Reducing calcium and phosphorus in crossbred beef cattle diets: impacts on productive performance during the growing and finishing phase
L. F. Prados A C , S. C. Valadares Filho A , S. A. Santos A , D. Zanetti A , A. N. Nunes A , D. R. Costa A , L. D. S. Mariz A , E. Detmann A , P. M. Amaral A , F. C. Rodrigues A and R. F. D. Valadares BA Universidade Federal de Viçosa, Department of Animal Science, 36570-000, Viçosa, MG, Brazil.
B Universidade Federal de Viçosa, Department of Veterinary Medicine, 36570-000, Viçosa, MG, Brazil.
C Corresponding author. Email: laurafrancoprados@hotmail.com
Animal Production Science 56(10) 1643-1649 https://doi.org/10.1071/AN14781
Submitted: 23 May 2014 Accepted: 20 February 2015 Published: 21 May 2015
Abstract
Forty 3/4 Bos indicus × 1/4 Bos taurus bulls (initial bodyweight = 214 ± 4 kg; 11 ± 0.2 months) were used in the study. Four bulls were slaughtered as reference and the other 36 bulls were allowed ad libitum consumption of treatment diets following a completely randomised 3 × 3 factorial design. The design included three diet concentrations of calcium (Ca) and phosphorus (P): standard, 50% of standard, and 75% of standard and three periods of feedlot confinement: 8, 16, and 24 weeks with four bulls per treatment combination. The diets were isonitrogenous and consisted of 60 : 40 corn silage to concentrate. Dry matter intake, crude protein, ether extract, organic matter, non-fibrous carbohydrates, Ca, and P, expressed as kg/day, were greater (P < 0.05) for bulls confined for longer periods. Nutrient digestibility and average daily gain was not affected (P > 0.05) by Ca and P concentration of diet or by feedlot phase. Dressing were decreased (P < 0.05) for bulls that remained in confinement for a shorter period. The daily maintenance requirements of Ca and P were 13.66 and 21.51 mg/kg empty bodyweight, respectively, and the absorption coefficients of Ca and P were 0.70 and 0.67, respectively. We concluded that for crossbred cattle in the feedlot, dietary levels of Ca and P recommended by BR-CORTE (2010), NRC (2000), and AFRC (1991) could be reduced by 62%, 66%, and 57%, respectively, for Ca and by 14%, 15%, and 43%, respectively, for P with significant savings in costs. This study shows that Ca and P can be reduced to 1.8 and 2.2 g/kg DM respectively, in the diets for crossbred cattle in feedlot.
Additional keywords: absorption coefficients, average day gain, mineral requirements.
References
AFRC (1991) AFRC Technical Committee on Responses to Nutrients, Report 6. A reappraisal of the calcium and phosphorus requirements of sheep and cattle. Nutrition Abstracts and Reviews 61, 573–612.AOAC (1990) ‘Official methods of analysis.’ 15th edn. (Association of Official Analytical Chemists: Arlington, VA)
ARC (1980) ‘The nutrient requirements of ruminant livestock.’ Technical Review. (Commonwealth Agricultural Bureaux: Farnham Royal, UK)
BR-CORTE (2010) ‘Exigências nutricionais de zebuínos puros e cruzados.’ 2nd edn. (Suprema: Visconde do Rio Branco, MG) Available at http://cqbal.agropecuaria.ws/webcqbal/brcorte/brcorte2010_eng.php [Verified 10 March 2015]
Call JW, Butcher JE, Blake JT, Smart RA, Shupe JL (1978) Phosphorus influence on growth and reproduction of beef cattle. Journal of Animal Science 47, 216–225.
Detmann E, Valadares Filho SC (2010) On the estimation of non-fibrous carbohydrates in feeds and diets. Arquivo Brasileiro de Medicina Veterinária e Zootecnia 62, 980–984.
| On the estimation of non-fibrous carbohydrates in feeds and diets.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXkt1Cgtrs%3D&md5=e948d3cad9bfc63b48d4f839adcb069cCAS |
Di Marco ON (1994) ‘Crecimiento y respuesta animal.’ 1st edn. (Associación Argentina de Producción Animal – AAPA: Balcarce)
Duncan DL (1958) The interpretation of studies of calcium and phosphorus balance in ruminants. Nutrition Abstracts and Reviews 28, 695–715.
Ellenberger HB, Newlander JA, Jones CH (1950) Composition of the bodies of dairy cattle. Vermont Agricultural Experimental Station 558, 3–66.
Erickson GE, Klopfenstein TJ, Milton CT, Hanson D, Calkins C (1999) Effect of dietary phosphorus on finishing steer performance, bone status and carcass maturity. Journal of Animal Science 77, 2832–2836.
Geisert BG, Erickson GE, Klopfenstein TJ, Luebbe MK (2005) Effects of dietary phosphorus level in beef finishing diets on phosphorus excretion characteristics. Nebraska Beef Cattle Reports. pp. 50–53. (University of Nebraska–Lincoln: Lincoln, NE) Available at http://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1164&context=animalscinbcr [Verified 27 April 2015]
Geisert BG, Erickson GE, Klopfenstein TJ, Macken CN, Luebbe MK, MacDonald JC (2010) Phosphorus requirement and excretion of finishing beef cattle fed different concentrations of phosphorus. Journal of Animal Science 88, 2393–2402.
| Phosphorus requirement and excretion of finishing beef cattle fed different concentrations of phosphorus.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXos1Kmtr4%3D&md5=4924f6d667c34f36532f9e675ea3aa31CAS | 20348380PubMed |
Goetsch AL, Owens FN (1985) Effects of calcium source and level on site of digestion and calcium levels in the digestive tract of cattle fed high-concentrate diets. Journal of Animal Science 61, 995–1003.
Khorasani GR, Janzen RA, McGill WB, Kennelly JJ (1997) Site and extent of mineral absorption in lactation cows fed whole-crop cereal grain silage or alfalfa silage. Journal of Dairy Science 75, 239–248.
NRC (1976) ‘Nutrient requirements of beef cattle.’ 5th edn. (National Academy Press: Washington, DC)
NRC (2000) ‘Nutrient requirements of beef cattle.’ 7th revised edn. (National Academy Press: Washington, DC)
Paulino MF, Fontes CAA, Jorge AM, Queiroz AC, Silva JFC, Gomes Júnior P (1999) Composição corporal e exigências de macroelementos minerais (Ca, P, Mg, Na e K) de bovinos não castrados de quatro raças zebuínas. Revista Brasileira de Zootecnia 28, 634–641.
| Composição corporal e exigências de macroelementos minerais (Ca, P, Mg, Na e K) de bovinos não castrados de quatro raças zebuínas.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1MXls1Shsb8%3D&md5=258232defeff01797bf2122fa4d89f48CAS |
Sainz RD (1998) Crescimento compensatório em bovinos de corte. In ‘Simpósio sobre produção intensiva de gado de corte’. (Eds JEP Cyrino, JFM Menten, DPD Lanna, VS Miyada) pp. 22–38. (CBNA: Campinas, SP)
Seal CJ, Reynolds CK (1993) Nutritional implications of gastrointestinal and liver metabolism in ruminants. Nutrition Research Reviews 6, 185–208.
| Nutritional implications of gastrointestinal and liver metabolism in ruminants.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2cXkvVWmtrk%3D&md5=125b292f6c650374efdda750be4f4f23CAS | 19094308PubMed |
Suttle NF (2010) ‘Mineral nutrition of livestock.’ 4th edn. (CAB International: Wallingford)
Ternouth JH (1990) Phosphorus and beef production in northern Australia. 3. Phosphorus in cattle – a review. Tropical Grasslands 24, 159–169.
Varner LW, Woods W (1972) Calcium levels in high grain beef cattle rations. Journal of Animal Science 35, 415–417.
Wise MB, Ordoveza AL, Barrick ER (1963) Influence of variations in dietary calcium:phosphorus ratio on performance and blood constituents of calves. The Journal of Nutrition 79, 79–84.