Environmental Science and Pollution Research

, Volume 20, Issue 12, pp 9034–9043 | Cite as

Study on the photodegradation of amidosulfuron in aqueous solutions by LC-MS/MS

Research Article
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Abstract

Sulfonylurea herbicides are extensively widespread for the protection of a variety of crops and vegetables because of their low application rates, high selectivity and low persistency in the environment; unfortunately, their low persistence does not always correspond to a lower toxicity, since new species potentially more toxic and stable than the precursor herbicides can form, owing to natural degradation processes. Here, the photodegradation of amidosulfuron in aqueous solutions was studied by high-performance liquid chromatography with diode array detection and tandem mass spectrometry to identify the degradation products in order to outline the environmental fate of the molecules generating from the simulation of one of the natural processes that can occur, i.e., photoinduced degradation. The photodegradation process results in a first order kinetic reaction with a t 1/2 value of 276 h (11.5 days) and a kinetic constant of 0.0027 h−1, and three possible degradation products were identified. The results obtained are then compared to those obtained in previous works carried out in comparable experimental conditions about nicosulfuron and tribenuron-methyl, two sulfonylurea herbicides belonging to different classes, and to literature data: hypotheses on the existence of preferential degradation pathways are then drawn, in consequence of the molecular structure of the sulfonylurea pesticide. In particular, the use of organic solvents to obtain complete solubilization of the sample plays a fundamental role and deeply influences the degradation processes that, therefore, not always fully adhere to the actual natural photodegradation pathways. Moreover, considerations about toxicity were driven since the complete mineralisation of the sample is not reached: even when the parent pesticides are totally degraded, they are, however, transformed into other organic compounds showing, if subject to ecotoxicological tests, at least the same toxicity of the precursor herbicides. The evidence here presented suggests that, at least for the class of sulfonylurea pesticides, their professed low persistence actually does not produce any real advantage.

Keywords

Photodegradation Amidosulfuron Mass spectrometry detection Aqueous solutions Sulfonylurea pesticide Liquid chromatography 
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Notes

Acknowledgements

The authors gratefully acknowledge the financial support from AATF (Associazione Ambiente-Territorio e Formazione, Alessandria, Italy), from Regione Piemonte, Direzione Igiene e Sanità Pubblica (Turin, Italy) and from MIUR (Ministero Italiano Università e Ricerca, Rome, Italy).

Supplementary material

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11356_2013_1900_MOESM2_ESM.pdf (5 kb)
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References

  1. Andersen SM, Hertz PB, Holst T, Bossi R, Jacobsen CS (2001) Mineralisation studies of 14C-labelled metsulfuron-methyl, tribenuron-methyl, chlorsulfuron and thifensulfuron-methyl in one Danish soil and groundwater sediment profile. Chemosphere 45:775–782CrossRefGoogle Scholar
  2. Benzi M, Robotti E, Gianotti V (2011) HPLC-DAD-MSn to investigate the photodegradation pathway of nicosulfuron in aqueous solution. Anal Bioanal Chem 399:1705–1714CrossRefGoogle Scholar
  3. Bhattacherjee AK, Dureja P (1999a) Light-induced transformations of tribenuron-methyl in aqueous solution. Pestic Sci 55:183–188CrossRefGoogle Scholar
  4. Bhattacherjee AK, Dureja P (1999b) Light-induced transformations of tribenuron-methyl. Chemosphere 38:741–749CrossRefGoogle Scholar
  5. Bhattacherjee AK, Dureja P (2002) Light-induced transformations of tribenuron-methyl on glass, soil, and plant surface. J Environ Sci Health B 37:131–140CrossRefGoogle Scholar
  6. Bossi R, Vejrup K, Jacobsen CS (1999) Determination of sulfonylurea degradation products in soil by liquid chromatography-ultraviolet detection followed by confirmatory liquid chromatography-tandem mass spectrometry. J Chromatogr A 855:575–582CrossRefGoogle Scholar
  7. Braschi I, Pusino A, Gessa C, Bollag JM (2000) Degradation of primsulfuron by a combination of chemical and microbiological processes. Agric Food Chem 48:2565–2571CrossRefGoogle Scholar
  8. D.Lgs 152/2006 “Norme in materia ambientale” from the Italian Legislation in accordance with the European Directive 2000/60/CEGoogle Scholar
  9. IRSA Method n. 8030 (2003) Metodi analitici per le acque. APAT, RomeGoogle Scholar
  10. Livanainen E, Heinonen-Tanski H (1991) Degradation and leaching of chlorsulfuron in three different soils. Acta Agric Scand 41:85–92CrossRefGoogle Scholar
  11. Martins JMF, Mermoud A (1999) Transport of rimsulfuron and its metabolite in soil columns. Chemosphere 38:601–616CrossRefGoogle Scholar
  12. Martins JMF, Chevre N, Spack L, Tarradellas J, Mermoud A (2001) Degradation in soil and water and ecotoxicity of rimsulfuron and its metabolites. Chemosphere 45:515–522CrossRefGoogle Scholar
  13. Maurino V, Minero C, Pelizzetti E, Vincenti M (1999) Photocatalytic transformation of sulfonylurea herbicides over irradiated titanium dioxide particles. Colloids Surf A 151:329–338CrossRefGoogle Scholar
  14. Metzger L, Munier-Lamy C, Choné T, Belgy M-J, Andreux F, Védy J-C (1996) Fate of a sulfonylurea herbicide in an alluvional soil, as shown by experimental degradation of pyrimidine-2-14C-labeled rimsulfuron. Chemosphere 33:625–633CrossRefGoogle Scholar
  15. Morrica P, Fidente P, Seccia S (2004) Identification of photoproducts from imazosulfuron by HPLC. Biomed Chomatogr 18:450–456CrossRefGoogle Scholar
  16. Normative ISO6060:1989. Water quality determination of chemical oxygen demandGoogle Scholar
  17. Olmedo C, Deban L, Coca M, Vega M, de la Rosa F (1997) Electrochemical study of the herbicide tribenuron. Fresenius J Anal Chem 31:253–260Google Scholar
  18. Perreau F, Bados P, Kerhoas L, Nélieu S, Einhorn J (2007) Trace analysis of sulfonylurea herbicides and their metabolites in water using a combination of off-line or on-line solid-phase extraction and liquid chromatography-tandem mass spectrometry. Anal Bioanal Chem 388:1265–1273CrossRefGoogle Scholar
  19. Polati S, Bottaro M, Frascarolo P, Gosetti F, Gianotti V, Gennaro MC (2006) HPLC-UV and HPLC-MSn multiresidue determination of amidosulfuron, azimsulfuron, nicosulfuron, rimsulfuron, thifensulfuron methyl, tribenuron methyl, and azoxystrobin in surface waters. Anal Chim Acta 579:146–151CrossRefGoogle Scholar
  20. Polati S, Bottaro M, Frascarolo P, Gosetti F, Mazzucco E, Gianotti V, Pollici E, Piacentini L, Pavese G, Gennaro MC (2008) HPLC-DAD-MS/MS study of tribenuron methyl photodegradation in surface waters. J Am Soc Mass Spectrom 19:1221–1229CrossRefGoogle Scholar
  21. Sabadie J (2002) Nicosulfuron: alcholysis, chemical hydrolysis and degradation on various minerals. J Agric Food Chem 50:526–531CrossRefGoogle Scholar
  22. Saha S, Kulshrestha G (2002) Degradation of sulfosulfuron, a sulfonylurea herbicide, as influenced by abiotic factors. J Agric Food Chem 50:4572–4575CrossRefGoogle Scholar
  23. Sarmah AK, Sabadie J (2002) Hydrolysis of sulfonylurea herbicides in soils and aqueous solutions: a review. J Agric Food Chem 50:6253–6265CrossRefGoogle Scholar
  24. Scrano L, Bufo SA, Perucci P, Meallier P, Mansur M (1999) Photolysis and hydrolysis of rimsulfuron. Pestic Sci 55:955–961CrossRefGoogle Scholar
  25. Sleiman M, Ferronato C, Fenet B, Baudot R, Jaber F, Chovelon JM (2006) Development of HPLC/ESI-MS and HPLC/1H NMR methods for the identification of photocatalytic degradation products of iodosulfuron. Anal Chem 78:2957–2966CrossRefGoogle Scholar
  26. The E-Pesticide Manual, Version 3.2 2005–06, 13th edn, Tomlin CDS (ed), BCPC, Hampshire, UKGoogle Scholar
  27. Vulliet E, Emmelin C, Chovelon JM, Guillard C, Herrmann JM (2002) Photocatalytic degradation of sulfonylurea herbicides in aqueous TiO2. Appl Cata B 38:127–137CrossRefGoogle Scholar
  28. Vulliet E, Chovelon JM, Guillard C, Hermann JM (2003) Factors influencing the photocatalytic degradation of sulfonylurea herbicides by TiO2 aqueous suspension. J Photochem Photobiol 159:71–79CrossRefGoogle Scholar
  29. Vulliet E, Emmelin C, Chovelon JM (2004) Influence of pH and irradiation wavelength on the photochemical degradation of sulfonylureas. J Photochem Photobiol 163:69–75CrossRefGoogle Scholar
  30. Wei L, Yu H, Sun Y, Fen J, Wang L (1998) The effects of three sulfonylurea herbicides and their degradation products on the green algae, Chlorella pyrenoidosa. Chemosphere 37:747–751CrossRefGoogle Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2013

Authors and Affiliations

  1. 1.ARPA Valle d’AostaSaint-ChristopheItaly
  2. 2.Department of Scienze e Innovazione TecnologicaUniversity of Piemonte Orientale “Amedeo Avogadro”AlessandriaItaly

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