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Compensatory growth and body composition changes in grazing steers following silage feeding without or with a supplement of fish meal and monensin

Published online by Cambridge University Press:  02 September 2010

M. J. Gibb
Affiliation:
AFRC Institute for Grassland and Environmental Research, Hurley, Maidenhead SL6 5LR
R. D. Baker
Affiliation:
AFRC Institute for Grassland and Environmental Research, Hurley, Maidenhead SL6 5LR
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Abstract

The effects of fish meal and monensin supplementation of silage on the growth and composition Friesian steers was examined in winter and subsequently during grazing. Four-month-old steers were given grass silage ad libitum, alone (U) or mixed with fish meal and monensin at 100 and 0·005 g/ dry matter (DM) of silage (S) for 17 weeks. Empty body weight (EBW) and carcass weight (CW) gains were significantly increased by supplementation (810 v. 495, and 553 v. 332 g/day, respectively). Although treatment S steers were heavier, their composition at turn-out was similar to that of the treatment U animals: mean fat, crude protein (CP), water, ash and energy contents were 121, 187, 640, 51 g/kg and 9·10MJ/kg EBW, respectively. During the following 20 weeks, six animals from each treatment grazed a perennial ryegrass/white clover sward unsupplemented (UU and SU), supplemented with a fish meal/maize/molassine meal (50:35: 15) pelleted diet and monensin at 4 g/kg live weight (LW) per day and 0·1 mg/kg LW per day, respectively, (UMF and SMF). A further group of six steers from treatment S received the pelleted diet without monensin during grazing (SF). Steers from treatment U showed significant compensation in EBW and in carcass growth at pasture, irrespective of whether they received a supplement, which led to a marked reduction of the differences in EBW and CW by final slaughter. Composition at final slaughter showed no significant effect winter nutrition, with the exception of fat content (g/kg EBW), which was significantly lower animals from treatment SU. Steers from treatments UMF and SMF had slightly higher rates of fat, CP, water and energy deposition, which resulted in higher fat and lower water contents (g/kg EBW) than those from treatments UU and SU, although these differences were not significant. Steers on treatment SF had gains and final compositions intermediate between those on treatments SU and SMF. Supplementation was cost effective in winter, but marginal in summer.

Type
Research Article
Copyright
Copyright © British Society of Animal Science 1991

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References

REFERENCES

Association of Official Agricultural Chemists. 1965. Official Methods of analysis of the Association of Official Agricultural Chemists. 10th ed. Association of Official Agricultural Chemists, Washington, DC.Google Scholar
Baker, R. D., Kilkenny, J. B., Spedding, A. W. and Tayler, J. C. 1972. An intensive grassland system using autumn born calves. Beef Production Handbook 1. Revised ed. Meat and Livestock Commission, Bletchley.Google Scholar
Baker, R. D., Young, N. E. and Laws, J. A. 1985. Changes in the body composition of cattle exhibiting compensatory growth and the modifying effects of grazing management. Animal Production 41: 309321.Google Scholar
Bonsembiante, M. and Andrighetto, I. 1984. L'impiego del monensin nell allevamento di vitelloni alimentati con silomais o stocchi di mais insilati. Zootechnica e Nutrizione Animale 10: 121133.Google Scholar
Boucque, Ch. V., Fiems, L. O., Cottyn, B. G., Casteels, M. and Buysse, F. X. 1982. Monensinsodium as a performance-promoting additive for fattening bulls and its impact on carcass and meat quality characteristics. Animal Feed Science and Technology 7: 401410.CrossRefGoogle Scholar
Brown, H., Carroll, L. H., Elliston, N. G., Grueter, H. P., McAskill, J. W., Olson, R. D. and Rathmacher, R. P. 1974. Field evaluation of monensin for improving feed efficiency in feedlot cattle. Journal of Animal Science 38: 1340 (Abstr.).Google Scholar
Daenicke, R., Rohr, K. and Oslage, H. J. 1982. Effect of monensin on rumen fermentation, performance and body composition of growing bulls. Livestock Production Science 8: 479488.CrossRefGoogle Scholar
Dinius, D. A., Simpson, M. E. and Marsh, P. B. 1976. Effect of monensin fed with forage on digestion and the rumenal ecosystem of steers. Journal of Animal Science 42: 229234.Google Scholar
England, P. and Gill, M. 1985. The effect of fish meal and sucrose supplementation on the voluntary intake of grass silage and live-weight gain of young cattle. Animal Production 40: 259265.Google Scholar
Farlin, S. D., Clanton, D. C. and Heldt, J. D. 1975. A new feed additive for beef cattle. Nebraska Beef Cattle Report, pp. 89.Google Scholar
Faulkner, D. B., Klopfenstein, T. J., Trotter, T. N. and Britton, R. A. 1985. Monensin effect on digestibility, ruminal protein escape and microbial protein synthesis on high-fiber diets. Journal of Animal Science 61: 654660.CrossRefGoogle ScholarPubMed
Federer, W. T. 1955. Experimental Design, pp. 2126. Macmillan, New York.Google Scholar
Fiems, L. O., Boucque, Ch. V., De Brabander, D. L., Cottyn, B. G. and Buysse, F. X. 1983. Effect of monensin-sodium supplementation on the performances of young grazing cattle. In Efficient Grassland Farming (ed. Corrall, A. J.), British Grassland Society Occasional Symposium No. 14, pp. 209211.Google Scholar
Flachowsky, G., Vorkaufer, G., Walter, R., Hercher, H. and Moller, E. 1985. Einsatz des Pansenfermoregulators Monensin in der Jungrinderfutterung unter Produktionsbedingungen. 2. Stall-haltung. Tiererndhrung und Futterung 14: 2123.Google Scholar
Garstang, J. R. 1981. Silage supplements for calves. Animal Production 32: 355 (Abstr.).Google Scholar
Garstang, J. R., Thomas, C. and Gill, M. 1979. The effect of supplementation of grass silage with fish meal on intake and performance by British Friesian calves. Animal Production 28: 423 (Abstr.).Google Scholar
Gibb, M. J. and Baker, R. D. 1987. Performance of young steers offered silage or thermo-ammoniated hay with or without a fish-meal supplement. Animal Production 45: 371381.Google Scholar
Gibb, M. J. and Baker, R. D. 1989. Performance and body composition of young steers given stackammoniated hay with or without a supplement or untreated hay with a supplement. Animal Production 48: 341351.Google Scholar
Gill, M. and Beever, D. E. 1982. The effect of protein supplementation on digestion and glucose metabolism in young cattle fed on silage. British Journal of Nutrition 48: 3747.CrossRefGoogle ScholarPubMed
Gill, M., Beever, D. E., Buttery, P. J., England, P., Gibb, M. J. and Baker, R. D. 1987. The effect of oestradiol-176 implantation on the response in voluntary intake, live-weight gain and body composition, to fishmeal supplementation of silage offered to growing calves. Journal of Agricultural Science, Cambridge 108: 916.CrossRefGoogle Scholar
O'Donovan, P. B. 1984. Compensatory gain in cattle and sheep. Nutrition Abstracts and Reviews — Series B 54: 389410.Google Scholar
Potter, E. L., Muller, R. D., Wray, M. I., Carroll, L. H. and Meyer, R. M. 1986. Effect of monensin on the performance of cattle on pasture or fed harvested forages in confinement. Journal of Animal Science 62: 583592.CrossRefGoogle ScholarPubMed
Potter, E. L., Raun, A. P., Cooley, C. O., Rathmacher, R. P. and Richardson, L. F. 1976. Effect of monensin on carcass characteristics, carcass composition and efficiency of converting feed to carcass. Journal of Animal Science 43: 678683.Google Scholar
Potter, E. L., Wray, M. I., Muller, R. D., Grueter, H. P., McAskill, J. and Young, D. C. 1985. Effect of monensin and tylosin on average daily gain, feed efficiency and liver abscess incidence in feedlot cattle. Journal of Animal Science 61: 10581065.Google Scholar
Prange, R. W., Davis, C. L. and Clark, J. H. 1978. Propionate production in the rumen of Holstein steers fed either a control or monensin supplemented diet. Journal of Animal Science 46: 11201124.Google Scholar
Richardson, L. F., Raun, A. P., Potter, E. L., Cooley, C. O. and Rathmacher, R. P. 1976. Effect of monensin on rumen fermentation in vitro and in vivo. Journal of Animal Science 43: 657664.CrossRefGoogle Scholar
Sanderson, R. and Thomas, C. 1987. Fish meal as a supplement to grass silage fed to young cattle. Eighth Silage Conference, AFRC Institute for Grassland and Animal Production, Hurley, pp. 163164 (Abstr.).Google Scholar
Sherrod, L. B., Kellison, R. L. and Klett, R. H. 1975. Monensin levels in growing and finishing steer rations. Research Report No. 25, Texas Technical University Centre at Amarillo, Pantex, Texas 79069, pp. 4346.Google Scholar
Thomas, C., Gill, M. and Austin, A. R. 1980. The effect of supplements of fishmeal and lactic acid on voluntary intake of silage by calves. Grass and Forage Science 35: 275279.Google Scholar
Wakita, M., Kobayashi, Y., Hoshino, S., Kitabayashi, Y., Hashimuru, M. and Kudo, H. 1987. Effects of salinomycin and monensin on feed conversion of concentrate and ruminal fluid characteristics in fattening Holstein steers. Japanese Journal of Zootechnology and Science 58: 396402.Google Scholar
Wilkinson, J. I. D., Appleby, W. G. C., Shaw, C. J., Lebas, G. and Pflug, R. 1980. The use of monensin in European pasture cattle. Animal Production 31: 159162.Google Scholar
Wilson, L. L., Hatfield, E. E. and Hixon, D. L. 1975. The effectiveness of different levels of monensin on the feedlot performance of finishing steers. Experiment 1. Illinois Beef Cattle Day Report.Google Scholar
Wright, I. A., Russel, A. J. F. and Hunter, E. A. 1986. The effect of winter food level on compensatory growth of weaned, suckled calves grazed at two sward heights. Animal Production 43: 211223.Google Scholar
Wright, I. A., Russel, A. J. F. and Hunter, E. A. 1989. Compensatory growth in cattle grazing different vegetation types. Animal Production 48: 4350.Google Scholar