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Feeding value for lambs of rapeseed meal arising from biodiesel production

Published online by Cambridge University Press:  18 August 2016

T. A. McAllister ,
K. Stanford ,
G. L. Wallins ,
M. J. T. Reaney  and
K.-J. Cheng
T. A. McAllister
Affiliation:
Research Centre, Agriculture and Agri-Food Canada, Box 3000, Lethbridge, Alberta, Canada T1J 4B1
K. Stanford
Affiliation:
Alberta Agriculture, Food and Rural Development, Agriculture Centre, Bag 3014, Lethbridge, Alberta, Canada T1J 4C7
G. L. Wallins
Affiliation:
Research Centre, Agriculture and Agri-Food Canada, Box 3000, Lethbridge, Alberta, Canada T1J 4B1
M. J. T. Reaney
Affiliation:
Research Centre, Agriculture and Agri-Food Canada, 107 Science Place, Saskatoon, Saskatchewan, Canada S7N 0X2
K.-J. Cheng
Affiliation:
Research Centre, Agriculture and Agri-Food Canada, Box 3000, Lethbridge, Alberta, Canada T1J 4B1
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Abstract

Meals prepared from low glucosinolate rapeseed screenings (SCREEN) and from seed which had heated during storage (HEAT) were compared against commercial rapeseed meal (COM) for feeding value. Oil, crude protein (CP) and acid-detergent insoluble nitrogen contents in SCREEN, HEAT and COM, respectively, were (g/kg): 118, 246 and 13; 227, 315 and 436; and 17, 64 and 21. in situ dry matter (DM) and protein disappearance rates, soluble protein fraction and effective rumen degradability of protein (EDCP) were lower (P < 0·05) in HEAT than in SCREEN or COM. Comparing oil-extracted meals in situ, EDCP of HEAT was lower (P < 0·05) than EDCP of SCREEN or COM but protein and DM disappearance rates of HEAT were only lower (P < 0·05) than those of SCREEN. Four isonitrogenous barley-based diets (150 g/kg CP, DM basis), containing SCREEN, HEAT, COM or COM supplemented with rapeseed oil (OIL), were given to lambs. For DM, organic matter and neutral-detergent fibre apparent digestibilities, the diets ranked SCREEN > HEAT = OIL > COM (P < 0·05). Digestion and retention of nitrogen were lower (P < 0·05) in lambs given HEAT than in lambs given other diets. Food efficiency of lambs given HEAT was improved (P < 0·05) as compared with lambs given SCREEN or COM. Dressing proportions were higher (P < 0·05) with HEAT, SCREEN and OIL diets than with COM. Other than minor changes in fatty acid composition of subcutaneous fat with HEAT and OIL, carcass traits were not altered by treatment. Feeding SCREEN or HEAT did not adversely affect animal performance or food utilization.

Keywords

biodieselcarcass compositiongrowthlambsrapeseed oil meal
Type
Research Article
Information
Animal Science , Volume 68 , Issue 1 , February 1999 , pp. 183 - 194
Copyright
Copyright © British Society of Animal Science 1999

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References

Ali, Y., Eskridge, K. M. and Hanna, M. A. 1995. Testing of alternative diesel fuel from tallow and soybean oil in Cummins N14-410 diesel engine. Bioresource Technololgy 53: 243254.Google Scholar
Ali, Y., Hanna, M. A. and Borg, J. E. 1996. In-cylinder pressure characteristics of a CI engine using blends of diesel fuel and methyl esters of beef tallow. Transactions of the American Society of Agricultural Engineers 39: 799804.Google Scholar
American Oil Chemists’ Society. 1996. Official methods and recommended practises of the AOCS, Update to the fourth edition (1989). American Oil Chemists’ Society Press, Champaign, IL.Google Scholar
Association of Official Analytical Chemists. 1990. Official methods of analysis, 15th edition. Assocation of Official Analytical Chemists, Arlington, VA.Google Scholar
Bauchart, D., Legay-Carmier, F. and Doreau, M. 1990. Ruminai hydrolysis of dietary triglycérides in dairy cows fed lipid-supplemented diets. Reproduction, Nutrition, Development 30: (suppl. 2) 187s.Google Scholar
Bayourthe, C., Moncoulon, R. and Vernay, M. 1993. Effect of protein-protected fat on ruminai and total nutrient digestibility of sheep diets. Journal of Animal Science 71: 10261031.Google Scholar
Bourdon, D. and Aumaître, A. 1990. Low-glucosinolate rapeseeds and rapeseed meals: effect of technological treatments on chemical composition, digestible energy content and feeding value for pigs. Animal Feed Science and Technology 30: 175191.Google Scholar
Bowes, P. C. 1984. Self-heating: evaluating and controlling the hazards. Elsevier, Amsterdam.Google Scholar
Brandt Jr, R. T. and Anderson, S. J. 1990. Supplemental fat source affects feedlot performance and carcass traits of finishing yearling steers and estimated diet net energy value. Journal of Animal Science 68: 22082216.Google Scholar
Brandt Jr, R. T., Anderson, S. J. and Elliott, J. K. 1988. Effect of supplemental fat on performance and carcass traits of finishing cattle fed milo or wheat processed by two methods. Cattle feeders’ day, Kansas Agricultural Experiment Station, Kansas State University, Manhattan, KA, progress report no. 555.Google Scholar
Canadian Council on Animal Care. 1993. Guide to the care and use of experimental animals, volume 1. (ed. Olfert, E. D., Cross, B. M. and McWilliam, A. A.). Canadian Council on Animal Care, Ottawa, ON.Google Scholar
Canadian Grain Commission. 1996. Officiai grain grading guide. Canadian Grain Commission, Winnipeg, MB.Google Scholar
Doreau, M., Ferlay, A. and Elmeddah, Y. 1993. Organic matter and nitrogen digestion by dairy cows fed calcium salts of rapeseed oil fatty acids or rapeseed oil. Journal of Animal Science 71: 499504.Google Scholar
Faldet, M. A., Voss, V. L., Broderick, G. A. and Satter, L. D. 1991. Chemical, in vitro and in situ evaluation of heat-treated soybean proteins. Journal of Dairy Science 74: 25482554.Google Scholar
Ferlay, A. and Doreau, M. 1992. Influence of method of administration of rapeseed oil in dairy cows. 1. Digestion of nonlipid components. Journal of Dairy Science 75: 30203027.CrossRefGoogle ScholarPubMed
Ferlay, A., Legay, F., Bauchart, D., Poncét, C. and Doreau, M. 1992. Effect of supply of raw or extruded rapeseeds on digestion in dairy cows. Journal of Animal Science 70: 915923.Google Scholar
Hassan, S. A. and Bryant, M. J. 1986. The response of store lambs to dietary supplements of fish meal. 2. Effects of level of feeding. Animal Production 42: 233240.Google Scholar
Henderson, C. 1973. The effects of fatty acids on pure cultures of rumen bacteria. Journal of Agricultural Science, Cambridge 81: 107112.Google Scholar
Herrera-Saldana, R.E, Huber, J. T. and Poore, M. H. 1990. Dry matter, crude protein and starch degradability of five cereal grains. Journal of Dairy Science 73: 23862393.Google Scholar
Hussein, H. S. and Jordan, R. M. 1991. Fishmeal as a protein supplement in ruminant diets: a review. Journal of Animal Science 69: 21472156.Google Scholar
Hussein, H. S., Merchen, N. R. and Fahey Jr, G. C. 1995. Effects of forage level and canola supplementation on site and extent of digestion of organic matter, carbohydrates and energy by steers. Journal of Animal Science 73: 24582468.Google Scholar
Jones, S. D. M., Robertson, W. M. and Price, M. A. 1993. The assessment of saleable meat yield in lamb carcasses. International congress of meat science technology, Calgary, AB, p. 190 (abstr.).Google Scholar
Kirton, A. H. and Johnson, D. L. 1979. Interrelationships between GR and other lamb carcass fatness measurements. Proceedings of the New Zealand Society of Animal Production 39: 194201.Google Scholar
Laforgia, D. and Ardito, V. 1995. Biodiesel fuelled idi engines: performances, emissions and heat release investigation. Bioresource Technology 51: 5359.Google Scholar
Lough, D. S., Solomon, M. B., Rumsey, T. S., Elasser, T. H., Slyter, L. L., Kahl, S. and Lynch, G. P. 1992. Effects of dietary canola seed and soy lecithin in high-forage diets on cholesterol content and fatty acid composition of carcass tissues of growing ram lambs. Journal of Animal Science 70: 11531158.CrossRefGoogle ScholarPubMed
Lynch, G. P. 1992. Effects of dietary canola seed and soy lecithin in high-forage diets on cholesterol content and fatty acid composition of carcass tissues of growing ram lambs. Journal of Animal Science 70: 11531158.Google Scholar
McAllister, T. A., Beauchemin, K. A., McClelland, L. A. and Cheng, K.-J. 1992. Effect of formaldehyde-treated barley or escape protein on nutrient digestibility, growth and carcass of feedlot lambs. Canadian Journal of Animal Science 72: 309316.CrossRefGoogle Scholar
McAllister, T. A., Cheng, K.-J., Beauchemin, K. A., Bailey, D. R. C., Pickard, M. D. and Gilbert, R. P. 1993. Use of lignosulfonate to decrease the ruminai degradability of canola meal protein. Canadian Journal of Animal Science 73: 211215.Google Scholar
McAllister, T. A., Cheng, K.-J., Rode, L. M. and Buchanan-Smith, J. G. 1990. Use of formaldehyde to regulate digestion of barley starch. Canadian Journal of Animal Science 70: 581 589.Google Scholar
McKinnon, J. J., Olubobokun, J. A., Christensen, D. A. and Cohen, R. D. H. 1991. The influence of heat and chemical treatment on ruminai disappearance of canola meal. Canadian Journal of Animal Science 71: 773780.Google Scholar
Maczulak, A. E., Dehority, B. A. and Palmquist, D. L. 1981. Effects of long chain fatty acids on growth of rumen bacteria. Applied and Environmental Microbiology 42: 856862.Google Scholar
Mills, J. T. 1989. Spoilage and heating of stored agricultural products. Prevention, detection and control. Research Branch, Agriculture Canada, publication 1823E.Google Scholar
Milner, M. and Geddes, W. F. 1946. Grain storage studies. I. Influence of localized heating of soybeans on interseed air movements. Cereal Chemistry 22: 477483.Google Scholar
Mir, Z. 1988. A comparison of canola acidulated fatty acids and tallow as supplements to a ground alfalfa diet for sheep. Canadian Journal of Animal Science 68: 761767.Google Scholar
Moshtaghi Nia, S. A. and Ingalls, J. R. 1995. Influence of moist heat treatment on ruminai and intestinal disappearance of amino acids from canola meal. Journal of Dairy Science 78: 15521560.Google Scholar
Ørskov, E. R. and McDonald, I. 1979. The estimation of protein degradability in the rumen from incubation measurements weighted according to the rate of passage. Journal of Agricultural Science, Cambridge 92: 499503.Google Scholar
Perrier, R., Michalet-Doreau, B., Bauchart, D. and Doreau, M. 1992. Assessment of an in-situ technique to estimate the degradation of lipids in the rumen. Journal of the Science of Food and Agriculture 59: 449455.Google Scholar
Solomon, M. B., Lynch, G. P., Paroczay, E. and Norton, S. 1991. Influence of rapeseed meal, whole rapeseed, and soybean meal on fatty acid composition and cholesterol content of muscle and adipose tissue from ram lambs. Journal of Animal Science 69: 40554061.CrossRefGoogle ScholarPubMed
Stanford, K., McAllister, T. A., Xu, Z., Pickard, M. and Cheng, K.-J. 1995. Comparison of lignosulfonate-treated canola meal and soybean meal as rumen undegradable protein supplements for lambs. Canadian Journal of Animal Science 75: 371377.Google Scholar
Statistical Analysis Systems Institute. 1993. SASIStat user’s guide, version 6.10, vol. 2. SAS Institute, Inc., Cary, NC.Google Scholar
Stumborg, M., Wong, A. and Hogan, E. 1996. Hydroprocessed vegetable oils for diesel fuel improvement. Bioresource Technology 56: 1318.Google Scholar
Tesfa, A. T. 1992. Effects of rapeseed oil on rumen enzyme activity and in sacco degradation of grass silage. Animal Feed Science and Technology 36: 7789.CrossRefGoogle Scholar
Tesfa, A. T. 1993. Effects of rapeseed oil supplementation on digestion, microbial protein synthesis and duodenal microbial amino acid composition in ruminants. Animal Feed Science and Technology 41: 313328.Google Scholar
Valentine, S. C. and Bartsch, B. D. 1988. Degradation of dry matter, crude protein, fat, crude fibre and nitrogen-free-extract in milled barley and lupin grains incubated in nylon bags in the rumen of dairy cows. Journal of Agricultural Science, Cambridge 110: 395400.CrossRefGoogle Scholar
Van Dyne, D. L., Weber, J. A. and Brashler, C. H. 1996. Macroeconomic effects of a community-based biodiesel production system. Bioresource Technology 56: 14.Google Scholar
Van Soest, P. J., Robertson, J. B. and Lewis, B. A. 1991. Methods for dietary fiber, neutral detergent fiber and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science 74: 35833597.CrossRefGoogle ScholarPubMed
Windschitl, P. M. and Stern, M. D. 1988. Evaluation of calcium lignosulfonate-treated soybean meal as a source of rumen protected protein for dairy cattle. Journal of Dairy Science 71: 33103322.Google Scholar
Zinn, R. A. 1989. Influence of level and source of dietary fat on its comparative feeding value in finishing diets for feedlot steers: feedlot cattle growth and performance. Journal of Animal Science 67: 10291037.Google Scholar
Zinn, R. A. 1994. Effects of excessive supplemental fat on feedlot cattle growth performance and digestive function. Professional Animal Scientist 10: 6672.Google Scholar