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Costs of preventive agronomic measures to reduce deoxynivalenol in wheat

Published online by Cambridge University Press:  10 April 2017

A. ZORN*
Affiliation:
Agroscope, Tänikon, 8356 Ettenhausen, Switzerland
T. MUSA
Affiliation:
Agroscope, Reckenholzstrasse 191, 8046 Zürich, Switzerland
M. LIPS
Affiliation:
Agroscope, Tänikon, 8356 Ettenhausen, Switzerland
*
*To whom all correspondence should be addressed. Email: [email protected]

Summary

Cereals are of major importance in human and animal nutrition, and the mycotoxin content is of great health and economic concern for the food sector and consumers. In Europe, Fusarium graminearum (FG) is the prevalent Fusarium species leading to Fusarium head blight on small grain cereals and contamination of grains by its main mycotoxin deoxynivalenol (DON). The present study assessed the costs of preventive agronomic measures to reduce the risk of DON contamination in wheat besides the use of fungicides. The abatement costs were calculated by linking actual data on wheat production costs and profits with assessments of DON contents based on results of the forecast model FusaProg for the period 2005–2011. Analysis revealed that ploughing was a relatively efficient measure to reduce DON risk compared with modifying crop rotation or growing a more FG-resistant wheat variety. Given a threshold value of 1·25 mg DON/kg wheat, a reduction of 0·1 mg DON was related to additional production costs of at least 2·5%. These economic findings are of relevance for farmers and policy makers in order to define sustainable production systems enabling both a high level of food safety and reducing the use of plant protection products.

Type
Crops and Soils Research Papers
Copyright
Copyright © Cambridge University Press 2017 

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References

REFERENCES

AGRIDEA (2005–2011a). Deckungsbeiträge 2005–2011. Lindau, Switzerland: AGRIDEA.Google Scholar
AGRIDEA (2005–2011b). Preiskatalog 2005–2011. Lindau, Switzerland: AGRIDEA.Google Scholar
Agroscope (2006–2012). Grundlagenberichte 2005–2011. Zentrale Auswertung von Buchhaltungsdaten. Ettenhausen, Switzerland: Agroscope.Google Scholar
Agroscope (2006–2007). Kostenelemente und Entschädigungsansätze für die Benutzung von Landmaschinen. Ettenhausen, Switzerland: Forschungsanstalt Agroscope Reckenholz-Tänikon ART.Google Scholar
Agroscope (2008–2011). Maschinenkosten 2008–2011. Ettenhausen, Switzerland: Agroscope.Google Scholar
Agroscope (2010–2013). Blé d'automne 2009/2010/2011/2012 – Winterweizen 2009/2010/2011/2012. Nyon, Switzerland: Agroscope.Google Scholar
Aho, E., Schwaag Serger, S., Mönig, W., Wilson, P., Garmendia, C., Steinberg, M. & Swieboda, P. (2014). Outriders for European Competitiveness – European Innovation Partnerships (EIPs) as a Tool for Systemic Change. Report of the Independent Expert Group. Luxembourg: Publications Office of the European Union.Google Scholar
Bateman, G. L., Gutteridge, R. J., Gherbawy, Y., Thomsett, M. A. & Nicholson, P. (2007). Infection of stem bases and grains of winter wheat by Fusarium culmorum and F. graminearum and effects of tillage method and maize-stalk residues. Plant Pathology 56, 604615.Google Scholar
Blum, A., Chervet, A., Forrer, H.-R., Vogelgsang, S. & Schmid, F. (2011). Fusarien in Getreide. Lindau, Switzerland: AGRIDEA.Google Scholar
Bundesamt für Landwirtschaft (2013). Agrarbericht. Bern, Switzerland: BLW.Google Scholar
Charles, R., Cholley, E. & Frei, P. (2011). Fruchtfolge, Bodenbearbeitung, Sorte und Fungizidschutz in der Getreideproduktion. Agrarforschung Schweiz 2, 212219.Google Scholar
Commission of the European Communities (2006). Commission regulation (EC) No 1881/2006 of 19 December 2006 setting maximum levels for certain contaminants in foodstuffs. Official Journal of European Union L364, 524.Google Scholar
Courvoisier, N., Häner, L. L., Bertossa, M., Thévoz, E., Anders, M., Stoll, P., Weisflog, T., Dugon, J. & Grünig, K. (2015). Liste der empfohlenen Getreidesorten für die Ernte 2016. Agrarforschung Schweiz 6(supplement), 16.Google Scholar
Dill-Macky, R. & Jones, R. K. (2000). The effect of previous crop residues and tillage on fusarium head blight of wheat. Plant Disease 84, 7176.Google Scholar
Edwards, S. G. (2004). Influence of agricultural practices on Fusarium infection of cereals and subsequent contamination of grain by trichothecene mycotoxins. Toxicology Letters 153, 2935.Google Scholar
Eidgenössisches Departement für Wirtschaft, Bildung und Forschung (WBF) (2016). Aktionsplan zur Risikoreduktion und nachhaltigen Anwendung von Pflanzenschutzmitteln. Bern, Switzerland: Schweizerische Eidgenossenschaft.Google Scholar
European Food Safety Authority (2013). Deoxynivalenol in food and feed: occurrence and exposure. EFSA Journal 11, 33793434.Google Scholar
European Parliament & Council of the European Union (2009). Directive 2009/128/EC of the European Parliament and of the Council of 21 October 2009 establishing a framework for Community action to achieve the sustainable use of pesticides. Official Journal of European Union L309, 7186.Google Scholar
Hensche, H.-U., Lorleberg, W., Schleyer, A., Wildraut, C., Kathmann, J. & Orth, S. (2011). Volkswirtschaftliche Neubewertung des gesamten Agrarsektors und seiner Netzwerkstrukturen. Forschungsberichte des Fachbereichs Agrarwirtschaft Soest No. 27. Soest, Germany: Fachhochschule Südwestfalen.Google Scholar
Jard, G., Liboz, T., Mathieu, F., Guyonvarch, A. & Lebrihi, A. (2011). Review of mycotoxin reduction in food and feed: from prevention in the field to detoxification by adsorption or transformation. Food Additives & Contaminants: Part A Chemistry, Analysis, Control, Exposure & Risk Assessment 28, 15901609.Google Scholar
Jossi, W., Zihlmann, U., Valenta, A., Scherrer, C., Krebs, H., Dubois, D., Fried, P. M., Malitius, O., Anken, T., Sidler, A. & Bergmann, F. (2002). Vielseitige Fruchtfolge fördert die Ertragsfähigkeit. Agrarforschung Schweiz 9, 9095.Google Scholar
Landschoot, S., Audenaert, K., Waegeman, W., De Baets, B. & Haesaert, G. (2013). Influence of maize–wheat rotation systems on Fusarium head blight infection and deoxynivalenol content in wheat under low versus high disease pressure. Crop Protection 52, 1421.Google Scholar
Lips, M. & Gazzarin, C. (2013). Zusätzliche Kosten für Qualitätsmerkmale. In Herausforderungen des globalen Wandels für Agrarentwicklung und Welternährung: 52. Jahrestagung der Gesellschaft für Wirtschafts- und Sozialwissenschaften des Landbaues e.V. vom 26. bis 28. September 2012 in Hohenheim (Eds Bahrs, E., Becker, T., Birner, R., Brockmeier, M., Dabbert, S., Doluschitz, R., Grethe, H., Lippert, C. & Thiele, E.), pp. 475476. Münster, Germany: Landwirtschaftsverlag.Google Scholar
Logrieco, A., Bottalico, A., Mulé, G., Moretti, A. & Perrone, G. (2003). Epidemiology of toxigenic fungi and their associated mycotoxins for some Mediterranean crops. European Journal of Plant Pathology 109, 645667.Google Scholar
Mouron, P. & Musa, T. (2014). DON-Risiko wirtschaftlich vermeiden. In Die Wettbewerbsfähigkeit des Schweizerischen Pflanzenbaus verbessern: Resultate und Erfahrungen des Agroscope Forschungsprogramms ProfiCrops (Ed. Agroscope), p. 69. Wädenswil, Switzerland: Agroscope.Google Scholar
Musa, T., Hecker, A., Vogelgsang, S. & Forrer, H. R. (2007). Forecasting of Fusarium head blight and deoxynivalenol content in winter wheat with FusaProg. EPPO Bulletin 37, 283289.Google Scholar
Nemecek, T., Huguenin-Elie, O., Dubois, D., Gaillard, G., Schaller, B. & Chervet, A. (2011). Life cycle assessment of Swiss farming systems: II. Extensive and intensive production. Agricultural Systems 104, 233245.Google Scholar
Niens, C., Strack, M. & Marggraf, R. (2014). Parental risk perception of mycotoxins and risk reduction behaviour. British Food Journal 116, 10141030.Google Scholar
Noleppa, S. & von Witzke, H. (2013). Der gesamtgesellschaftliche Nutzen von Pflanzenschutz in Deutschland. Frankfurt am Main, Germany: Industrieverband Agrar e.V.Google Scholar
Prandini, A., Sigolo, S., Filippi, L., Battilani, P. & Piva, G. (2009). Review of predictive models for Fusarium head blight and related mycotoxin contamination in wheat. Food and Chemical Toxicology 47, 927931.Google Scholar
Qualitätsstrategie der Schweizerischen Land- und Ernährungswirtschaft (2014). Vision und Ziele der Eiweissstrategie (Projekt der Qualitätsstrategie). Courtételle, Switzerland: Sekretariat Qualitätsstrategie.Google Scholar
QuNaV (2013). Verordnung über die Förderung von Qualität und Nachhaltigkeit in der Land- und Ernährungswirtschaft (SR 910·16). Bern, Switzerland: Schweizerische Bundesrat. AS 2013 3879.Google Scholar
Raupach, K. & Marggraf, R. (2013). Unzureichender Verbraucherschutz vor dem Mykotoxin Deoxynivalenol – Aktuelle Situation und Verbesserungsmöglichkeiten. In Herausforderungen des globalen Wandels für Agrarentwicklung und Welternährung (Eds Bahrs, E., Becker, T., Birner, R., Brockmeier, M., Dabbert, S., Doluschitz, R., Grethe, H., Lippert, C. & Thiele, E.), pp. 259269. Munich, Germany: Gesellschaft für Wirtschafts- und Sozialwissenschaften des Landbaues e. V.Google Scholar
Schaafsma, A. W. & Hooker, D. C. (2007). Climatic models to predict occurrence of Fusarium toxins in wheat and maize. International Journal of Food Microbiology 119, 116125.Google Scholar
Schneider, M. (2009). Fruchtfolgegestaltung und konservierende Bodenbearbeitung/Direktsaat – Eine pflanzenbaulich/ökonomische Analyse. PhD thesis, Technische Universität München, München, Germany.Google Scholar
Shephard, G. S. (2006). Mycotoxins in the context of food risks and nutrition issues. In The Mycotoxin Factbook: Food and Feed Topics (Eds Barug, D., Bhatnagar, D., Van Egmond, H. P., Van der Kamp, J. W., Van Osenbruggen, W. A. & Visconti, A.), pp. 2136. Wageningen, Netherlands: Wageningen Academic Publishers.Google Scholar
Siegel, D. & Babuscio, T. (2011). Mycotoxin management in the European cereal trading sector. Food Control 22, 11451153.Google Scholar
Spycher, S., Badertscher, R. & Daniel, O. (2013). Indikatoren für den Einsatz von Pflanzenschutzmitteln in der Schweiz. Agrarforschung Schweiz 4, 192199.Google Scholar
Strickhof (2013). Feldbau. Lindau, Switzerland: Strickhof. Available online at: http://www.strickhof.ch/ausbildungs-undversuchsbetrieb/feldbau/ (accessed 9 February 2017).Google Scholar
Swiss granum (2013). Medienmitteilung, 16.10.2013: Positive Bilanz des Mykotoxin-Monitorings 2013 von Swiss Granum. Bern, Switzerland: Schweizerische Branchenorganisation Getreide, Ölsaaten und Eiweisspflanzen.Google Scholar
Swiss National Bank (SNB) (2016). Zinssätze und Devisenkurse. Zürich, Switzerland: SNB.Google Scholar
van der Fels-Klerx, H., Kandhai, M., Brynestad, S., Dreyer, M., Börjesson, T., Martins, H., Uiterwijk, M., Morrison, E. & Booij, C. (2009). Development of a European system for identification of emerging mycotoxins in wheat supply chains. World Mycotoxin Journal 2, 119127.Google Scholar
Vogelgsang, S., Hecker, A., Musa, T., Dorn, B. & Forrer, H. R. (2011). On-farm experiments over 5 years in a grain maize/winter wheat rotation: effect of maize residue treatments on Fusarium graminearum infection and deoxynivalenol contamination in wheat. Mycotoxin Research 27, 8196.Google Scholar
Wegulo, S. N. (2012). Factors influencing deoxynivalenol accumulation in small grain cereals. Toxins 4, 11571180.Google Scholar
Wendt, H. & Peter, G. (2014). Gestiegene Erzeugerpreise für tierische Erzeugnisse treiben den Erzeugeranteil nach oben. Braunschweig, Germany: Thünen Institut.Google Scholar
West, J. S., Holdgate, S., Townsend, J. A., Edwards, S. G., Jennings, P. & Fitt, B. D. L. (2012). Impacts of changing climate and agronomic factors on Fusarium ear blight of wheat in the UK. Fungal Ecology 5, 5361.Google Scholar
Wittmer, I., Moschet, C., Simovic, J., Singer, H., Stamm, C., Hollender, J., Junghans, E. M. & Leu, C. (2014). Über 100 Pestizide in Fliessgewässern. Aqua & Gas 3, 3243.Google Scholar
Zandonella, R., Sutter, D., Liechti, R. & von Stokar, T. (2014). Volkswirtschaftliche Kosten des Pestizideinsatzes in der Schweiz. Zürich, Switzerland: INFRAS by order of Greenpeace, Pro Natura, SVS/BirdLife Schweiz, WWF.Google Scholar
Zukunftsinstitut (2013). Food Report 2014. Frankfurt am Main, Germany: Zukunftsinstitut.Google Scholar