Trace mineral requirements for growth of Moxotó goats grazing in the semiarid region of Brazil

Araújo, Marcos Jácome de; Medeiros, Ariosvaldo Nunes de; Teixeira, Izabelle Auxiliadora Molina de Almeida; Costa, Roberto Germano; Marques, Carlo Aldrovandi Torreão; Resende, Kléber Tomás de; Melo, Gabriel Maurício Peruca de

doi:10.1590/S1806-92902017000300008

ABSTRACT

A comparative slaughter trial was conducted to estimate the body composition and net requirements of Cu, Zn, Mn, Fe, and Co for growth of castrated Moxotó goat kids, with15.69±0.78 kg initial body weight (BW), grazing in the semiarid region of Brazil. The baseline group consisted of four randomly selected kids (15.37±0.30 kg BW). Thirty-two kids were randomly allocated into eight groups (considered as block), distributed among four levels of concentrate supplementation (0, 0.5, 1.0, and 1.5% BW). Animals in a group were slaughtered when the 1.5% BW treatment kids in the group reached approximately 25 kg BW. The trace element content (mg/kg of empty body weight) ranged from 23.68 to 27.81 mg Zn, 35.70 to 47.29 mg Fe, 0.86 to 1.09 mg Mn, 1.45 to 1.75 mg Cu, and 0.83 to 0.87 mg Co for Moxotó kids at 15 and 25 kg BW, respectively. The net requirements (mg/kg of empty body weight gain) ranged from 30.43 to 35.74 mg Zn, 53.48 to 70.84 mg Fe, 1.22 to 1.54 mg Mn, 1.93 to 2.32 mg Cu, and 0.91 to 0.95 mg Co for animals with BW ranging from 15 to 25 kg, respectively. Indigenous goats grazing in the semiarid region of Brazil have different requirements from those values recommended by international committees for dairy and meat goats.

Caatinga; factorial method; micro mineral; zinc

Introduction

Trace elements play an important role in maintaining normal cell metabolism in animals and inappropriate provision of any of the trace elements may damage the health and productivity of the animal. Pathologies, such as anemia, may indicate a deficiency in Fe, Cu, and Co, but they may also indicate a manifestation of Mo, Se, and Zn toxicity. Resistance to infection is influenced by Cu, Fe, Se, and Zn, and skeletal deformities occur as a consequence of the lack of Cu, Mn, Zn, Ca, and P. Moreover, deficiencies in Cu, Mn, Zn, I, and Se affect animal reproduction (Underwood and Suttle, 1999Underwood, E. J. and Suttle, N. F. 1999. The mineral nutrition of Livestock. 3rd ed. CABI Publishing, NY, USA.). The available method to prevent trace mineral deficiency of animals is by adding mineral supplements (Suttle, 2010Suttle, N. F. 2010. Mineral nutrition of Livestock, 4th ed. CAB International, Oxfordshire, UK.); so accurate estimates of trace mineral requirement is necessary in the prevention of trace mineral disorders.

Due to the lack of specific methodologies that may provide more accurate results, some scientific committees and authors have suggested recommendations for animal needs in trace elements, including a safety margin for its values to assure that needs of animals are properly assisted and to avoid signs of deficiency. Thus, the requirements for some trace elements for goats have been obtained from feeding trials and/or adapted from values obtained from dairy cattle, although adjustments have been made based on other estimates and available data on goats (NRC, 2007NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.).

Another challenging factor is that the recommendations are made for animals in feedlot regimen, claiming that grazing animals meet all of their needs in minerals due to an elevated concentration of trace elements in forage, in addition to other sources, such as soil and water (NRC, 2007NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.). However, the concentration of trace elements in forage varies according to the type of soil, fertilization practices, forage species, plant age, pasture botanical composition, weather conditions, time of year, and other factors (Ramírez-Perez et al., 2000Ramírez-Perez, A. H.; Buntinx, S. E. and Rosiles, R. 2000. Effect of breed and age on the voluntary intake and the micromineral status of non-pregnant sheep II. Micromineral status. Small Ruminant Research 37:231-242.).

The estimation of the trace element requirements demands exact knowledge of trace element deposition in the body (Bellof and Pallauf, 2007Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834.). Thus, an accurate technique with direct measurement, as comparative slaughter, has recently been used in trials to estimate the trace element requirements for sheep (Ji et al., 2014Ji, S. K.; Xu, G. S.; Diao, Q. Y.; Jiang, C. G.; Deng, K. D.; Tua, Y. and Zhang, N. F. 2014. Net zinc requirements of Dorper × thin-tailed Han crossbred lambs. Livestock Science 167:178-185.; Zhang et al., 2015Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481.). Therefore, the present study was performed to determine the trace element (Zn, Fe, Cu, Mg, and Co) requirements for growth of Moxotó goat kids grazing in the semiarid region of Brazil using the comparative slaughter technique.

Material and Methods

The study was conducted in the municipality of São João do Cariri (7^o29'34" S and 36^o41'53" W), Paraiba State, Brazil. The climate is Bsh type, which is classified as hot semiarid according to the Koopen classification, and vegetation is typical of Caatinga. The average maximum temperature during the experimental period was 31.45 °C and the average minimum temperature was 20.11 °C. The relative humidity was 61.2% and there was 44.26 mm of rainfall. Humane animal care and handling procedures were followed according to the local animal care committee.

Thirty-six castrated Moxotó kids with an average initial body weight (BW) of 15.69±0.78 kg at approximately four months of age were used in this study. Four animals were slaughtered at the beginning of the experiment with 15.37±0.30 kg of BW representing the initial body composition (baseline group). Thirty-two kids were randomly allocated to four supplementation levels: 0, 0.5, 1.0, and 1.5% BW. Kids were pair-fed in eight slaughter groups (considered as blocks). A slaughter group consisted of one kid from each treatment and when the animal fed for 1.5% BW in each slaughter group reached 25 kg of BW, it was slaughted along with the other goat kids from the same group (goat kids fed 0, 0.5, and 1.0% BW).

The animals had access to native pasture from 07.00 to 16.00 h. After this time, the animals were put in a pen equipped with individual stalls (2.0 × 1.0 m) that did not have coverage but had a ground floor to receive the supplementation. The animals had free access to drinking water and the collective fountains were located at the management center. The experimental concentrate was the same for all treatments, varying only the amount offered to the animals once a day (16.00 h). The feed refusals were weighed, recorded, and sampled in the morning of the next day. The experimental concentrate ingredients were calculated according to the NRC (1981)NRC - National Research Council. 1981. Nutrient requirements of goats: Angora, dairy, and meat goats in temperate and tropical countries. National Academy of Sciences, Washington, DC. to allow a growth rate of 150 g/day for the animals with 1.5% BW supplementation level (Table 1). To control the growth and adjust the concentrate supply, the animals were weighed weekly before feeding using a scale with a precision of 0.1 kg. The experimental area was composed of two paddocks of approximately 8 ha each.

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Table 1
Ingredient and chemical composition of the experimental concentrate and extrusa

In addition to the nutritional requirement assessment, a trial to estimate the dry matter intake (DMI) of the animals on pasture was conducted. Eight animals, with an average of 25.83±4.48 kg BW, cannulated in the esophagus, were used, in a Latin square design (four goats × four periods) with simultaneous repetitions, receiving the same feeding supplementation levels as animals from the requirement test. This trial was carried out to develop a model (equation) to estimate the DMI of the animals from nutritional requirement trial.

The extrusa collection was held for eight consecutive days, in alternating shifts, forming four full collection days for each animal (four mornings and four afternoons). In the morning, the cannulas were removed and coupled to the extrusa collecting bags, which were made of synthetic leather with a bottom of nylon mesh to reduce the excess of saliva. Then, the animals were driven back to the management center for the removal of bags and placement of cannulas and then they were released into their paddocks.

For the afternoon collection, the animals were removed from the pasture 4 h before sampling to avoid regurgitation and contamination of the experimental samples; then, the same procedures as those of the morning collection were performed. The extrusa samples were made considering the experimental period and the animal.

The pasture DMI was estimated through the total feces excretion and dry matter digestibility of diet (Equation 1):

DMI = [(100 × Fecal excretion, kg DM/day) / (100 – DM digestibility of extrusa)] (1)

The total feces collection was performed using collecting bags attached to animals, which were collected in the early morning (07.00 h) and late afternoon (05.00 h). After homogenization of the material from each bag, aliquots of 20% of total excreted for 24 h were removed for the formation of samples per animal and period, which were wrapped in plastic bags properly identified and stored at –10 °C.

After the experimental period, samples were thawed, weighed, and dried in a forced-ventilation oven at 55 °C for 72 h and ground through a 1-mm screen using a Wiley mill (Arthur H. Thomas Co., Philadelphia, PA). The determination of the in vitro DM digestibility was held on artificial rumen (DAYSE II; ANKON Technology Coorp., Fairport, NY) based on methodology adapted from Tilley and Terry et al. (1963). The DMI values (BW, kg^0.75) of fistulated animals were then decreased with the supplementation levels (SL = 0, 0.5, 1.0, and 1.5% BW) and from the regression equation (DMI, g/kg^0.75 BW = 0.0677 + 0.0086SL – 0.0141SL²), average values of 67.7, 68.5, 62.2, and 48.9 g/kg^0.75 BW were found per day for levels of 0, 0.5, 1.0, and 1.5%, respectively. These values were then used to estimate the DMI of animals from the nutritional requirement experiment. The total DMI was equal to the sum of the DMI of the pasture plus the DMI of the concentrate.

Body weights were measured immediately before feed and water were withdrawn for 16 h. Shrunk BW was measured immediately before slaughter and after feed and water were withdrawn for 16 h. At slaughter, the kids were stunned through cerebral concussion and killed by exsanguination using conventional humane procedures. The blood was weighed and sampled. The body was separated into individual components, which were then weighed separately. The individual components were as follows: internal organs (liver, heart, lungs, trachea, tongue, kidneys, and spleen), emptied and cleaned digestive tract (rumen, reticulum, omasum, abomasum, small intestines, and large intestines), hide, head, feet, and carcass. The digestive tract was weighed before and after emptying and flushing with water. All body components were initially frozen at –6 °C. The components were then cut into small pieces, ground with a large screw grinder through a plate with 0.32-cm holes, and mixed by two additional passes through the grinder. After grinding and homogenization, the samples were collected, frozen again, and dried for DM determination. Empty body weight (EBW) was computed as shrunk BW at slaughter minus digestive tract contents. Because the sum of fat, protein, water, and ash content of the empty body did not add up to the observed EBW, the components were proportionally scaled to match the observed EBW.

The ingredients of the diet and extrusa were analyzed for DM (AOAC, 1990AOAC - Association of Official Analytical Chemistry. 1990. Official methods of analysis. 15th ed. AOAC International, Washington, DC.; method no. 930.15), and crude protein (AOAC, 1990AOAC - Association of Official Analytical Chemistry. 1990. Official methods of analysis. 15th ed. AOAC International, Washington, DC.; method no. 984.13). The gross energy was determined by a Parr adiabatic calorimetric bomb. The determination of the in vitro DM digestibility was performed on artificial rumen (DAYSE II; ANKON Technology Corp., Fairport, NY) based on methodology adapted from Tilley and Terry (1963)Tilley, J. M. A. and Terry, R. A. 1963. A two stage technique for the in vitro digestion of forage crops. Journal of the British Grassland Society 18:104-111..

The analyses for the determination of minerals in the concentrate ingredient samples, extrusa, and defatted samples were conducted by means of acid digestion (Mahanti and Barnes, 1983Mahanti, H. and Barnes, R.M. 1983. Determination of major and trace elements in bone by Determination of major, minor and trace elements in bone by inductively-coupled plasma emission spectrometry. Analytica Chimica Acta 151:409-417.). For the digestion of samples, a mixture of nitric acid (HNO₃) with hydrochloric acid (HCl) and hydrogen peroxide (H₂O₂) was used to obtain a mineral solution. This extract was used to obtain dilutions to determine the different trace elements and the readings were performed through atomic absorption spectrophotometry.

The samples of each animal were thawed, dried in an air-circulation oven at 55 °C, and ground in a blender. After this procedure, the samples were defatted by extraction in ether in a Soxhlet apparatus (AOAC, 1990AOAC - Association of Official Analytical Chemistry. 1990. Official methods of analysis. 15th ed. AOAC International, Washington, DC.; method no. 920.39). After extraction with ether, the samples were ground in a ball mill and stored in closed containers. The DM contents (fatted) were determined in an oven at 105 °C up to constant weight, and the ash, crude protein, and trace minerals were determined as mentioned for the ingredients of the experimental concentrate on fat-free samples.

The initial EBW of animals slaughtered at the end of the trial was estimated from the regression equation developed from the baseline animals (Equation 2). By Subtracting the initial EBW from the final EBW, the empty body weight gain (EBWG) was estimated.

Initial EBW, kg = 0.5098 (±25.95) + [0.5757 (±1.68) × initial BW, kg] (2)

The net requirements for growth were calculated using all animals, except those from treatment without supplementation that lost weight, to estimate body gain composition. Body composition was estimated using direct chemical analyses of the whole empty body. The factorial approach was used to estimate trace requirements for growth. Linear regression analyses were conducted to express EBW as a function of BW. The trace element content of animals was summarized by allometric regressions of the logarithm of observed mineral content on the logarithm of empty body weight equation (3).

Log₁₀ y = a + b × log₁₀ EBW, (3)

in which Log₁₀ y = log of the total amount of trace element in the EBW (mg); Log₁₀ EBW = the log of EBW (in kg); and a and b = regression parameters. The equation 3 was differentiated based on the EBW to compute estimates of the composition of the gain at various EBW (Equation 4):

y’ = b × 10^a × EBW^(b−1), (4)

in which y’ = nutrient per unit of empty weight gain (in mg/kg of gain); EBW is expressed in kilograms; and a and b = coefficients determined from a linear regression (Equation 3). To estimate the net trace element requirements for BW gain, the values of body composition of gain were divided by the BW to EBW ratio factor.

The goat kids were distributed at random in a randomized block (slaughter groups) design (eight blocks) and each block contained one animal for each level of supplementation (0, 0.5, 1.0, and 1.5%). The data of DMI, body composition, average daily gain (ADG), and EBW were analyzed using a mixed model with the fixed effects of supplementation level (degree freedom = 3), random effect of slaughter groups (degree freedom = 7), and random residual error using PROC MIXED of SAS (Statistical Analysis System, version 9.0). Polynomial contrast test was performed to analyze linear and quadratic effects using the CONTRAST option of the MIXED procedure. Significance was declared at P<0.05.

The mathematical model was as follows:

Y_ij = µ + α_i + b_j + e_ij,

in which Y_ij = expected outcome for the dependent variable; µ = overall mean; α_i = effect fixed of the i-th supplementation level (i = 0, 0.5, 1.0, and 1.5% BW); b_j = random effect of the j-th block (slaughter groups; j = 1, 2…8); and e_ij = random error associated with each observation.

Linear regression analyses to estimate the growth requirements were adjusted using the PROC REG of SAS. The following model was employed:

Y = α + bx + e,

in which Y = expected response (Log₁₀ of amount of trace element in the EBW); α = the y-intercept; b = slope of the regression line; x = independent variable (Log₁₀ of EBW); and e = the standard error of parameter estimate. Residuals plotted against the predicted values were used to check the assumptions of the model for homoscedasticity, independency, and normality of the errors. A data point was deemed to be an outlier and removed from the database if the studentized residual was outside the ±2.5 range values.

Results

Empty body weight, ADG, EBWG, and DMI increased as supplementation level increased (P<0.0001) (Table 2). A linear positive effect was observed for the proportions of fat, protein, and zinc, while the proportions of water in the empty body decreased linearly in response to the increasing supplementation levels. The proportions of ash, Fe, Mn, Cu, and Co were not influenced by the increasing levels of supplementation (Table 2). On the other hand, when the Zn, Fe, Cu, and Co contents were expressed based on the metabolic weight (mg/kg^0.75 of EBW) (Table 3), a linear increase was observed in response to the increased level of supplementation. As expected, the trace element content on an EBW fat-free basis, independent of the treatment, was more significant than the mineral content before the removal of the fat (Table 3).

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Table 2
Performance and final body composition (fat, protein, water, ash, Zn, Fe, Mn, Co, and Cu) of Moxotó goat kids at baseline and fed different supplementation levels

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Table 3
Final body content of trace minerals (Zn, Fe, Mn, Co, and Cu) of Moxotó goat kids at baseline and fed different supplementation levels

The body composition of Zn, Fe, Mn, Cu, and Co in the empty body of Moxotó goats was estimated according to the EBW (Table 4). Increases of 14.85, 24.5, 21.1, 17.14, and 4.65% in the Zn, Fe, Mn, Cu, and Co concentrations, respectively, were found when the BW varied from 15 to 25 kg (Table 4). The contents of trace elements varied from 23.68 to 27.81 mg of Zn, 35.70 to 47.29 mg of Fe, 0.86 to 1.09 mg of Mn, 1.45 to 1.75 mg of Cu, and 0.83 to 0.87 mg of Co per kg of EBW for animals with BW varying from 15 to 25 kg, respectively (Table 4).

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Table 4
Allometric equations to estimate the body composition in trace elements (Zn, Fe, Mn, Cu, and Co) of Moxotó goats fed different supplementation levels

By deriving the logarithm regression equations of the body content for Zn, Fe, Mn, Cu, and Co according to the EBW logarithm, the prediction equations for these elements per kg of EBWG were obtained (Table 5). Subsequently, the trace element quantities (mg/kg of EBWG) for different weight ranges were determined. The trace element deposition in EBWG followed the same concentration pattern as in EBW (Table 4). The contents of trace elements per EBWG correspond to the respective net requirements for 1 kg of EBWG. Such requirements varied from 30.43 to 35.74 mg of Zn, 53.48 to 70.84 mg of Fe, 1.22 to 1.54 mg of Mn, 1.93 to 2.32 mg of Cu, and 0.91 to 0.95 mg of Co per kg of EBWG for animals with BW varying from 15 to 25 kg, respectively (Table 5).

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Table 5
Prediction of the composition of empty body weight gain (mg/kg) of Zn, Fe, Mn, Cu, and Co at different body weights of Moxotó goats

To calculate the net trace element requirements for live weight gain (mg/kg of BW gain), the values of composition of EBWG (Table 5) were divided by the correction factors that were determined by the BW:EBW ratio, which were calculated as 1.26, 1.22, and 1.20 and corresponded to animals with BW of 15, 20, and 25 kg BW, respectively. Our findings indicate that the net requirement for weight gain ranged from 24.15 (30.43/1.26) to 29.78 (35.74/1.20) mg of Zn, 42.44 (53.48/1.26) to 59.03 (70.84/1.20) mg of Fe, 0.97 (1.22/1.26) to 1.28 (1.54/1.20) mg of Mn, 1.53 (1.93/1.26) to 1.93 (2.32/1.20) mg of Cu, and 0.72 (0.91/1.26) to 0.79 (0.95/1.20) mg of Co per kg of BW gain when the BW ranged from 15 to 25 kg, respectively.

Discussion

A positive contribution of concentrate supplementation to growth performance and body composition of grazing goats was demonstrated in this study. Similar results were reported by Silva et al. (2013)Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179., who showed that the EBW, EBWG, and trace element content of Canindé goats with BW varying from 15 to 25 kg increased as feed intake level increased. In this study, we found that when the Zn, Fe, Cu, and Co contents were expressed based on the metabolic weight (mg/kg^0.75 of EBW) (Table 3), a linear increase was observed in response to the increased level of supplementation. This concentration pattern may have been a reflection of the increased mineral intake and weight gain, which led to a better body development of the animals as the increase in BW has been noted as one of the main discriminating factors in body composition (Mahgoub and Lu, 1998Mahgoub, O. and Lu, C. D. 1998. Growth, body and carcass tissue distribution in goats of large and small sizes. Small Ruminant Research 27:267-278.; Bellof and Pallauf, 2007Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834.; Fernandes et al., 2007Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Fernandes, J. S.; Silva, H. M.; Carstens, G. E.; Teixeira, I. A. M. A. and Akinaga, L. 2007. Energy and protein requirements for maintenance and growth of Boer crossbred kids. Journal of Animal Science 85:1014-1023.; Araújo et al., 2010Araújo, M. J.; Medeiros, A. N.; Teixeira, I. A. M. A.; Costa, R. G.; Marques, C. A. T.; Resende, K. T. and Mello, G. M. P. 2010. Mineral requirements for growth of Moxotó goats grazing in the semi-arid region of Brazil. Small Ruminant Research 93:1-9.; Fernandes et al., 2012Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Teixeira, I. A. M. A.; Fernandes Jr, J. S. 2012. Macromineral requirements for the maintenance and growth of Boer crossbred kids. Journal of Animal Science 90:458-4466.; Teixeira et al., 2013Teixeira, I. A. M. A.; Resende, K. T.; Silva, A. M. A.; Silva Sobrinho, A. G.; Härter, C. J. and Sader, A. P. O. 2013. Mineral requirements for growth of wool and hair lambs. Revista Brasileira de Zootecnia 42:347-353.).

Silva et al. (2013)Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179. observed that trace element concentrations in the empty body of Canindé goats increased as feed intake levels increased. In lambs, Bellof and Pallauf (2007)Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834. observed a similar concentration pattern to the one presented in this study, reporting that the concentration of Zn and Mn increased during the growing period and there was a decrease in the concentration of Fe and Cu as BW increased. On the other hand, Zang et al. (2015)Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481. found that for each gender (males and females) of Dorper × Hu crossbred lambs, Fe, Mn, Cu, and Zn concentrations slightly decreased as BW increased, except for zinc concentration in males.

Data on trace elements in body compositions are scarce and conflicting. In the literature, however, there are some data on the deposition of trace elements in specific organs and tissues. Among these reports, Suttle (1979)Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96. found that mean concentrations of manganese for groups of lamb carcasses (18 to 69 kg BW) fell within the ranges 0.7-1.2 mg/kg fresh carcass weight, respectively. Years later, Grace (1983)Grace, N. D. 1983: The mineral requirements of grazing ruminants. Occasional Publication. New Zealand Society of Animal Production, Palmerston North. reported that the concentration of manganese varied from 0.5 to 3.9 mg/kg of DM in the carcasses of sheep and cattle. In adult sheep, the concentration of manganese is elevated in the liver (4.2 mg/kg of DM), followed by the pancreas (1.7 mg/kg of DM) and kidneys (1.2 mg/kg of DM) and the concentration is less than 0.3 mg/kg of DM in other tissues. Haenlein and Anke (2011)Haenlein, G. F. W. and Anke, M. 2011. Mineral and trace element research in goats: A review. Small Ruminant Research 95:2-19. verified increased amounts of manganese in the liver (10.1 mg/kg of DM), ribs (9.7 mg/kg of DM) and pancreas (7.0 mg/kg of DM) of goats fed normal amounts of this element. In the present study, the concentrations of manganese in the empty body varied from 0.25 to 0.40 mg/kg of DM when the BW varied from 15 to 25 kg, respectively.

The liver is one of the main organs for copper storage (200 to 300 mg/kg of DM). The concentration of copper in the carcass is relatively low with values of 1.2 mg/kg fresh weight in sheep and 0.8 mg/kg fresh weight in cattle (Grace, 1983Grace, N. D. 1983: The mineral requirements of grazing ruminants. Occasional Publication. New Zealand Society of Animal Production, Palmerston North.). In the present study, copper values of 1.45 and 1.75 mg/kg of EBW were found in animals with BW varying from 15 to 25 kg, respectively, which were different from the values reported for sheep and cattle. These results may indicate divergences in the nutritional requirements between these species. Zhang et al. (2015)Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481., reported that Fe, Mn, and Cu concentrations in Dorper × Hu lambs were greater in viscera (blood included) and zinc concentration was higher in fleece than other body tissues and that viscera tissue had more than 56, 60, and 71% of the total Fe, Mn, and Cu, respectively, in the empty body. The main pool of zinc was the tissues of bone and muscle, which had more than 32 and 36% of the total zinc, respectively, in the empty body.

Studies have also demonstrated that the retention of trace elements (mg/kg of EBWG) is influenced by the nutrition plan, sex, and final body weight (Bellof and Pallauf, 2007Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834.; Ji, et al., 2014; Silva et al., 2013Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179.; Zhang et al., 2015Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481.). Ji et al. (2014)Ji, S. K.; Xu, G. S.; Diao, Q. Y.; Jiang, C. G.; Deng, K. D.; Tua, Y. and Zhang, N. F. 2014. Net zinc requirements of Dorper × thin-tailed Han crossbred lambs. Livestock Science 167:178-185. observed that concentrations of zinc ranged from 29 to 30 mg/kg EBWG for ram lambs and 29 to 28 mg/kg EBW for ewe lambs, which were slightly lower than our findings. Bellof and Pallauf (2007)Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834., working with German Merino Land sheep, reported an average of 26.1 mg Fe, 1.04 mg Mn, 1.41 mg Cu, and 30.0 mg Zn/kg of EBWG for the animals with body weight varying from 18 to 55 kg, respectively. Silva et al. (2013)Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179. observed that trace contents in Canindé goats ranged between 13.96 and 14.20 mg for Fe, 9.56 and 10.26 mg for Zn, 6.37 and 6.38 mg for Mn, and 5.86 and 7.90 mg/kg of EBWG, respectively, for animals with 15 and 25 kg BW, which is slightly lower than our findings.

Trace elements serve as structural components of several metalloenzymes such as glutathione catalase (Fe) and superoxide dismutase (Cu and Zn). Metalloenzymes are required for a wide range of metabolic activities such as energy production, protein digestion, cell replication, antioxidant activity, and wound healing (McDowell, 1992McDowell, L. R. 1992. Minerals in animal and human nutrition. Academic Press, London.). However, nutritional requirements of trace minerals for goats are scarce. In a recent study, Ji et al. (2014)Ji, S. K.; Xu, G. S.; Diao, Q. Y.; Jiang, C. G.; Deng, K. D.; Tua, Y. and Zhang, N. F. 2014. Net zinc requirements of Dorper × thin-tailed Han crossbred lambs. Livestock Science 167:178-185. found that the net zinc requirement for growth decreased from 23.4 to 23.2 mg/kg BW gain for ram lambs and 23.8 to 22.1 mg/kg BW gain for ewe lambs as the BW increased from 20 to 35 kg. On the other hand, Zang et al. (2015) found that the net requirements for growth decreased from 56.60 to 49.40 mg Fe, from 0.30 to 0.22 mg Mn, and from 3.00 to 2.40 mg Cu per kg of BW gain and increased from 22.70 to 23.00 mg Zn per kg of BW gain for males, while decreased from 24.70 to 17.60 mg Fe, from 0.35 to 0.25 mg Mn, from 2.30 to 1.70 mg Cu, and from 22.30 to 20.50 mg Zn per kg of BW gain for females from 20 to 35 kg BW, respectively.

The recommendations of zinc for growth adopted by the NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. for goats are 25 mg of Zn/kg of BW gain, which are similar to the value found in this research (24.15 to 29.79 mg of Zn/kg of BW gain). Suttle (1979)Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96. reported that the value of 24 mg/kg carcass gain was taken to represent the approximate net growth requirements of lambs. This value has been widely adopted for ruminant nutritional systems (NRC, 2007NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.; Suttle, 2010Suttle, N. F. 2010. Mineral nutrition of Livestock, 4th ed. CAB International, Oxfordshire, UK.). Therefore, the results presented in this paper are consistent with these general findings.

For goats, the NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. determined that factorial approach to calculating iron requirements was not justified because of the lack of data. It has been reported that dietary requirements for goats are higher than for sheep because they are more often affected by internal parasites; in addition, older animals have lower needs, because considerable recycling of iron occurs when red blood cells turn over (Underwood, 1977Underwood, E. J. 1977. Trace elements in human and animal nutrition. 4th ed. Academic Press, London.); and in older animals, blood volume does not increase as it does for younger animals (NRC, 2007NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.). Net iron requirements in this study (42.45 to 59.03 mg of Fe/BW gain) were similar to those recommended by NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. for growing sheep (55 mg of Fe/kg of BW gain) and to those found by Zang et al. (2015)Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481. for males (56.60 to 49.40 mg of Fe/BW gain); however; they were greater than those observed for females (24.70 to 17.60 mg of Fe/BW gain). In our study, all the net requirements for growth were higher than those observed by Silva et al. (2013)Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179. working with animals in similar conditions to those of this study. According to Zang et al. (2015)Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481., these differences might be related, in part, to breed, feed, management practices, and physiological and environmental conditions.

Manganese is an essential mineral in the ration of goats, required for skeletal development and reproductive efficiency. Suttle (1979)Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96. reported that values of 0.85 mg/kg carcass gain were taken to represent the approximate net growth requirements of lambs for manganese. According to NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC., the amount of manganese deposited in the weight gain is estimated as 0.70 and 0.47 mg/kg of BW for goats and sheep, respectively. According to Zang et al. (2015), the net requirements for growth varied from 0.30 to 0.22 mg Mn/kg of BW gain for males and from 0.35 to 0.25 mg Mn/kg of BW gain for females from 20 to 35 kg BW, respectively. Comparing these results with those given in the present study (0.97 to 1.29 mg of Mn/kg of BW gain), the manganese net requirements for gain for the Moxotó goats from 15 and 25 kg of BW were about 28% and 46% higher, respectively, than those reported by the NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. for goats. These findings indicate that the manganese net requirements for growth are higher in goats than in sheep. Animals of different genotypes are well known to exhibit differences in their mineral requirements due to the differences in their body composition (Teixeira et al., 2013Teixeira, I. A. M. A.; Resende, K. T.; Silva, A. M. A.; Silva Sobrinho, A. G.; Härter, C. J. and Sader, A. P. O. 2013. Mineral requirements for growth of wool and hair lambs. Revista Brasileira de Zootecnia 42:347-353.).

Copper is an essential trace element that plays an important role in the biochemical reactions of the body; however, its requirement and interaction with other minerals is not clearly understood (Solaiman et al., 2006Solaiman, S. G.; Shoemaker, C. E. and D’Andrea, G. H. 2006. The effect of high dietary Cu on health, growth performance, and Cu status in young goats. Small Ruminant Research 66:85-91.). In an attempt to define its requirements for growth of lambs, Sutlle (1979)Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96. considered the value of <1.0 mg/kg carcass gain an overestimate of the net growth requirement, therefore suggesting that the true value should be closer to that of 0.45 mg/kg of BW gain estimated for calves of marginally adequate copper status (Sutlle, 1979Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96.). CSIRO (2007)CSIRO - Commonwealth Scientific and Industrial Research Organization. 2007. Nutrient requirements of domesticated ruminants. CSIRO Publishing, Collingwood, Australia. recommends net requirements of 0.27 mg Cu/day for one year-old sheep, with 40 kg of BW and 0.1 kg/day gain. The NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. determined that factorial approach to calculate copper requirements was not justified because of a lack of data. However, for sheep, the net requirement recommendation of the NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC. for growth is 1.06 μg Cu per kg of live weight gain using factorial method. This indicated that the net copper requirements for growth of Moxotó goats (1.53 to 1.59 mg/kg BW gain) were higher than the recommendations of the NRC (2007)NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC..

Results presented by Suttle (1979)Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96. indicated that the extent to which Cu is deposited in tissues influenced the Cu concentrations in the whole carcass. Therefore, these researchers suggested that the net growth requirement for coper must, therefore, either be derived from minced carcasses that exclude the liver or from animals that have at no time received more dietary copper than they require. On the other hand, the major concentration of copper in goats is not only in the liver (10 mg/kg of DM), but in other tissues such as brain (14 mg/kg of DM) and heart muscle (13 mg/kg of DM), as reported by Haenlein and Anke (2011)Haenlein, G. F. W. and Anke, M. 2011. Mineral and trace element research in goats: A review. Small Ruminant Research 95:2-19.. Therefore, it is possible that such inconsistencies may be related to differences in experimental conditions. Accordingly, more research is necessary to evaluate body composition in copper to better establish mineral requirements for different goat genotypes to obtain a more efficient and economic production system.

There is a paucity of information available relative to the net requirements of cobalt for goats. Therefore, dietary cobalt requirements are used. In this study, cobalt presented the lowest retention in empty body gain, which may have been due to the low requirements of this mineral in body tissues (Table 5). Similarly to other trace elements, the net requirements of cobalt increased as BW and weight gain rate increased. Cobalt is important in ruminants because it is required by ruminal microorganisms to synthesize vitamin B₁₂. Consequently, diets containing inadequate amounts of cobalt result in vitamin B₁₂ deficiencies. It is commonly assumed that the minimum daily requirement of cobalt specified for sheep is adequate for goats. However, this assumption appears not to be valid for all goat breeds (Johnson et al., 2004Johnson, E. H.; Al-Habsi, K.; Kaplan, E.; Srikandakumar, A.; Kadim, I. T.; Annamalai, K.; Al-Busaidy, R. and Mahgoub, O. 2004. Caprine hepatic lipidosis induced through the intake of low levels of dietary cobalt. Veterinary Journal 168:174-179.). Some authors have demonstrated that goats fed a diet containing the minimum daily requirement of cobalt as specified for sheep developed poor hair coats, weight loss, and reduction in erythrocyte counts and hemoglobin.

According to Suttle (2010)Suttle, N. F. 2010. Mineral nutrition of Livestock, 4th ed. CAB International, Oxfordshire, UK., net mineral requirements underestimate gross dietary needs for minerals because ingested minerals are incompletely absorbed, the degree of underestimate being inversely related to the efficiency with which a given mineral is absorbed from a given diet. However, the main advantage of the factorial approach is that requirements can be predicted for a wide range of production circumstances, provided that reliable data are available for each model component (ARC, 1980ARC - Agriculture and Research Council. 1980: The nutrient requirements of ruminant livestock. CAB International, Wallingford, UK.; White, 1996White, C. L. 1996. Understanding the mineral requirements of sheep. p.15-29. In: Detection and treatment of mineral nutrition problems in grazing sheep. Masters, D. G. and White, C. L., eds. ACIAR Monograph 37, Canberra.). Therefore, these extrapolated nutrient recommendations can be used as a starting point for the minimum suggested nutrient requirements and concentrations in formulating diets (Robert and Van, 2006Robert, J. and Van, S. 2006. Nutrient requirements of South American camelids: a factorial approach. Small Ruminant Research 61:165-186.).

This research is one of the few to provide information on trace mineral requirements for indigenous goats using the factorial approaches. Thus, it is difficult to compare these results with values generated with similar animals to the ones used in this research. Therefore, new studies on the nutrient requirements should be undertaken, including different breeds in different environments because of the influence of breed and environment on the requirements of the animals. Thus, these differences must be taken into account when a diet is formulated.

Conclusions

The net zinc, iron, manganese, copper, and cobalt requirements of Moxotó goat kids grazing in the semiarid region increases as feed intake level and their body weight increase from 15 to 25 kg. In addition, our study reveals that body weight changes affects more the deposition of iron and manganese in empty body weight gain than other trace elements.

Acknowledgments

The authors would like to thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and the Banco do Nordeste do Brasil for financial support.

References

AOAC - Association of Official Analytical Chemistry. 1990. Official methods of analysis. 15th ed. AOAC International, Washington, DC.
Araújo, M. J.; Medeiros, A. N.; Teixeira, I. A. M. A.; Costa, R. G.; Marques, C. A. T.; Resende, K. T. and Mello, G. M. P. 2010. Mineral requirements for growth of Moxotó goats grazing in the semi-arid region of Brazil. Small Ruminant Research 93:1-9.
ARC - Agriculture and Research Council. 1980: The nutrient requirements of ruminant livestock. CAB International, Wallingford, UK.
Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834.
CSIRO - Commonwealth Scientific and Industrial Research Organization. 2007. Nutrient requirements of domesticated ruminants. CSIRO Publishing, Collingwood, Australia.
Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Fernandes, J. S.; Silva, H. M.; Carstens, G. E.; Teixeira, I. A. M. A. and Akinaga, L. 2007. Energy and protein requirements for maintenance and growth of Boer crossbred kids. Journal of Animal Science 85:1014-1023.
Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Teixeira, I. A. M. A.; Fernandes Jr, J. S. 2012. Macromineral requirements for the maintenance and growth of Boer crossbred kids. Journal of Animal Science 90:458-4466.
Grace, N. D. 1983: The mineral requirements of grazing ruminants. Occasional Publication. New Zealand Society of Animal Production, Palmerston North.
Haenlein, G. F. W. and Anke, M. 2011. Mineral and trace element research in goats: A review. Small Ruminant Research 95:2-19.
Ji, S. K.; Xu, G. S.; Diao, Q. Y.; Jiang, C. G.; Deng, K. D.; Tua, Y. and Zhang, N. F. 2014. Net zinc requirements of Dorper × thin-tailed Han crossbred lambs. Livestock Science 167:178-185.
Johnson, E. H.; Al-Habsi, K.; Kaplan, E.; Srikandakumar, A.; Kadim, I. T.; Annamalai, K.; Al-Busaidy, R. and Mahgoub, O. 2004. Caprine hepatic lipidosis induced through the intake of low levels of dietary cobalt. Veterinary Journal 168:174-179.
Mahanti, H. and Barnes, R.M. 1983. Determination of major and trace elements in bone by Determination of major, minor and trace elements in bone by inductively-coupled plasma emission spectrometry. Analytica Chimica Acta 151:409-417.
Mahgoub, O. and Lu, C. D. 1998. Growth, body and carcass tissue distribution in goats of large and small sizes. Small Ruminant Research 27:267-278.
McDowell, L. R. 1992. Minerals in animal and human nutrition. Academic Press, London.
NRC - National Research Council. 1981. Nutrient requirements of goats: Angora, dairy, and meat goats in temperate and tropical countries. National Academy of Sciences, Washington, DC.
NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.
Ramírez-Perez, A. H.; Buntinx, S. E. and Rosiles, R. 2000. Effect of breed and age on the voluntary intake and the micromineral status of non-pregnant sheep II. Micromineral status. Small Ruminant Research 37:231-242.
Robert, J. and Van, S. 2006. Nutrient requirements of South American camelids: a factorial approach. Small Ruminant Research 61:165-186.
Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179.
Solaiman, S. G.; Shoemaker, C. E. and D’Andrea, G. H. 2006. The effect of high dietary Cu on health, growth performance, and Cu status in young goats. Small Ruminant Research 66:85-91.
Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96.
Suttle, N. F. 2010. Mineral nutrition of Livestock, 4th ed. CAB International, Oxfordshire, UK.
Teixeira, I. A. M. A.; Resende, K. T.; Silva, A. M. A.; Silva Sobrinho, A. G.; Härter, C. J. and Sader, A. P. O. 2013. Mineral requirements for growth of wool and hair lambs. Revista Brasileira de Zootecnia 42:347-353.
Tilley, J. M. A. and Terry, R. A. 1963. A two stage technique for the in vitro digestion of forage crops. Journal of the British Grassland Society 18:104-111.
Underwood, E. J. 1977. Trace elements in human and animal nutrition. 4th ed. Academic Press, London.
Underwood, E. J. and Suttle, N. F. 1999. The mineral nutrition of Livestock. 3rd ed. CABI Publishing, NY, USA.
Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481.
White, C. L. 1996. Understanding the mineral requirements of sheep. p.15-29. In: Detection and treatment of mineral nutrition problems in grazing sheep. Masters, D. G. and White, C. L., eds. ACIAR Monograph 37, Canberra.

Publication Dates

Publication in this collection
Mar 2017

History

Received
16 Apr 2016
Accepted
6 Nov 2016

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

[1] AOAC - Association of Official Analytical Chemistry. 1990. Official methods of analysis. 15th ed. AOAC International, Washington, DC.

[2] Araújo, M. J.; Medeiros, A. N.; Teixeira, I. A. M. A.; Costa, R. G.; Marques, C. A. T.; Resende, K. T. and Mello, G. M. P. 2010. Mineral requirements for growth of Moxotó goats grazing in the semi-arid region of Brazil. Small Ruminant Research 93:1-9.

[3] ARC - Agriculture and Research Council. 1980: The nutrient requirements of ruminant livestock. CAB International, Wallingford, UK.

[4] Bellof, G. and Pallauf, J. 2007. Deposition of copper, iron, manganese and zinc in empty body growing of lambs of the breed German Merino Land sheep. Animal 6:827-834.

[5] CSIRO - Commonwealth Scientific and Industrial Research Organization. 2007. Nutrient requirements of domesticated ruminants. CSIRO Publishing, Collingwood, Australia.

[6] Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Fernandes, J. S.; Silva, H. M.; Carstens, G. E.; Teixeira, I. A. M. A. and Akinaga, L. 2007. Energy and protein requirements for maintenance and growth of Boer crossbred kids. Journal of Animal Science 85:1014-1023.

[7] Fernandes, M. H. M. R.; Resende, K. T.; Tedeschi, L. O.; Teixeira, I. A. M. A.; Fernandes Jr, J. S. 2012. Macromineral requirements for the maintenance and growth of Boer crossbred kids. Journal of Animal Science 90:458-4466.

[8] Grace, N. D. 1983: The mineral requirements of grazing ruminants. Occasional Publication. New Zealand Society of Animal Production, Palmerston North.

[9] Haenlein, G. F. W. and Anke, M. 2011. Mineral and trace element research in goats: A review. Small Ruminant Research 95:2-19.

[10] Ji, S. K.; Xu, G. S.; Diao, Q. Y.; Jiang, C. G.; Deng, K. D.; Tua, Y. and Zhang, N. F. 2014. Net zinc requirements of Dorper × thin-tailed Han crossbred lambs. Livestock Science 167:178-185.

[11] Johnson, E. H.; Al-Habsi, K.; Kaplan, E.; Srikandakumar, A.; Kadim, I. T.; Annamalai, K.; Al-Busaidy, R. and Mahgoub, O. 2004. Caprine hepatic lipidosis induced through the intake of low levels of dietary cobalt. Veterinary Journal 168:174-179.

[12] Mahanti, H. and Barnes, R.M. 1983. Determination of major and trace elements in bone by Determination of major, minor and trace elements in bone by inductively-coupled plasma emission spectrometry. Analytica Chimica Acta 151:409-417.

[13] Mahgoub, O. and Lu, C. D. 1998. Growth, body and carcass tissue distribution in goats of large and small sizes. Small Ruminant Research 27:267-278.

[14] McDowell, L. R. 1992. Minerals in animal and human nutrition. Academic Press, London.

[15] NRC - National Research Council. 1981. Nutrient requirements of goats: Angora, dairy, and meat goats in temperate and tropical countries. National Academy of Sciences, Washington, DC.

[16] NRC - National Research Council. 2007. Nutrient requirements of small ruminants: sheep, goats, cervids, and new world camelids. 1st rev. ed. National Academy Press, Washington, DC.

[17] Ramírez-Perez, A. H.; Buntinx, S. E. and Rosiles, R. 2000. Effect of breed and age on the voluntary intake and the micromineral status of non-pregnant sheep II. Micromineral status. Small Ruminant Research 37:231-242.

[18] Robert, J. and Van, S. 2006. Nutrient requirements of South American camelids: a factorial approach. Small Ruminant Research 61:165-186.

[19] Silva, C. M.; Medeiros, A. N.; Costa, R. G.; Sales, E. P.; Silva, A. M. A. and Lima Jr, V. L. 2013. Micromineral nutritional requirements for weight gain in Canindé goats under grazing in the Brazilian semiarid. Acta Scientiarum - Animal Sciences 35:173-179.

[20] Solaiman, S. G.; Shoemaker, C. E. and D’Andrea, G. H. 2006. The effect of high dietary Cu on health, growth performance, and Cu status in young goats. Small Ruminant Research 66:85-91.

[21] Suttle, N. F. 1979. Copper, iron, manganese and zinc concentrations in the carcass of lambs and calves and the relationship to trace element requirements for growth. British Journal of Nutrition 42:89-96.

[22] Suttle, N. F. 2010. Mineral nutrition of Livestock, 4th ed. CAB International, Oxfordshire, UK.

[23] Teixeira, I. A. M. A.; Resende, K. T.; Silva, A. M. A.; Silva Sobrinho, A. G.; Härter, C. J. and Sader, A. P. O. 2013. Mineral requirements for growth of wool and hair lambs. Revista Brasileira de Zootecnia 42:347-353.

[24] Tilley, J. M. A. and Terry, R. A. 1963. A two stage technique for the in vitro digestion of forage crops. Journal of the British Grassland Society 18:104-111.

[25] Underwood, E. J. 1977. Trace elements in human and animal nutrition. 4th ed. Academic Press, London.

[26] Underwood, E. J. and Suttle, N. F. 1999. The mineral nutrition of Livestock. 3rd ed. CABI Publishing, NY, USA.

[27] Zhang, H.; Nie, H. T.; Wang, Q.; Wang, Z.Y.; Zhang, Y.L.; Guo, R.H. and Wang, F. 2015. Trace element concentrations and distributions in the main body tissues and the net requirements for maintenance and growth of Dorper × Hu lambs. Journal of Animal Science 93:2471-2481.

[28] White, C. L. 1996. Understanding the mineral requirements of sheep. p.15-29. In: Detection and treatment of mineral nutrition problems in grazing sheep. Masters, D. G. and White, C. L., eds. ACIAR Monograph 37, Canberra.

Ingredient	Composition (g/ kg of DM)	Chemical analysis

		g/ kg of DM		GE	mg/kg of DM

		DM	CP		Copper	Zinc	Iron	Manganese	Cobalt
Corn meal¹	580	870.6	93.9	4.68	0.33	61.22	28.03	14.63	1.37
Soybean meal	270	866.4	458.3	4.51	0.67	54.21	44.96	24.97	1.70
Wheat meal	50	888.8	150.8	4.26	1.16	93.72	57.36	107.92	1.52
Cotton meal	50	866.8	336.0	4.13	0.61	36.15	6.57	8.88	1.85
Limestone	10	-	-	-	0.82	16.05	1218.69	44.04	17.68
Premix	40	-	-	-	86.30	1429.55	3078.79	809.85	64.75
Total	1000	875.8	202.5	4.35	3.92	113.98	166.93	53.90	4.19
Extrusa	-	231.0	118.7	3.48	8.28	51.56	172.36	81.84	3.94

Item	Baseline	Supplementation level (% of BW)				SEM	P-value

		0	0.5	1.0	1.5		L	Q
Number of kids	4	7	8	8	8	-	-	-
Days on feed	-	150	150	150	150	-	-	-
Initial BW (kg)	15.38	15.76	15.73	15.71	15.73	-	-	-
Final BW (kg)	15.38	18.40	21.04	22.94	25.69	0.93	<0.0001	0.89
SBW (kg)	13.91	16.82	19.44	21.25	23.42	0.81	<0.0001	0.73
EBW (kg)	11.15	13.09	15.58	17.69	19.72	0.72	<0.0001	0.68
ADG (g/d)	-	15.74	34.29	49.56	69.83	5.80	<0.0001	0.82
EBWG (g/d)	-	10.49	27.09	43.16	58.57	4.47	<0.0001	0.91
DMI (g/d)	-	569.67	703.73	772.34	789.80	14.12	<0.0001	<0.0001
Fat (g/kg of EBW)	68.12	74.97	96.21	107.37	145.26	10.04	<0.0001	0.24
Protein (g/kg of EBW)	154.44	154.71	162.54	165.22	169.56	4.08	0.001	0.56
Water (g/kg of EBW)	709.63	705.32	674.25	655.66	631.95	11.80	<0.0001	0.72
Ash (g/kg of EBW)	45.32	45.41	44.95	46.02	44.56	1.66	0.85	0.77
Zn (mg/100 g of EBW)	2.30	2.45	2.51	2.61	2.73	0.10	0.03	0.61
Fe (mg/100 g of EBW)	3.80	4.68	3.96	4.48	4.90	0.34	0.43	0.11
Mn (mg/100 g of EBW)	0.07	0.11	0.10	0.12	0.10	0.01	0.91	0.53
Co (mg/100 g of EBW)	0.08	0.09	0.08	0.08	0.09	0.004	0.36	0.06
Cu (mg/100 g of EBW)	0.14	0.15	0.19	0.18	0.17	0.02	0.42	0.14

Item	Baseline	Supplementation level (% of BW)				SEM	P-value

		0	0.5	1.0	1.5		L	Q
EBW (kg)	11.15	13.09	15.58	17.69	19.72	0.72	<0.0001	0.68
Zn (mg/kg^0.75 of EBW)	41.95	49.22	56.02	62.34	69.39	3.52	<0.0001	0.85
Fe (mg/kg^0.75 of EBW)	56.34	93.52	89.37	106.73	124.61	9.09	0.004	0.15
Mn (mg/kg^0.75 of EBW)	1.27	2.21	2.29	2.89	2.59	0.31	0.16	0.47
Co (mg/kg^0.75 of EBW)	1.47	1.74	1.87	1.93	2.37	0.10	<0.0001	0.06
Cu (mg/kg^0.75 of EBW)	2.58	2.92	4.12	4.23	4.34	0.35	0.008	0.11
Zn (mg/100 g of EBW fat-free)	2.53	2.71	2.85	3.01	3.23	0.13	0.0006	0.57
Fe (mg/100 g of EBW fat-free)	3.40	5.18	4.50	5.16	5.83	0.41	0.15	0.11
Mn (mg/100 g of EBW fat-free)	0.08	0.12	0.18	0.14	0.12	0.01	0.76	0.55
Co (mg/100 g of EBW fat-free)	0.09	0.10	0.10	0.09	0.11	0.004	0.05	0.06
Cu (mg/100 g of EBW fat-free)	0.16	0.16	0.21	0.20	0.20	0.02	0.19	0.16

Item	Regression equation	R²	RMSE	P-value	Body weight¹ (kg)

					15	20	25
EBW (kg)	EBW = –1.6334 ( ±0.53) + [0.9017 (±0.02) × SBW]	0.97	0.50	<0.0001	11.89	16.40	20.91
Zn (mg/kg of EBW)	Log₁₀ Zn = 1.0678 (±0.09) + [1.2852 (±0.07) × log₁₀ EBW]	0.92	0.03	<0.0001	23.68	25.95	27.81
Fe (mg/kg of EBW)	Log₁₀ Fe = 1.0171 (±0.23) + [1.4981 (±0.19) × log₁₀ EBW]	0.69	0.09	<0.0001	35.70	41.90	47.29
Mn (mg/kg of EBW)	Log₁₀ Mn = –0.5166 (±0.34) + [1.4189 (±0.28) × log₁₀ EBW]	0.46	0.14	<0.0001	0.86	0.98	1.09
Cu (mg/kg of EBW)	Log₁₀ Cu = –0.1894 (±0.29) + [1.3269 (±0.24) × log₁₀ EBW]	0.50	0.12	<0.0001	1.45	1.61	1.75
Co (mg/kg of EBW)	Log₁₀ Co = –0.1754 (±0.13) + [1.0885 (±0.10) × log₁₀ EBW]	0.79	0.05	<0.0001	0.83	0.86	0.87

Item	Body weight (kg)			Equation¹

	15	20	25
EBW (kg)	11.89	16.40	20.91
Zn (mg/kg of EBWG)	30.43	33.35	35.74	15.02 × EBW^0.2851
Fe (mg/kg of EBWG)	53.48	62.77	70.84	15.58 × EBW^0.4981
Mn (mg/kg of EBWG)	1.22	1.39	1.54	0.43 × EBW^0.4189
Cu (mg/kg of EBWG)	1.93	2.14	2.32	0.86 × EBW^0.3269
Co (mg/kg of EBWG)	0.91	0.93	0.95	0.73 × EBW^0.0886