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Feed Restriction and Compensatory Growth in Guzerá Females
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Feed Restriction and Compensatory Growth in Guzerá Females
Neto, S. Gonzaga; Bezerra, L.R.; Medeiros, A.N.; Ferreira, M.A.; Filho, E.C. Pimenta; Candido, E.P.; Oliveira, R.L.;
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This study examined the effect of restricting feed intake and the subsequent compensatory growth in Guzera females. Eighteen animals with an initial age of 21 months and a mean weight of 268.17 kg were placed in three groups according to the alimentary regime: feed ad libitum; feed restricted to 20% dry matter; and feed restricted to 40% dry matter. In the restricted feed phase, the dry mater intake decreased as the restriction levels increased, influencing the reduction in intake of other nutrients. In the realimentation phase, the 40% restricted feed group ingested more dry matter (% BW) and crude protein () than the group fed ad libitum (p<0.001). The serum nutrient concentrations were inversely proportional (p<0.001) to the restriction level, and there was no difference (p>0.001) in the realimentation phase. In the restricted feed phase, the final live weight decreased (p<0.05) as the restriction level increased. For the daily mean weight gain in the control group, there was no difference (p>0.05) compared to the animals with 20% feed restriction, but this was higher than in the group with 40% feed restriction. In the re-alimentation phase, the group with 40% feed restriction achieved higher weight gain rates, which was different from the control and 20% restriction groups. In both phases, the animals in the group with 40% feed restriction presented better feed conversion which was different (p<0.05) from the control group. In the feed restriction phase, it was observed that the intake of N, nitrogen excreted in feces and urine, nitrogen balance and nitrogen retention decreased (p<0.05) with the restriction level. None of the variables were influenced in the re-alimentation phase. These results show that feed restriction by 40% can be adopted as a nutritional management practice.
Compensatory Growth;Metabolites;Nitrogen;Nutrition;Zebu;
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Alves, M., F. Gonzalez, N. Carvalho, P. Mühlbach, V. Lima, T. R. Conceicao and V. Wald. 2004. Feeding dairy cows with soybean by-products: effects on metabolic profile. Ciencia Rural, 34(1):239-243. crossref(new window)

Amstalden, M., M. R. Garcia, R. L. Stanko, S. E. Nizielski, C. D. Morrison, D. H. Keisler and G. L. Williams. 2002. Central infusion of recombinant ovine leptin normalizes plasma insulin and stimulates a novel hypersecretion of luteinizing hormone after short-term fasting in mature beef cows. Biological Reproduction 66:1555-1561. crossref(new window)

Bezerra, L. R. 2006. Performance and metabolic behavior of Santa Inês lambs fed with different concentrations of Spirulina platensis in diluted cow's milk. 173f. Dissertation (Master in Zootechny) - University of Campina Grande, Paraíba.

Chelikani, P. K., J. D. Ambrose, D. H. Keisler and J. J. Kennelly. 2004. Effect of short-term fasting on plasma concentrations of leptin and other hormones and metabolites in dairy cattle. Domest. Anim. Endocrinol. 26:33-48. crossref(new window)

Clark, J. H., K. C. Olson, T. B. Schmidt, M. L. Linville, D. O. Alkire, D. L. Meyer, G. K. Rentfrow, C. C. Carr and E. P. Berg. 2007. Effects of dry matter intake restriction on diet digestion, energy partitioning, phosphorus retention, and ruminal fermentation by beef steers. J. Anim. Sci. 85:3383-3390. crossref(new window)

Cole, N. A. 2000. Changes in postprandial plasma and extracellular and ruminal fluid volumes in wethers fed or unfed for 72 h. J. Anim. Sci. 78:216-223.

Costa, P. B., A. C. Queiroz, M. T. Rodrigues, A. L. R. Magalhães, M. G. Costa, F. L. B. Toral, T. A. Carvalho, L. Monteiro, K. Zorzi and M. S. Duarte. 2007. Performance of dairy heifers under management compensatory growth supplementation with ionophore. Rev. Bras. Zootec. 36(2): 461-470. crossref(new window)

Ford, J. A. Jr. and C. S. Park. 2001. Nutritionally directed compensatory growth enhances heifer development and lactation potential. J. Dairy Sci. 84:1669-1678. crossref(new window)

Firkins, J. L., Z. Yu and M. Morrison. 2007. Ruminal nitrogen metabolism: perspectives for integration of microbiology and nutrition for dairy. J. Dairy Sci. 90 (Suppl. 1):E1-16. crossref(new window)

Fujihara, T., E. R. Orskov and P. J. Reeds. 1987. The effect of protein infusion on urinary excretion of purine derivatives in ruminants nourished by intragastric nutrition. J. Agric. Sci. 109:7-12. crossref(new window)

Herdt, H. H. 2000. The veterinary clinics of North America: food animal practice. 16(2):408.

Hoch, T., C. Begon, I. Cassar-malek, B. Picard and I. Savaryauzeloux. 2003. Mecanismes et consequences de la croissance compensatrice chez lês ruminants. INRA Productions Animales 16(1):49-59.

Lobo, R. N. B., V. M. Penna and F. E. Madalena. 2000. Breeding program evaluation for dual purpose zebu cattle. Revista Brasileira de Zootecnia, 29(5) :1349-1360. crossref(new window)

Mcdowell, L. R. 1999. Minerals for grazing ruminants in tropical regions, with emphasis on Brazil. Florida: University of Florida, 93 p. (Boletim, 3).

Mertens, D. R. 2001. Physical effective NDF and Its Use in Formulating dairy rations. In: INTERNATIONAL SYMPOSIUM ON DAIRY CATTLE, 2, 2001, Florida Dairy Extension, Florida: University of Florida, p. 25-36.

National Research Council (NRC). 1996. Nutrient requirement of dairy cattle. Washington: National Academy of Science, 242.

Pereira, K. P., A. S. C. V. Véras, M. A. Ferreira, A. M. V. Batista, K. A. Marques and A. C. A. Fotius. 2007. Nitrogen balance and endogenous losses in cattle and buffaloes fed with increasing levels of concentrate. Acta Scientiarum Animal Science 29(4):433-440.

Ruiz, R., L. O. Tedeschi, J. C. Marini, D. G. Fox, A. N. Pell, G. Jarvis and J. B. Russel. 2002. The effect of a ruminal nitrogen (N) deficiency in dairy cows: evaluation of the cornell net carbohydrate and protein system ruminal n deficiency adjustment. J. Dairy Sci. 85:2986-2999. crossref(new window)

Ryan, W. J., I. H. Williams and R. J. Moir. 1993. Compensatory growth in sheep and cattle. Growth pattern and feed intake. Aust. J. Agric. Res. Perth, 44:1609-1621. crossref(new window)

Ryan, W. J. 1990. Compensatory growth in cattle and sheep. In: Nutrition abstracts and reviews (Series B), 50:653-664.

Silva, D. J. and A. C. Queiroz. 2002. Food analysis (chemical and biological). 3.ed. Vicosa, MG: Universidade Federal de Vicosa, p. 235.

Statistical Analysis System (SAS). 2000. Version 8.12 SAS, INC. Cany, NC, USA, 2000.

Taylor-edwards, C. C., N. A. Elam, S. E. Kitts, K. R. Mc leod, D. E. Axe, E. S. Vanzant, N. B. Kristensen and D. L. Harmon. 2009. Influence of slow-release urea on nitrogen balance and portal-drained visceral nutrient flux in beef steers. J. Anim. Sci. 7:209-221.

Taylor, M. S., K. T. Knowlton, M. L. Mcgilliard, W. M. Seymour and J. H. Herbein. 2008. Blood mineral, hormone, and osteocalcin responses of multiparous jersey cows to an oral dose of 25-hydroxyvitamin d3 or vitamin d3 before parturition. J. Dairy Sci. 91:2408-2416. crossref(new window)

Tolla, N., T. Mirkena and L. A. Yimegnuha. 2003. Effect of feed restriction on compensatory growth of Arsi (Bos indicus) bulls. Anim. Feed Sci. Technol. 103:29-39. crossref(new window)

Valadares, R. F. D., G. A. Broderick, S. C. Valadares Filho and M. K. Clayton. 1999. Effect of replacing alfafa silage with high moisture corn on ruminal protein synthesis estimated from excretion of total purine derivatives. J. Dairy Sci. 82(12): 2686-2696. crossref(new window)

Valkeners, D., A. Théwis, F. Piron and Y. Beckers. 2004. Effect of imbalance between energy and nitrogen supplies on microbial protein synthesis and nitrogen metabolism in growing doublemuscled Belgian Blue bulls. J. Anim. Sci. 82:1818-1825.

Verbic, J., X. B. Chen and N. A. Macleod. 1990. Excretion of purine derivatives by ruminants. Effect of microbial nucleic acid infusion on purine derivative excretion by steers. J. Agric. Sci. 114:243-248. crossref(new window)

Weiss, W. P. 1999. Energy prediction equations for ruminant feeds. In: CORNELL NUTRITION CONFERENCE FOR FEED MANUFACTURERS, 61, 1999, Ithaca. Proceedings... Ithaca: Cornell University, 1999, p. 176-185.

Wilson, P. N. and D. F. Osbourn. 1960. Compensatory growth after under nutrition in mammals and birds. Biological Reviews 35(3):324-363.

Yan, T., J. P. Frost. and T. W. J. Keady. 2007. Prediction of nitrogen excretion in feces and urine of beef cattle offered diets containing grass silage. J. Anim. Sci. 85:1982-1989. crossref(new window)

Zanton, G. I. and A. J. Heinrichs. 2008. Analysis of nitrogen utilization and excretion in growing dairy cattle. J. Dairy Sci. 91(4):p.1519-1533. crossref(new window)