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Formation of biogenic amines in well fermented grass silages

Published online by Cambridge University Press:  27 March 2009

M. van Os
Affiliation:
DLO-Institute for Animal Science and Health (ID-DLO), Department of Ruminant Nutrition, PO Box 65, 8200 AB Lelystad, The Netherlands
P. G. van Wikselaar
Affiliation:
DLO-Institute for Animal Science and Health (ID-DLO), Department of Ruminant Nutrition, PO Box 65, 8200 AB Lelystad, The Netherlands
S. F. Spoelstra
Affiliation:
DLO-Institute for Animal Science and Health (ID-DLO), Department of Ruminant Nutrition, PO Box 65, 8200 AB Lelystad, The Netherlands

Summary

Biogenic amine formation was studied in silages made from perennial ryegrass. In 1991 two batches of grass from the same sward of the ID–DLO permanent pasture were wilted to either 250 or 450 g dry matter (DM)/kg, and ensiled in eight 1-litre laboratory silos for eachtreatment (Expt A). To induce differences in fermentation pattern, the grass was ensiled without additive (CON) or treated with formic acid (5 ml/kg; FA), cell wall degrading enzymes (2·1 ml/kg; ENZ), molasses (50 g/kg; MOL), or inoculated with Lactobacillus plantarum (107 colony forming units (CFU)/g; LP), a combination of Lactobacillus plantarum and Streptococcus faecium (105 CFU/g; LPSF), or Enterobacter sakazakii (6×lO6 CFU/g; EB). One silo for each treatment was opened after 1, 2, 4 and 7 days for pH determination and duplicate silos were opened after 10 and 90 days for pH determination and analysis of fermentation products. Two similar experiments (B and C) were performed using the CON, FA and LP treatments.

Total amine content of the grass was low (0·1–0·2 g/kg DM). The well preserved silages in each experiment contained considerable amounts of amines, ranging from 0·1 g/kg DM in the wilted LP and FA silages to 7·4 g/kg DM in a low DM CONsilage. Tyramine, cadaverine, putrescine and histamine were, in descending order, the principalbiogenic amines formed, representing together 90 (S.E. 9)% of the total biogenic amine contentof the silages. Formation of amines occurred mainly during the first 10 days of fermentation, and was highest in silages with a slow acidification rate. Ensiling at high DM content, with formic acid or inoculation with large numbers of lactic acid bacteria significantly (P < 0·01) reduced the amount of amines in the silage. Total and individual amine contents of the silages were significantly correlated with concentrations of ammonia and acetic acid. It was concluded that the formation of biogenic amines in grass silage is related to protein degradation, and that amine formation can be reduced by restriction of fermentation in the silage, or by achieving rapid acidification during the first phase of ensiling.

Type
Crops and Soils
Copyright
Copyright © Cambridge University Press 1996

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References

REFERENCES

Baile, C. A. & Della-Ferra, M. A. (1988). Physiology of control of food intake and regulation of energy balance in dairy cows. In Nutrition and Lactation of the Dairy Cow (Ed. Garnsworthy, P. C.), pp. 251261. London: Butterworths.CrossRefGoogle Scholar
Brady, C. J. (1966). The redistribution of nitrogen in silage by lactic-acid-producing bacteria. Australian Journal of Biological Sciences 19, 123130.CrossRefGoogle ScholarPubMed
Buchanan-Smith, J. G. & Phillip, L. E. (1986). Food intake in sheep following intraruminal infusion of extracts from lucerne silage with particular reference to organic acids and products of protein degradation. Journal of Agricultural Science, Cambridge 106, 611617.CrossRefGoogle Scholar
Choudhury, N., Hansen, W., Engesser, D., Hammes, W. P. & Holzapfel, W. H. (1990). Formation of histamine and tyramine by lactic acid bacteria in decarboxylase assay medium. Letters in Applied Microbiology 11, 278281.CrossRefGoogle Scholar
Dulphy, J. P. & Demarquilly, C. (1981). Problemes particuliers aux ensilages (Particular problems with silages). In Prévisions de la Valeur Nutritive des Aliments des Ruminants, pp. 81104. Versailles: INRA Publications.Google Scholar
Edwards, R. A., Dainty, R. H., Hibbard, C. M. & Ramantanis, S. V. (1987). Amines in fresh beef of normal pH and the role of bacteria in changes in concentration observed during storage in vacuum packs at chill temperatures. Journal of Applied Bacteriology 63, 421434.CrossRefGoogle ScholarPubMed
Genstat 5 Committee. (1987). Genstat 5 Reference Manual. Oxford: Clarendon Press.Google Scholar
Heron, S. J. E., Edwards, R. A. & McDonald, P. (1986). Changes in the nitrogenous components of gamma irradiated and inoculated ensiled ryegrass. Journal of the Science of Food and Agriculture 37, 979985.CrossRefGoogle Scholar
Hughes, A. D. (1970). The non-protein nitrogen composition of grass silages. II. The changes occurring during the storage of silage. Journal of Agricultural Science, Cambridge 75, 421431.CrossRefGoogle Scholar
Hughes, A. D. (1971). The non-protein nitrogen composition of grass silages. III. The composition of spoilt silages. Journal of Agricultural Science, Cambridge 76, 329336.CrossRefGoogle Scholar
Jackson, R. B. (1964). Volatile bases in ryegrass silage. Journal of the Science of Food and Agriculture 15, 308312.CrossRefGoogle Scholar
Jones-Owen, V. M. & Lechocki, S. A. (1974). A modified gas chromatographic method for lactate analysis. Clinical Biochemistry 7, 97101.CrossRefGoogle Scholar
Joosten, H. M. L. J. (1987). Conditions allowing the formation of biogenic amines in cheese. 3. Factors influencing the amounts formed. Netherlands Milk and Dairy Journal 41, 329357.Google Scholar
Joosten, H. M. L. J. (1988). The biogenic amine contents of Dutch cheese and their toxicological significance. Netherlands Milk and Dairy Journal 42, 2542.Google Scholar
Kemble, A. R. & Macpherson, H. T. (1954). Liberation of amino acids in perennial ryegrass during wilting. Biochemical Journal 58, 4649.CrossRefGoogle ScholarPubMed
Křižek, M. (1993). Biogenic amines in silage. 1. The occurrence of biogenic amines in silage. Archives for Animal Nutrition 43, 169177.Google ScholarPubMed
Lindgren, S., Petterson, K., Jonsson, A., Lingvall, P. & Kaspersson, A. (1985). Silage inoculation: selected strains, temperature wilting and practical application. Swedish Journal of Agricultural Research 15, 918.Google Scholar
Macpherson, H. T. & Violante, P. (1966 a). Ornithine, putrescine and cadaverine in farm silage. Journal of the Science of Food and Agriculture 17, 124127.CrossRefGoogle ScholarPubMed
Macpherson, H. T. & Violante, P. (1966 b). The influence of pH on the metabolism of arginine and lysine in silage. Journal of the Science of Food and Agriculture 17, 128130.CrossRefGoogle Scholar
McDonald, P., Henderson, A. R. & Heron, S. J. E. (1991). The Biochemistry of Silage, 2nd edn. Marlow, Bucks: Chalcombe Publications.Google Scholar
Meister, A (1965). Biochemistry of the Amino Acids, Volume I, 2nd edn. New York: Academic Press.Google Scholar
Miettinen, H., Setälä, J. & Moisio, T. (1991). Estimation of the effect of silage quality on silage palatability and silage intake in dairy cows. In Forage Conservation Towards 2000 (Eds Pahlow, G. & Honig, H.), pp. 408409. Braunschweig-Völkenrode: Institute of Grassland and Forage Research.Google Scholar
Ohshima, M. & McDonald, P. (1978). A review of the changes in nitrogenous compounds of herbage during ensilage. Journal of the Science of Food and Agriculture 29, 497505.CrossRefGoogle Scholar
Pahlow, G. (1991). Role of microflora in forage conservation. In Forage Conservation Towards 2000 (Eds Pahlow, G. & Honig, H.), pp. 46. Braunschweig-Völkenrode: Institute of Grassland and Forage Research.Google Scholar
Rauramaa, A., Setälä, J., Moisio, T., Heikkilä, T. & Lampila, M. (1987 a). The effect of inoculants and cellulase on the fermentation and microbiological composition of grass silage. I. Biochemical changes in the silages. Journal of Agricultural Science in Finland 59, 361370.Google Scholar
Rauramaa, A., SetäLä, J., Moisio, T., Sivelä, S., Heikkilä, T. & Lampila, M. (1987 b). The effect of inoculants and cellulase on the fermentation and microbiological composition of grass silage. II. Microbiological changes in the silages. Journal of Agricultural Science in Finland 59, 371377.Google Scholar
Richard, C. (1984). Genus VI. Enterobacter. In Bergey's Manual of Systematic Bacteriology, Vol. I (Eds Krieg, N. R. & Holt, J. G.), pp. 465476. Baltimore: Williams & Wilkins.Google Scholar
Rooke, J. A., Borman, A. J. & Armstrong, D. G. (1990). The effect of inoculation with Lactobacillus plantarum on fermentation in laboratory silos of herbage low in watersoluble carbohydrate. Grass and Forage Science 45, 143152.CrossRefGoogle Scholar
Searle, P. L. (1984). The Berthelot or indophenol reaction and its use in the analytical chemistry of nitrogen. The Analyst 109, 549568.CrossRefGoogle Scholar
Spoelstra, S. F. (1990). Comparison of the content of clostridial spores in wilted grass silage ensiled in either laboratory, pilot-scale or farm silos. Netherlands Journal of Agricultural Science 38, 423434.CrossRefGoogle Scholar
Spoelstra, S. F. (1991). Chemical and biological additives in forage conservation. In Forage Conservation Towards 2000 (Eds Pahlow, G. & Honig, H.), pp. 1012. Braunschweig-Völkenrode: Institute of Grassland and Forage Research.Google Scholar
Spoelstra, S. F. & Hindle, V. A. (1989). Influence of wilting on chemical and microbial parameters of grass relevant to ensiling. Netherlands Journal of Agricultural Science 37, 355364.CrossRefGoogle Scholar
Steel, R. G. D. & Torrie, J. H. (1980). Principles and Procedures of Statistics: A Biometrical Approach. Singapore: McGraw-Hill.Google Scholar
Tveit, B., Lingaas, F., Svendsen, M. & Sjaastad, Ø. V. (1992). Etiology of acetonemia in Norwegian cattle. 1. Effect of ketogenic silage, season, energy level and genetic factors. Journal of Dairy Science 75, 24212432.CrossRefGoogle ScholarPubMed
Villanueva, V. R. & Adlakha, R. C. (1978). Automated analysis of common basic amino acids, mono-, di-, and polyamines, phenolicamines and indoleamines in crude biological samples. Analytical Biochemistry 91, 264275.CrossRefGoogle ScholarPubMed
Van Vuuren, A. M., Van Der Koelen, C., Valk, H. & De Visser, H. (1993). Effects of partial replacement of ryegrass by low protein feeds on rumen fermentation and nitrogen loss by dairy cows. Journal of Dairy Science 76, 29822993.CrossRefGoogle ScholarPubMed
Voss, N. (1966). Über die Amin- und Ammoniakbildung im Gärfutter (About amine and ammonia formation in silages). Wirtschaftseigene Fuller 12, 161171.Google Scholar
Voss, N. (1967). Untersuchungen über den Proteinabbau in Gras- und Luzernesilage (Studies on protein degradation in grass and lucerne silages). Wirtschaftseigene Fuller 13, 130145.Google Scholar