Hostname: page-component-84b7d79bbc-rnpqb Total loading time: 0 Render date: 2024-07-29T14:25:35.287Z Has data issue: false hasContentIssue false
  • English
  • Français

Rice bran as a supplement to elephant grass for cattle and buffalo in Indonesia: 2. Carcass development, energy accretion and its effect on feed efficiency: 2. Carcass development, energy accretion and its effect on feed efficiency

Published online by Cambridge University Press:  27 March 2009

J. B. Moran
J. B. Moran
Affiliation:
Project for Animal Research and Development, Balai Penelitian Ternak, PO Box 123, Bogor, Indonesia
Get access Rights & Permissions [Opens in a new window]

Summary

Indonesian Ongole and swamp buffalo bulls that had previously been given 0, 1·2, 2·4, 3·6 or 4·8 kg/head/day rice bran plus ad libitum elephant grass were slaughtered after 161 days feeding. Abdominal depot fat, full and empty reticulo-rumen and cold carcass weights were recorded. Various carcass variables were measured and the 9–10–11 rib joints were dissected into bone, muscle and fat. Carcass gross energy was calculated from rib-fat content using previously determined regression equations. Feed efficiency was expressed in terms of the ratios of live-weight gain or carcass-energy accretion to metabolizable energy available for growth.

Increasing supplementation with rice bran resulted in larger abdominal fat depots, higher dressing percentages, increased carcass fatness (and hence carcass gross energy) and improved rib muscle to bone ratios. Carcass conformation was unaffected by dietary treatment. When feed efficiency was expressed per unit live-weight gain, there was a decrease with increasing rice-bran feeding. Feed efficiency, expressed per unit of carcass energy accretion, improved with rice-bran supplementation and was generally higher in buffalo than in Ongole bulls. Dietary and species differences in feed efficiency could be primarily explained by the differential energy cost of deposition of, and the availability of energy from, carcass protein and lipid.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 100 , Issue 3 , June 1983 , pp. 717 - 722
Copyright
Copyright © Cambridge University Press 1983

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Australian Meat Board (1971). Australian Beef Carcass Appraisal System. Sydney: Australian Meat Board.Google Scholar
Callow, E. H. (1947). Comparative studies of meat. 1. The chemical composition of fatty and muscular tissue in relation to growth and fattening. Journal of Agricultural Science, Cambridge 37, 113129.CrossRefGoogle Scholar
Calub, A. D., Castillo, L. S., Madamba, J. C. & Palo, L. P. (1971). The carcass quality of carabaos and cattle fattened in feedlot. Philippine Journal of Animal Science 8, 6978.Google Scholar
Charles, D. D. & Johnson, E. R. (1975). Liveweight gains and carcass composition of buffalo (Bubalus bubalis) steers on four feeding regimes. Australian Journal of Agricultural Research 26, 407413.CrossRefGoogle Scholar
Ferrell, C. L., Kohlmeier, R. H., Crouse, J. D. & Glimp, H. (1978). Influence of dietary energy, protein and biological type of steer upon rate of gain and carcass characteristics. Journal of Animal Science 46, 255270.CrossRefGoogle Scholar
Garrett, W. N. (1971). Energetic efficiency of beef and dairy steers. Journal of Animal Science 32, 451456.CrossRefGoogle Scholar
Griffith, T. W. (1978). Effects of variations in energy and protein intake on digestibility, nitrogen balance and carcass composition in British Friesian castrate male cattle. Animal Production 26, 233243.Google Scholar
Hankins, O. G. & Howe, P. E. (1946). Estimation of the composition of beef carcasses and cuts. U.S. Department of Agriculture Technical Bulletin no. 926.Google Scholar
Johnson, E. R. & Charles, D. D. (1975). Comparisons of liveweight gain and changes in carcass composition between buffalo (Bubalus bubalis) and Bos tauru steers. Australian Journal of Agricultural Research 26, 415422.CrossRefGoogle Scholar
Lindhe, B. (1975). Genetic change of energy deposition in beef cattle. World Review of Animal Production 11 (2), 1925.Google Scholar
Moran, J. B. (1976). Beef production as influenced by grazing and feeding management and by mature size. Ph.D. thesis, University of London.Google Scholar
Moran, J. B. (1978). The comparative performance of Indonesian beef breeds. Proceedings First Ruminant Seminar, P3T /Instilut Pertanian Bogor, pp. 2831. Bogor, Indonesia.Google Scholar
Moran, J. B. (1980). The prediction of chemical content of the whole carcass from the physically dissected rib joint in cattle and buffaloes. Proceedings of Australian Society of Animal Production 13, 503.Google Scholar
Moran, J. B. (1982). Growth and development of ether extract in the carcasses of cattle and buffalo. Proceedings of Australian Society of Animal Production 14, 601.Google Scholar
Moran, J. B. (1983). Rice bran as a supplement to elephant grass for cattle and buffalo in Indonesia. 1. Feed intake, utilization and growth rates. Journal of Agricultural Science, Cambridge 100, 709716.CrossRefGoogle Scholar
Preston, T. R. & Willis, M. B. (1970). Intensive Beef Production. Oxford: Pergamon Press.Google Scholar
Thorbek, G. (1980). Studies on protein and energy metabolism in growing calves. Beretning fra Statens Husdyrbrugsforsog 498, 84 pp.Google Scholar
Webster, A. J. F. (1980). The energetic efficiency of growth. Livestock Production Science 7, 243252.CrossRefGoogle Scholar