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The digestion by sheep of silages made with and without the addition of formaldehyde

Published online by Cambridge University Press:  27 March 2009

D. E. Beever ,
D. J. Thomson ,
S. B. Cammell  and
D. G. Harrison
D. E. Beever
Affiliation:
The Grassland Research Institute, Hurley, Maidenhead, Berkshire, SL6 5LR
D. J. Thomson
Affiliation:
The Grassland Research Institute, Hurley, Maidenhead, Berkshire, SL6 5LR
S. B. Cammell
Affiliation:
The Grassland Research Institute, Hurley, Maidenhead, Berkshire, SL6 5LR
D. G. Harrison
Affiliation:
The Grassland Research Institute, Hurley, Maidenhead, Berkshire, SL6 5LR
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Summary

S.24 perennial ryegrass was conserved by ensiling directly (control) and after treatment with a solution of formaldehyde at the rate of 6 g HCHO/100 g crude protein. After storage for 90 days, part of the formaldehyde-treated silage was dried in a high-temperature drier.

The quantitative digestion of the energy, carbohydrate and nitrogen moieties of the three diets and the production of volatile fatty acids and microbial protein within the rumen were measured using five sheep fitted with re-entrant cannulae at the proximal duodenum and terminal ileum.

Treatment with formaldehyde depressed organic matter and energy digestion within the rumen compared with untreated silage (P < 0·001) and a further depression was observed on the dehydrated material. Both formaldehyde-treated silages showed enhanced flows of total amino acids into the small intestine compared with the control silage and net absorption from the small intestine was elevated by 13 and 21% respectively on these two diets. On the untreated silage over 71% of the protein entering the small intestine was microbial in origin whereas, due to depressed microbial growth and increased protection of feed protein from rumen fermentation, microbial protein comprised only 17% of duodenal protein on the two formaldehyde-treated silage diets. Fifteen and 81 % of the dietary protein passed undegraded through the stomachs to the duodenum on the control and the two formaldehyde-treated silage diets respectively.

Total VFA production within the rumen was not significantly influenced by the treatments imposed, but on the untreated silage only 56% of the energy apparently digested in the rumen was converted to VTA energy whilst a mean value of 74% was recorded on the other two diets.

Estimates of the total energy absorbed gave values of 10·6, 11·9 and 10·7 MJ/kg D.M. for the control, formaldehyde and dried, formaldehyde silage diets with absorbed protein energy representing 21, 22 and 26% of the total absorbed energy respectively.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 88 , Issue 1 , February 1977 , pp. 61 - 70
Copyright
Copyright © Cambridge University Press 1977

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References

Baldwin, R. L., Lucas, H. L. & Cabrera, R. (1970). Energetic relationships in the formation and utilization of fermentation end products. In Physiology of Digestion and Metabolism in the Ruminant (ed. Phillipson, A. T.), pp. 319–34. Newcastle-upon-Tyne: Oriel.Google Scholar
Barry, T. N., Duncan, S. J. & Fennessy, P. F. (1973). The effect of formaldehyde treatment on the chemical composition and nutritive value of silage. New Zealand Journal of Agricultural Research 15, 712–22.CrossRefGoogle Scholar
Beever, D. E., Cammell, S.B. & Wallace, A.S. (1974). The digestion of fresh, frozen and dried perennial ryegrass. Proceedings of Nutrition Society 33, 73A.Google Scholar
Beever, D. E., Harrison, D. G., Thomson, D. J., Cammell, S. B. & Osbourn, D. F. (1974). A method for the estimation of dietary and microbial protein in duodenal digesta of ruminants. British Journal of Nutrition 32, 99112.CrossRefGoogle ScholarPubMed
Beever, D. E., Thomson, D. J. & Cammell, S. B. (1976). The digestion of frozen and dried grass by sheep. Journal of Agricultural Science, Cambridge 86, 443–52.CrossRefGoogle Scholar
Beever, D. E., Thomson, D. J. & Harrison, D. G. (1976). Energy and protein transformations in the rumen and absorption of nutrients by sheep fed forage diets. In Proceedings of the 12th International Grassland Congress. Moscow, 1974, section 5, pp. 6975.Google Scholar
Beever, D. E., Thomson, D. J., Pfeffer, E. & Armstrong, D. G. (1971). The effect of drying and ensiling grass on its digestion in sheep. British Journal of Nutrition 26, 123–34.CrossRefGoogle ScholarPubMed
Bjarnson, J. & Carpenter, K. (1969). Mechanisms of heat damage in proteins. 1. Models with acylated lysine units. British Journal of Nutrition 23, 859–68.CrossRefGoogle Scholar
Brown, G. F., Armstrong, D. G. & MacRae, J. C. (1968). The establishment in one operation of a cannula into the rumen and re-entrant cannulae into the duodenum and ileum of sheep. British Veterinary Journal 124, 7882.CrossRefGoogle Scholar
Christian, K. R. & Coup, M. R. (1954). Measurement of feed intake by grazing cattle and sheep. VI. The determination of chromic oxide in faeces. New Zealand Journal of Science and Technology A36, 328–30.Google Scholar
Coehlo da Silva, J. F., Seeley, R. C, Thomson, D. J., Beever, D. E. & Armstrong, D. G. (1972). The effects of physical form on the sites of digestion of a dried lucerne diet. 2. Sites of nitrogen digestion. British Journal of Nutrition 28, 4361.CrossRefGoogle Scholar
Conway, E. J. & Byrne, A. (1933). The micro determination of ammonia. Biochemical Journal 27, 419–29.Google ScholarPubMed
Corbett, J. L., Greenhalgh, J. F. D., McDonald, I. & Florence, E. (1960). Excretion of chromium sesquioxide administered as a component of paper to sheep. British Journal of Nutrition 14, 289–94.CrossRefGoogle Scholar
Dewar, W. A. & McDonald, P. (1961). Determination of dry matter in silage by distillation with toluene. Journal of the Science of Food and Agriculture 12, 790–5.CrossRefGoogle Scholar
Elsden, S. R. & Gibson, Q. H. (1954). The estimation of lactic acid using cerie sulphate. Biochemical Journal 58, 154–8.CrossRefGoogle Scholar
Ferguson, K. A. (1975). The protection of dietary proteins and amino acids against microbial fermentation in the rumen. In Digestion and Metabolism in the Ruminant (ed. McDonald, I. W. and Warner, A. C. I.), pp. 448–64. Armidale, N.S.W.: University of New England.Google Scholar
Ferguson, K. A., Hemsley, J. A. & Reis, P. J. (1967). The effect of protecting dietary protein from microbial degradation in the rumen. Australian Journal of Science 30, 215–17.Google Scholar
Harrison, D. G., Beever, D. E., Thomson, D. J. & Osbourn, D. F. (1973). The influence of diet upon the quantity and types of amino acids entering and leaving the small intestine of sheep. Journal of Agricultural Science, Cambridge 81, 391401.CrossRefGoogle Scholar
Harrison, D. G., Beever, D. E., Thomson, D. J. & Osbourn, D. F. (1975). Manipulation of rumen fermentation in sheep by increasing the rate of flow of water from the rumen. Journal of Agricultural Science, Cambridge 85, 93101.CrossRefGoogle Scholar
Hemsley, J. A., Hogan, J. P. & Weston, R. H. (1970). Protection of forage protein from nominal degradation. In Proceedings of the 11th International Grassland Congress, Surfers Paradise, NSW, pp. 703–6.Google Scholar
Hemsley, J. A., Reis, P. J. & Downes, A. M. (1973). Influence of various formaldehyde treatments on the nutritional value of casein for wool growth. Australian Journal of Biological Sciences 26, 961–72.CrossRefGoogle ScholarPubMed
Hogan, J. P. & Weston, R. H. (1970). Quantitative aspects of microbial protein synthesised in the Rumen. In Physiology of Digestion and Metabolism in the Ruminant (ed. Phillipson, A. T.), pp. 474–85. Newcastle-upon-Tyne: Oriel Press.Google Scholar
Hungate, B. E. (1966). The Rumen and its Microbes, pp. 270. New York: Academic Press.Google Scholar
Leng, R. A. (1970). Formation and production of volatile fatty acids in the rumen. In Physiology of Digestion and Metabolism in the Ruminant (ed. Phillipson, A. T.), pp. 406–21. Neweastle-upon-Tyne: Oriel Press.Google Scholar
MacRae, J. C. & Armstrong, D. G. (1969). Studies on intestinal absorption in the sheep. British Journal of Nutrition 23, 1523.CrossRefGoogle Scholar
McMeniman, N. P., Ben-Ghadalia, D. & Armstrong, D. G. (1976). Nitrogen-energy inter-reactions in the rumen. Proceedings of the 1st International Symposium on Protein Metabolism and Nutrition (ed. Cole, D. J. A., Boorman, K. N., Buttery, P. J., Lewis, D., Neale, R. J. and Swan, N.), pp. 217–29.Google Scholar
Moore, S. (1963). On the determination of cystine as cysteic acid. Journal of Biological Chemistry 238, 235–7.CrossRefGoogle Scholar
Smith, R. H. (1975). Nitrogen metabolism in the rumen and the composition and nutritive value of nitrogen compounds entering the duodenum. In Digestion and Metabolism in the Ruminant (ed. McDonald, I. W. and Warner, A. C. I.), pp. 399415. Armidale, N.S.W.: University of New England.Google Scholar
Thomas, P. C. & Clapperton, J. L. (1972). Significance to the host of changes in fermentation activity. Proceedings of the Nutrition Society 31, 165–70.CrossRefGoogle Scholar
Van Dooken, P. (1972). Survey on the Chemistry of the Tanning of Proteins by Formaldehyde. Internal Report CSIRO. Division of Animal Production, Ian Clunies Ross Laboratories, Sydney, Australia.Google Scholar
Van Soest, P. J. & Wine, R. H. (1967). Use of detergents in the analysis of fibrous feeds in determination of plant cell wall constituents. Journal of the Associates of Official Analytical Chemists 50, 50–3.Google Scholar
Walker, D. J. (1968). The position of lactic acid and its derivatives in the nutrition and metabolism of ruminants. Nutrition Abstracts and Reviews 38, 111.Google ScholarPubMed
Weller, R. A., Gray, F. V., Pilgrim, A. F. & Jones, G. B. (1967). The rates of production of volatile fatty acids in the rumen. Australian Journal of Agricultural Research 18, 107–18.CrossRefGoogle Scholar
Whittenbury, R., McDonald, P. & Bryan-Jones, D. G. (1967). A short review of some biochemical and microbiological aspects of ensilage. Journal of the Science of Food and Agriculture 18, 441–4.CrossRefGoogle Scholar
Wilkins, R. J., Wilson, R. F. & Cook, J. E. (1975). Restriction of fermentation during ensilage: the nutritive value of silages made with the addition of formaldehyde. In Proceedings of the 12th International Grassland Congress, Moscow 1974, section 6, pp. 237.Google Scholar
Wilkins, R. J., Wilson, R. F. & Woouford, M. K. (1974). The effects of formaldehyde on the silage fermentation Vaxtodling 29. Proceedings 5th General Meeting European Grassland Federation, Uppsala 1974, pp. 197201.Google Scholar
Wilkinson, J. M., Wilson, R. F. & Barry, T. N. (1976). Factors affecting the nutritive value of silage. In Outlook on Agriculture (in the Press).CrossRefGoogle Scholar
Wilson, R. F. & Wilkins, R. J. (1972). An evaluation of laboratory ensiling techniques. Journal of the Science of Food and Agriculture 23, 377–85.CrossRefGoogle Scholar