEn concentration in the diets, which are in agreement with Scherer et al. (2011Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.). The afore mentioned authors noticed that despite the lower intake of nutrients due to the lower feed intake of quails fed high AMEn levels, meat-type quails reduced body weight but not protein content in carcass. Nutrient intake was indeed lower in quails fed the highest AMEn levels. However, the oil, due to its extra-caloric effect, may have attenuated the reduced nutrient supply by increasing digestibility by increasing digesta retention in gastrointestinal tract (Sakomura et al., 2004; Mateos & Sell, 1981). Such hypothesis was confirmed by Cançado & Baião (2002) who observed an increase in protein digestibility in broilers fed diets with higher oil content compared with birds fed diets without oil.

CONCLUSION

Based on performance and carcass composition, the level of 2,820 kcal AMEn/kg meet meat-type quail requirements.

REFERENCES

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  • Maiorka A, Dahlke F, Santin E, Kessler AM, Penz Jr. AM. Effect of energy levels of diets formulated on total or digestible amino acid basis on broiler performance. Brazilian Journal of Poultry Science 2004;6(2):87-91.
  • Mbajiorgu CA, Ng`ambi JW, Norris DD. Voluntary feed intake and nutrient composition in chickens. Asian Journal of Animal and Veterinary Advances 2011;6(1):20-28.
  • Nir I, Nitsan Z, Mahagua M. Comparative growth and development of the digestive organs and of some enzymes in broiler and egg type chicks after hatching. British Poultry Science 1993;34(3):523-532.
  • Reis RS, Barreto SLT, Torres RA, Muniz JCL, Mendonça MO, Viana GS, et al. Proteína bruta e energia metabolizável para codornas de corte de 1 a 14 dias de idade. Arquivos Brasileiros de Medicina Veterinária e Zootecnia 2014;66(11):903-910.
  • Rostagno HS, Albino LFT, Donzele JL, Gomes PC, Oliveira RF, Lopes DC, et al. Tabelas brasileiras para aves e suínos. composição de alimentos e exigências nutricionais. 3rd ed. Viçosa: Editora UFV; 2011.
  • Scherer C, Furlan AC, Martins EN, Scapinello C. Ton APS. Exigência de energia metabolizável de codornas de corte no período de 1 a 14 dias de idade. Revista Brasileira de Zootecnia 2011;40(11):2496-2501.
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  • UFV - Universidade Federal de Viçosa. SAEG - Sistema de análises estatísticas e genéticas. Viçosa; 2000.

Publication Dates

  • Publication in this collection
    Apr-Jun 2018

History

  • Received
    16 May 2017
  • Accepted
    30 Oct 2017
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