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Revista de Ciências Agrárias

versão impressa ISSN 0871-018X

Rev. de Ciências Agrárias vol.38 no.1 Lisboa mar. 2015

 

ARTIGO

Performance and carcass characteristics of Santa Inês lambs fed protein diets

Desempenho e características de carcaça de cordeiros Santa Inês alimentados com dietas proteicas

Janaina L. Silva1*, Karina G. Ribeiro2, Odilon G. Pereira2, Sebastião C. Valadares Filho2, Douglas S. Pina3 e Pedro V. R. Paulino1

 

1 Department of Animal Science, Universidade Federal dos Vales do Jequitinhonha e Mucuri (UFVJM), Campus JK, Rodovia MGT 367 - Km 583, nº 5000, Alto da Jacuba, Diamantina/MG, Brazil. ZipCode: 39100-000. *E-mail: silva_janainalima@yahoo.com.br, author for correspondence.

2 Department of Animal Science. Federal University of Viçosa (UFV), Peter Henry Rolfs Avenue, s/n, Campus Universitário, Zip code 36570-000, Viçosa-MG, Brazil. E-mails: karinaribeiro@ufv.br; odilon@ufv.br; scvfilho@ufv.br; pveiga@ufv.br

3 Department of Animal Science. Federal University of Mato Grosso (UFMT), Alexandre Ferronato Avenue,1200, Setor Industrial, Sinop-MT, Brazil. E-mail: douglaspinaufmt@gmail.com

 

ABSTRACT

The objective of this study was to determine the best level and the effect of diets containing different levels of crude protein (CP) on performance and carcass characteristics of feedlot Santa Inês lambs. In trial 1, eight intact lambs with an average live weight of 25.8 kg were distributed in two 4 x 4 Latin squares and were kept in individual metabolic cages. The total collection of feces was used to estimate digestibility and the total urine collection was used to determine the nitrogen balance. In trial 2, 32 intact lambs with an average live weight of 22.0 kg were distributed in an completely randomized design with eight repetitions and were kept in individual metabolic cages. For both trials, the diets consisted of four levels of CP (14.25; 15.50; 16.75; and 18.0%), with 40% corn silage and 60% concentrate in the dry matter. The increase in crude protein levels in the diets did not alter the digestibility, performance, or carcass characteristics of feedlot-finished Santa Inês lambs; therefore, a level of 14.25% crude protein is recommended, as it allowed for satisfactory gains in animal performance.

Keywords: carcass yield, daily gain, intake, nitrogen balance

 

RESUMO

O objetivo deste estudo foi determinar o melhor nível e o efeito de dietas contendo diferentes níveis de proteína bruta (PB) sobre o desempenho e características de carcaça em cordeiros Santa Inês confinados. No ensaio 1, oito cordeiros, não castrados, com peso vivo médio de 25,8 kg foram distribuídos em dois quadrados latinos 4 x 4, sendo mantidos em gaiolas metabólicas individuais. A colheita total de fezes foi utilizada para estimar a digestibilidade e o método de colheita total de urina foi utilizado para determinar o balanço de nitrogénio. No ensaio 2, 32 cordeiros, não castrados, com peso vivo médio de 22,0 kg, foram distribuídos num delineamento inteiramente casualizado, com oito repetições e mantidos em gaiolas metabólicas individuais. Em ambos os ensaios, as dietas consistiram em quatro níveis de PB (14,25; 15,50; 16,75 e 18,0%); com 40% de silagem de milho e 60% de concentrado, com base na matéria seca. O aumento nos níveis de proteína bruta nas dietas não alterou a digestibilidade dos nutrientes, desempenho ou as características da carcaça nos cordeiros Santa Inês terminados em confinamento, portanto, recomenda-se o nível de 14,25% de PB, por permitir ganhos satisfatórios no desempenho de carcaça.

Palavras-chave: balanço de nitrogénio, consumo, ganho de peso diário, rendimento de carcaça

 

Introduction

Sheep production competes with and has advantages over cattle production because it occupies less space per animal, is easier to manage, is highly adaptable to adverse environmental conditions, requires lower animal purchase costs, and has a rapid rate of economic return (Rogério et al., 2013).

Santa Inês sheep, which are widely distributed in northeastern Brazil, are hardy animals, prolific, adaptable to various environmental conditions, and they gain weight easily when in feedlots (Costa et al., 2012; Sousa et al., 2012; Rufino et al., 2013).

To obtain high performance and quality carcasses, the feedlot is one of the most commonly used systems in sheep production (Prado et al., 2000). It allows for higher returns on invested capital, standardization of the final product, reduction of the age at slaughter (Vieira et al., 2013), and rapid production of lambs with good carcass conformation, good yield, a high percentage of lean meat, and adequate fat coverage (Souza et al., 2013; Majdoub-Mathlouthi et al., 2013).

The protein in the diets of finishing animals can improve performance and carcass traits and ensure increases in production rates; however, studies to assess the optimal level of dietary protein are still controversial, because the climatic conditions from which animals are selected influence their nutritional requirements (Regadas Filho et al., 2013).

The main objective of this study was to evaluate the effects of different levels of dietary crude protein (CP) on the intake and apparent total tract digestibility of the nutrients, the nitrogen (N) balance, and the performance and carcass characteristics; also, the goal was to establish a better level of protein for feedlot-finished Santa Inês breed lambs according to the recommendations of the NRC (1985), while comparing the results to recommendations of the NRC (2007).

 

Materials and Methods

Trial 1 was conducted in the Animal Laboratory of the Department of Animal Science of the Federal University of Viçosa, lasting for a total of 60 days. Eight Santa Inês intact breed lambs were distributed in two 4 x 4 Latin squares, with four diets and four animals each. The initial average weight of lambs was 25.8 ± 1.21 kg. Each experimental period lasted for 15 days, with 10 days for adaptation to the diets and five days for collection. The animals were placed in individual metabolic cages for the in vivo digestibility assays; a feeding trough, drinking device, and urine collection system were provided in each cage. At the beginning of the experiment, all of the animals were dewormed with an oral parasiticide, and the metabolic cages were cleaned daily.

Trial 2 was conducted in the Animal Laboratory of the Department of Animal Science of the Federal University of Viçosa, lasting for a total of 57 days. Four lambs were slaughtered at the beginning of the experimental phase for evaluation of the carcass yield, which served as a reference for the evaluation of carcass gain of the 32 lambs that were slaughtered at the end of the experiment. The remaining thirty-two intact Santa Inês lambs with an initial weight of 22.08 ± 1.94 kg were confined in individual stalls and were distributed in a completely randomized design, with four diets and eight repetitions, except for the treatment with 14.25% CP which had seven repetitions due to the loss of an experimental unit. The stalls were suspended with a slatted floor 0.70 m from the ground, with dimensions of 1.55 x 0.88 x 1.90 m (L x W x H), and were equipped with individual feeders and drinkers. Before confinement, the animals were identified, treated for ecto- and endo- parasites, vaccinated against clostridial diseases, tetanus, and enterotoxemia, and the pens were cleaned daily during the entire experimental period.

The treatments consisted of four diets with different levels of crude protein (14.25; 15.50; 16.75; and 18.00% CP in the DM) with a roughage-to-concentrate ratio of 40:60 (40% corn silage and 60% concentrate), and were formulated according to the recommendations of the National Research Council (NRC, 1985) for lambs with an average live weight between 20 and 25 kg.

The chemical composition of the foods and the diets are found in Tables 1 and 2, respectively. The diets were fed to the animals in two daily feedings (07:00 and 15:00 h), with half given in the morning and half given in the afternoon, and each animal had clean and fresh water available ad libitum. The animals’ intake was calculated daily during the adaptation period and was used as a reference for the feeding during the experimental period to allow 10% of leftovers. During the experimental period, the provided diets and the leftovers were weighed daily to estimate the daily intake of DM, which was obtained based on the difference between the amount of DM provided to the animals and the amount of DM left over in the trough.

During the collection periods in Trial 1, samples of feces, urine, provided diet and leftovers feed, were taken. For the collection of urine and to obtain the volume excreted during a 24-hr period, plastic buckets with an eight-liter capacity were used, which were covered with protective screens to prevent contamination of the material by fur, food, or feces. In each bucket, 60 mL of 20% H2SO4 solution was added to avoid loss of N due to volatilization and possible fermentation of the urine. After each collection, 100 mL samples were stored in bottles that were identified by animal and experimental period (composite sample), in a -20°C freezer. To analyze urine, the samples were thawed and homogenized by shaking, and then the samples were analyzed for the total N.

To obtain the in vivo digestibility coefficients, a sack of synthetic leather was attached to each animal to collect all the feces, which were weighed daily in the morning and in the afternoon; samples corresponding to 10% of the total weight of feces, were homogenized and removed. The fecal samples were stored in plastic bags, identified by animal and experimental period, and stored in a -20°C freezer.

The samples of the provided diets, the leftovers in the experimental assays, and the fecal samples collected in the digestibility assay per animal and per experimental period were dried in a convection oven at 55°C for 72 hours; after the initial drying, the samples were ground in a Willey mill with a 1-mm sieve. In the samples of the provided diets, the following were calculated for the leftovers and the feces: dry matter (DM), organic matter (OM), crude protein (CP), ether extract (EE), and neutral detergent fiber corrected for ash and protein (NDFap), based on methodologies described by Detmann et al. (2012).

To monitor weight gain in Trial 2, the animals were weighed at 14-days intervals and then at seven-day intervals as the weight of the animals approached 30 kg, which was previously established as the slaughter weight. Upon reaching an average body weight of 30 kg, the animals were fasted for 16 hours and subsequently weighed to obtain the pre-slaughter body weight.

To estimate the non-fibrous carbohydrates (NFC), the equation recommended by Hall (2000) for foods containing urea was adopted: NFC = 100 – [(%CPurea + %urea)] + %NDFap + %EE + %ash, in which CPurea and NDFap, respectively, are crude protein corrected for urea and neutral detergent fiber corrected for ash and protein.

The calculation of the total digestible nutrients (TDN) was performed according to the equation proposed by Weiss (1999): TDN = [(DCP + DNFC + DNDFap + DEE x 2.25)], in which DCP, DNFC, DNDFap, and DEE, respectively, denote digestible CP, NFC, NDF, and EE, with NDF corrected for ash and protein.

The values for the total apparent digestibility of the nutrients (DN) were obtained from the equation cited by Berchielli et al. (2005): DN (%) = [(DM ingested x % Nutrient) – (DM excreted x % Nutrient) x 100]/(DM ingested x % Nutrient).

The N balance (NB) or the retained N was determined by subtracting the total N excreted in the feces and urine from the total ingested N, which represents the total N that was effectively retained in the animal’s body, based on the following equation: NB = Ingested N – (N Feces + N Urine). The amount of absorbed N can be determined by subtracting the total ingested N and the N contained in the feces per the following equation: Absorbed N = Ingested N – N Feces.

After the slaughter, the animals were skinned (removal of the leather) and eviscerated, and the contents of the gastrointestinal tract (GIT) were removed, along with the urinary bladder and the gallbladder, thereby making it possible to calculate the empty body weight: EBW = BWS [body weight at slaughter] – (GIT + urinary bladder + gallbladder). Empty body weight was used to determine the biological or true yield (TY), obtained by relation between the weight of hot carcass and empty body weight (Sañudo and Sierra, 1986). From the slaughtered body, which was bled, skinned, gutted, and without hooves, the hot carcass weight was obtained (HCW). Then, the values obtained for the weight of the kidneys and the pelvic and renal fat, were subtracted from the HCW for the calculation of the hot carcass yield (HCY) by using the following equation: HCY (%) = (HCW/BWS) x 100, in which HCW (kg) = hot carcass weight, and BWS (kg) = body weight at slaughter. The daily carcass gain (CG) was calculated in relation to the pre-slaughter body weight: CGPSW (g d-1) = [(PSW x (HCY/100)) - (IBWf x (RCY/100))]/n, and in relation to the empty body weight: CGEBW (g d-1) = [(EBW x (HCY/100)) - (IBWf x (RCY/100))]/n, in which PSW (kg) = pre-slaughter body weight; EBW (kg) = empty body weight; HCY (%) = hot carcass yield; IBWf (kg) = initial body weight of the animals when fasting; RCY (%) = carcass yield of the reference animals; and n = number of days of evaluation.

The obtained data were subjected to analysis of variance and regression analysis with a 5% probability of type I error using the Statistical Analysis System (SAS, 1999). The weight of the animals was considered as a covariable.

 

Results and Discussion

The data showed that even with an improvement in the supply of dietary protein for the finished lamb, the evaluated levels in the present study did not promote (p>0.05) variations in the intake of DM, OM, EE, NDFap, NFC, or TDN, while the intake of CP, RDP, and RUP increased linearly (p<0.05) with the levels of protein in the diet (Table 3).

The average intake of 1,056 g of DM per day was less than the 1,300 g d-1 recommended by the NRC (1985), but greater than the 830 g d-1 recommended by the NRC (2007) for lambs in this category (Table 3). The average DM intake of 88.07 g kg-1 BW0.75 is higher than that recommended by the NRC (2007) of 64.5 g kg-1 BW0.75. High protein levels and diet quality may modify intake, as suggested by Costa et al. (2013), when comparing NRC (1985) and NRC (2007). Achieving the proper intake of DM with a correct balance in the diet is extremely important in a production system, because the intake will determine the level of ingested nutrients and the maximum animal production (Berchielli et al., 2005).

The average daily intake of DM that was found in this study (Table 3) is similar to the 1,061 g d-1 obtained by Rocha et al. (2004) when evaluating diets containing crude protein levels ranging from 14% to 20% for confined Santa Inês lambs, and it is close to the 1,040 g d-1 obtained by Haddad et al. (2001) when diets were provided with 14% CP to Awassi lambs during finishing. However, these authors found intakes of 1,230 and 1,178 g d-1, respectively, when the protein levels were 16% and 18% of DM.

The CP intakes (Table 3) in diets with 14.25 and 15.5% PB were less than179 g d-1, which is recommended by the NRC (1985); however, for all crude protein levels that were used in this study, the obtained CP intakes were higher than 101 g CP per day, which is recommended by the NRC (2007). These results indicate that the protein requirements for growing lambs, according to the recommendation of the NRC (1985), are over estimated. This data was validated by the NRC (2007) for small ruminants, in which lower levels of protein were sufficient to meet the needs of the animals, a result that is beneficial to feedlot finishing systems because the lower level of protein reduces the costs of food concentrates.

In the studies of Rogério et al. (2013), animals that were fed balanced diets by the NRC (2007) and with 20% CP showed increased protein utilization and improved intake of digestible protein. However, the authors noted that when comparing the NRC (1985) and NRC (2007) recommendations, the performance data were similar, except for nutrient intake. The protein and energy intake were higher in diets that were balanced by the NRC (2007) due to a better relationship between energy and protein.

As it was found in the present study, Rocha et al. (2004) observed increases in protein intake of 165, 179, and 218 g d-1, respectively, for Santa Inês lambs receiving diets with 14, 16, and 18% CP; however, Haddad et al. (2001) did not find differences in the intake of protein when they used levels of 16% and 18% CP, and the average value of 187 g d-1 was similar to that found in the present study.

The intake of 97.9; 105.7; 113.5; and 121.3 g RDP d-1, which were estimated for the levels of 14.25; 15.50; 16.75; and 18.00% CP, respectively, exceeded the value of 64 g d-1 of RDP recommended by the NRC (2007). The highest intake of RDP and RUP as a function of the increased levels of crude protein could be due to the increased levels of urea, which is a source of non-protein N with high rumen degradability, and to the corn gluten meal in the diets, which is a source of RUP.

Costa et al. (2013) reported that the NRC (2007) recognizes that RDP and bypass protein of the feed are not constant, but instead depend on the degradation and passage rates. In contrast, the NRC (1985) only considered the CP value of a given food without considering the protein degradation rate in the rumen.

The different levels of crude protein in the diets did not affect (p>0.05) the coefficients of total tract digestibility of the nutrients (Table 4). An increase in the protein level of the diet was expected to improve the digestibility of the ingested nutrients due to the greater supply of N for the rumen microorganisms; however, the lack of effect in the present study probably occurred because the proposed diets met the requirements of the animals, and balanced diets with ingredients of good nutritional value were used, thereby resulting in a lack of variation in the intake of nutrients.

The intake and absorption of N and the fecal and urinary excretions were not influenced (p>0.05) by the different levels of crude protein. For the NB or the amount of N that was truly retained in the bodies of the animals, no effect was observed (p>0.05) due to the levels of CP that were used in the diets (Table 5).

The excretion of N via urine was observed to be greater than the N excretion in the feces, from which we can infer that the provided protein levels exceeded what the lamb could absorb (Table 5). We also observed that after subtracting the amount of excreted N via the feces (7.30 g d-1) and urine (18.90 g d-1) from the total amount of ingested N (31.10 g d-1), the lamb managed to retain 4.90 g N d-1 to be used for maintenance and production. A similar behavior was observed for the proportion of N retained relative to the N ingested, and the proportion of N retained relative to the N absorbed (Table 5). Importantly, no negative NB was verified in any of the diets, which indicates that protein intake met the requirements of the animals.

In the analysis of the animal yield, no effects of the different levels of crude protein in the diets (p>0.05) were identified on the final body weight, average daily weight gain (AWG), carcass gains (CG), carcass weight (CW), and the feed conversion (FC) (Table 6). For protein conversion, an increase of 0.0752 kg CP kg-1 gain for each 1% increase in the level of dietary protein was estimated. According to this regression equation, the rates of protein conversion for CP levels of 14.25; 15.50; 16.75; and 18.00% were, respectively, 0.69; 0.78; 0.88; and 0.97 kg CP kg-1 gain.

Dry matter intake, feed conversion, and weight gain can be increased by manipulating the levels of dietary protein (Zundt et al., 2002); nevertheless, in this study, the levels that were studied did not promote changes in these variables. The overall average that was observed for ADG was 217 g d-1, which is similar to the 200 g d-1 gain suggested by the NRC (2007) when the requirements for the intake of DM of 1,100 g d-1 and 106 g d-1 CP are met (Table 6). Gains that were similar to those found in the present study of 226 g d-1 in Santa Inês lambs receiving diets with 14; 16; and 18% CP were reported by Rocha et al. (2004), who also did not find an effect of the different evaluated protein levels. Also, Titi et al. (2000) observed a similar weight gain of 208 g d-1 in Awassi lambs that were fed a diet containing 16% CP, while at the levels of 14% and 18% CP, the authors found lower gains of 171 and 189 g d-1, respectively. Haddad et al. (2001) found an average daily gain of 223 g in Awassi lambs receiving diets with 14% CP during finishing; however, gains of 287 and 259 g d-1, respectively, which were greater than those found in the present study, were observed when 16 and 18% CP were used.

An average final body weight of 30.11 kg and a hot carcass weight (HCW) of 13.81 kg were observed in the present study, which were slightly lower (Table 6) than the values that were suggested as ideal by Silva Sobrinho (2001) of 31 kg LWS and 14.3 kg HCW, both of which were obtained from the compilation of various results of studies and were considered as reference values. However, Silva and Pires (2000) noted that the consumer market is the main determinant of the ideal slaughter weight, which may vary in function of the region of Brazil in which the meat is sold. HCW of 14.6 and 14.8 kg, similar to those in the present study, were reported by Rocha et al. (2004) when Santa Inês lambs received diets with 14 and 16% CP, respectively.

In this study, there was no effect of protein levels on hot carcass yield, with an average value of 44.85%, as well as on the true yield (53.67%), which was obtained relative to the empty body weight (true or biological yield) (Table 6). These results were considered satisfactory when using reference values of 44.5% for retail yield and 53% for true yield, which were suggested by Silva Sobrinho (2001) as the ideal for sheep. This variable is influenced not only by factors related to the animal such as age, sex, breed, crossbreeding, weight at birth, and weight at slaughter, but also by the nutritional level, sanitary conditions, and management (Silva Sobrinho, 2001).

In the present study, the feed conversion averaged 5.13 kg DM kg-1 gain was obtained (Table 6). Better feed conversions of 4.19, 4.28, and 4.35 kg DM kg-1 gain were obtained by Rocha et al. (2004) when using protein levels of 14, 16, and 18%, respectively, in Santa Inês lamb diets; values of 4.6, 4.4, and 4.6 kg DM kg-1 gain were obtained for Awassi lambs when Haddad et al. (2001) used diets with 14, 16, and 18% CP, respectively. From our results, we could verify a trend to a higher DM intake with the increase in the protein content of diets. However, the weight gain tended to decrease which probably affected feed conversion.

 

Conclusion

We recommend the use of 14.25% of crude protein in diets of feedlot-finished lambs to obtain good performance and carcass characteristics, without altering either the intake and digestibility of nutrients or the nitrogen balance of lambs. According to results, the tested protein levels for finishing lambs that were recommended by the NRC (1985) are excessive when compared to the recommendations by the NRC (2007).

 

Acknowledgements

The authors would like to thank the Minas Gerais Research Fund (Fundação de Amparo à Pesquisa do Estado de Minas Gerais – FAPEMIG).

 

References

Berchielli, T.T.; Oliveira, S.G. e Garcia, A.V. (2005) - Aplicação de técnicas para estudos de ingestão, composição da dieta e digestibilidade. Archives of Veterinary Science, vol. 10, n. 2, p. 29-40.         [ Links ]

Costa, R.G.; Treviño, I.H.; Medeiros, G.R. de; Medeiros, A.N.; Pinto, T.F. e Oliveira, R.L. de. (2012) - Effects of replacing corn with cactus pear (Opuntia ficus indica Mill) on the performance of Santa Inês lambs. Small Ruminant Research, vol. 102, n. 1, p. 13-17.         [ Links ]

Costa, H.H.A.; Rogério, M.C.P.; Muir, J.P.; Alves, A.A.; Galvani, D.B.; Pompeu, R.C.F.F.; Landim, A.V.; Carneiro, M.S.S. e Campos, W.E. (2013) - Nutritional evaluation of lamb diets in a tropical setting formulated according to NRC (1985) and NRC (2007) specifications. Small Ruminant Research, vol. 113, n. 1, p. 20-29.         [ Links ]

Detmann, E.; Souza, M.A.de; Valadares Filho, S.C.; Queiroz, A.C.de; Berchielli, T.T.; Saliba, E.O.S.; Cabral, L.S.; Pina, D.S.; Ladeira, M.M. e Azevedo, J.A.G. (2012) - Métodos para Análise de Alimentos. Instituto Nacional de Ciência e Tecnologia de Ciência Animal. Visconde do Rio Branco: Suprema.         [ Links ]

Haddad, S.G.; Nasr, R.E. e Muwalla, M.M. (2001) - Optimum dietary crude protein level for finishing Awassi lambs. Small Ruminant Research, vol. 39, n. 1, p. 41-46.         [ Links ]

Hall, M. B. (2000) - Calculation of non-structural carbohydrate content of feeds that contain non-protein nitrogen. Bulletin 339:A-25. University of Florida, Gainesville.         [ Links ]

Majdoub-Mathlouthi, L.; Saïd, B.; Say, A. e Kraiem, K. (2013) - Effect of concentrate level and slaughter body weight on growth performances, carcass traits and meat quality of Barbarine lambs fed oat hay based diet. Meat Science, vol. 93, n. 3, p. 557-563.         [ Links ]

National Research Council - NRC (1985) - Nutrient Requirements of Sheep, National Research Council, Washington, DC.         [ Links ]

National Research Council - NRC (2007) - Nutrient requirements of small ruminants: sheep, goats, cervids, and new camelids. National Research Council, Washington, D.C.         [ Links ]

Prado, I.N.; Martins, A.S.; Alcalde, C.R.; Zeoula, L.M. e Marques, J.A. (2000) - Performance of Heifers fed diets containing corn or cassava hull as energy source and cottonseed meal or yeast as protein source. Revista Brasileira de Zootecnia, vol. 29, n. 1, p. 278–287.         [ Links ]

Regadas Filho, J.G.L.; Pereira, E.S.; Pimentel, P.G.; Villarroel, A.B.S.; Medeiros, A.N. e Fontenele, R.M. (2013) - Body composition and net energy requirements for Santa Inês lambs. Small Ruminant Research, vol. 109, n. 2-3, p. 107-112.         [ Links ]

Rocha, M.H.M.; Susin, I.; Pires, A.V.; Fernandes Jr., J.S. e Mendes, C.Q. (2004) - Performance of Santa Inês lambs fed diets of variable crude protein levels. Scientia Agricola, vol. 61, n. 2, p. 41-145.         [ Links ]

Rogério, M.C.P.; Castro, E.M.de; Martins, E.C.; Monteiro, J.P.; Silva, K.de.M.; Cândido, M.J.D.; Gomes, T.C.L.; Bloc, A.F.R.; Vasconcelos, A.M.de; Leite, E.R. e Costa, H.H.A. (2013) - Economical and financial analysis of lamb finishing fed with diets formulated according to the NRC (1985) and the NRC (2007). Tropical Animal Health and Production, vol. 45, n. 1, p. 259-266.         [ Links ]

Rufino, L.D.A.; Pereira, O.G.; Ribeiro, K.G.; Valadares Filho, S.C.; Cavali, J. e Paulino, P.V.R. (2013) - Effect of substitution of soybean meal for inactive dry yeast on diet digestibility, lamb’s growth and meat quality. Small Ruminant Research, vol. 111, n. 1-3, p. 56-62.         [ Links ]

Sañudo, C. e Sierra, I. (1986) - Calidad de la canal en la especie ovina. Ovino, vol. 11, n. 1., p. 127-153.         [ Links ]

SAS Institute Inc. (1999) - SAS/STAT User’s Guide: Version 8. SAS Institute Inc., Cary, North Carolina.         [ Links ]

Silva, L.F. e Pires, C.C. (2000) - Avaliações quantitativas e predição das proporções de osso, músculo e gordura da carcaça em ovinos. Revista Brasileira de Zootecnia, vol. 29, n. 4, p. 1253-1260.         [ Links ]

Silva Sobrinho, A.G. (2001) - Criação de ovinos. Jaboticabal, FUNEP, 302p.         [ Links ]

Souza, D.A.; Selaive-Villarroel, A.B.; Pereira, E.S.; Osório, J.C.S. e Teixeira, A. (2013) - Growth performance, feed efficiency and carcass characteristics of lambs produced from Dorper sheep crossed with Santa Inês or Brazilian Somali sheep. Small Ruminant Research, vol. 114, n. 1, p. 51-55.         [ Links ]

Sousa, W.J.de; Cartaxo, F.Q.; Costa, R.G.; Cezar, M.F.; Cunha, M.G.G.; Pereira Filho, J.M. e Santos, N.M.dos. (2012) - Biological and economic performance of feedlot lambs feeding on diets with different energy densities. Revista Brasileira de Zootecnia, vol. 41, n. 5, p. 1285-1291.         [ Links ]

Titi, H.H.; Tabbaa, M.J.; Amasheh, M.G.; Barakeh, F. e Daqamseh, B. (2000) - Comparative performance of Awassi lambs and Black goat kids on different crude protein levels in Jordan. Small Ruminant Research, vol. 37, n. 1-2, p. 131-135.         [ Links ]

Valadares Filho, S.C.; Magalhães, K.A. e Rocha Jr., V.R. (2006) - Tabelas brasileiras de composição de alimentos para bovinos. CQBAL 2.0. Viçosa, UFV.         [ Links ]

Vieira, P.A.S.; Pereira, L.G.R.; Azevêdo, J.A.G.; Neves, A.L.A.; Chizzotti, M.L.; Santos, R.D.; Araújo, G.G.L.; Misturaf, C. e Chaves, A.V. (2013) - Development of mathematical models to predict dry matter intake in feedlot Santa Inês rams. Small Ruminant Research, vol. 112, n. 1-3, p. 78-84.         [ Links ]

Weiss, W.P. (1999) - Energy prediction equations for ruminant feeds. In: Proceedings of the 61th Cornell Nutrition Conference Feed Manufactures, Ithaca, Cornell University, p. 176-185.         [ Links ]

Zundt, M.; Macedo, F.A.F. e Martins, E.N. (2002) - Desempenho de cordeiros alimentados com diferentes níveis proteicos. Revista Brasileira de Zootecnia, vol. 31, n. 3, p. 1307-1314.         [ Links ]

 

Received/Recebido: 2014. 07.21

Accepted/Aceite: 2014.12.29

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