Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-30T21:20:46.016Z Has data issue: false hasContentIssue false

Carry-over of aflatoxin from cows' food to milk

Published online by Cambridge University Press:  02 September 2010

A. Veldman
Affiliation:
CLO-Institute for Animal Nutrition ‘De Schothorst’, PO Box 533, 8200 AM Lelystad, The Netherlands
J. A. C. Meijs
Affiliation:
CLO-Institute for Animal Nutrition ‘De Schothorst’, PO Box 533, 8200 AM Lelystad, The Netherlands
G. J. Borggreve
Affiliation:
CLO-Institute for Animal Nutrition ‘De Schothorst’, PO Box 533, 8200 AM Lelystad, The Netherlands
J. J. Heeres-van der Tol
Affiliation:
CLO-Institute for Animal Nutrition ‘De Schothorst’, PO Box 533, 8200 AM Lelystad, The Netherlands
Get access

Abstract

Two experiments were made. In experiment 1, dairy cows in early lactation (2 to 4 weeks) and dairy cows in late lactation (34 to 36 weeks) were given aflatoxin B, (AFBt)at a level of 34 to 39 fig/day by feeding them contaminated compound food. The aflatoxin Mrcontent(AFMj) of raw milk was determined four times during the experimental period of 14 days. The milk yield was measured daily.

The carry-over rate of aflatoxin was proportionately 0·062 and 0·018 for cows in early and late lactation respectively. This difference was not only due to milk production level but possibly also associated to AFB, liver metabolism.

In experiment 2, eight high (40 kg milk per day) and eight low (16 kg milk per day) milk yielding cows, carry-over of AFB1 from compound food into AFM, in milk was measured at different levels ofAFB7 intake ranging from 7 to 57 fig/day. Independent of AFBj-intake, high-producing dairy cows had a higher carry-over rate than low producing animals (proportionately 0·038 v. 0·025). Carry-over ofAFB1 to AFM, was linearly correlated with milk yield. Variations in the level of AFM1 in milk of individual cows were not due to variations in milk yield. The relationship between AFB2 intake per day and AFM^content in milk per kg could be described by the formula: AFMj (ng/kg milk) = 119 AFB, intake (fig per cow per day) + 1·9. This means that in order to produce milk with less than 0·05 fig AFM, per kg milk the average daily individual intake in a herd should be limited to 40 fig AFB7 per day.

As dairy cows in their early to mid lactation period consume large quantities of compound food, a maximum level of AFB3 in dairy foods has to be set at an acceptable daily intake (ADI) value to guarantee that AFM1 levels in milk do not exceed tolerable levels.

Type
Research Article
Copyright
Copyright © British Society of Animal Science 1992

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

Allcroft, R., Roberts, B. A. and Lloyd, M. K. 1968. Excretion of aflatoxin in a cow. Food Cosmetic Toxicology 6: 619625.CrossRefGoogle Scholar
Commission of the European Communities. 1983. Third Commission Directive of 28 July 1983 amending the annex to Council Directive 74/63/EEC on the fixing of maximum permitted levels of undesirable substances and products in feeding stuffs. Official Journal of the European Communities L222: 3132.Google Scholar
Kiermeier, F., Reinhardt, V. and Behringer, G. 1975. Zum vorkommen von aflatoxinen in rohmilch. Deutsche Lebensmittel Rundschau 71: 3538.Google Scholar
Lafont, P., Lafont, J., Mousset, S. and Fryasinnet, C. 1980. Etude de la contamination du lait de vache lors de l'ingestion de faibles quantites d'aflatoxine. Annales de Nutrition et Alimentation 34: 699708.Google Scholar
Munksgaard, L., Larsen, J., Werner, H., Anderson, P. E. and Viuf, B. T. 1987. Carry-over of aflatoxin from cows' feed to milk and milk products. Milchwissenschaft 42: 165167.Google Scholar
Paulsch, W. E., Van Egmond, H. P. and Sizoo, E. A. 1988. Liquid chromatographic determination of aflatoxins in mixed feeds containing citrus pulp. Journal of the Association of Official Analytical Chemists 71: 957961.Google Scholar
Steiner, J., Blüthgen, A., Heeschen, W., Wetzel, S. and Hammann, J. 1990. Untersuchungen zur beeinflussung der ausscheidung von aflatoxin M1 durch polychlorierte bifhenyle beim laktierenden rind. Kieler Milchwirtschaftliche Forsungberichte 42: 543552.Google Scholar
Tuinstra, L. G. M. Th. and Haasnoot, W. 1982. Rapid HPLC method for the determination of aflatoxin M1 in milk at the nanogram/kg level. Zeitschrift für Analytische Chemie 312: 622623.Google Scholar
Van Egmond, H. P. 1989. Carry-over of aflatoxin B1 into aflatoxin M1 in milk. In Mycotoxins in dairy products (ed Egmond, H. P. van), pp. 1216. Elsevier Applied Science Publishers, Amsterdam.Google Scholar