Chemical and analytical support for the safe use of the fungicide pidiflumetofen in agricultural practice

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Introduction. The launch of chemical compositions based on pydiflumetofen, which has already proven itself in global agricultural practice as an effective means of suppressing mycotoxin-producing fungi, on the Russian market has set the task of chemical and analytical support for its safe use.

The aim of the study was to develop methods for determining residual amounts of pydiflumetofen in plant products and environmental objects (water, soil, air), which would be available for wide implementation in analytical laboratories, with subsequent use to assess the safety of pesticide application technology on grain crops.

Materials and methods. High-performance liquid chromatography with a diode array detector was used for measurements. The sample preparation was based on the classical scheme, which consists of extracting the substance from plant samples and soil with a mixture of acetonitrile and water, followed by purification of the extract using solid-phase extraction (SPE). Concentration of the water sample with its simultaneous purification was performed on SPE cartridges. Sampling of air from the working area was performed using paper filters, and atmospheric air was sampled using XAD-2 sorption tubes.

Results. The optimal conditions for the chromatographic separation of pydiflumetofen were selected: a column with a reversed phase (C18), the mobile phase is acetonitrile: water (75:25, by volume), the mode is isocratic, the wavelength is 230 nm. Absolute calibration on a solvent was used. The calibration characteristic is linear in the concentration range of 0.05–0.1 µg/ml, the correlation coefficient is more than 0.99. The lower limit of the detectable concentrations (in grain and soil 0.01 mg/kg, straw – 0.05 mg/kg, water – 0.001 mg/L, air of the working area – 0.01 mg/m3, atmospheric air – 0.005 mg/m3) corresponds to the established hygienic standards.

Limitations. In the study, only cereal grains (wheat, barley) were considered as plant products.

Conclusion. The developed methods were used to assess the safety of the pesticide application technology on grain crops. No residual amounts of the active substance were detected in the elements of the crop (grain, straw) of winter wheat and spring barley over a two-year observation period. Laboratory studies have confirmed the substance to be retained in the upper layers of soil, which limits its penetration into groundwater. The results of the hygienic assessment of the technology of ground spraying of field crops showed the risk to workers to be acceptable.

Compliance with ethical standards. The study does not require a biomedical ethics committee opinion.

Contribution:
Rakitskiy V.N. — concept and design of the study;
Bragina I.V. — concept and design of the study;
Bondareva L.G. — collection and processing of material, writing the text, editing;
Fedorova N.E. — concept and design of the study, collection and processing of material, writing the text, editing.
All authors are responsible for the integrity of all parts of the manuscript and approval of the manuscript final version.

Conflict of interest. The authors declare no conflict of interest.

Acknowledgement. The study had no sponsorship.

Received: November 4, 2024 / Accepted: December 3, 2024 / Published: December 28, 2024

作者简介

Valery Rakitskiy

Federal Scientific Center of Hygiene named after F.F. Erisman

Email: vtox@yandex.ru

DSc (Medicine), Academician of the RAS, Scientific Director of the Institute of Hygiene, Pesticide Toxicology and Chemical Safety, Federal Scientific Center of Hygiene named after F.F. Erisman, Mytishchi, 141014, Russian Federation

e-mail: vtox@yandex.ru

Irina Bragina

Federal Service for Supervision of Consumer Rights Protection and Human Welfare

Email: bragina_IV@gsen.ru

DSc (Medicine), Deputy Head of the Federal Service for Supervision of Consumer Rights Protection and Man Wellbeing, Moscow, 117105, Russian Federation

e-mail: bragina_IV@gsen.ru

Lydia Bondareva

Federal Scientific Center of Hygiene named after F.F. Erisman

Email: lydiabondareva@gmail.com

PhD (Chemistry), Senior researcher, Department of an analytical control methods, Federal Scientific Center of Hygiene named after F.F. Erisman, Mytishchi, 141014, Russian Federation

e-mail: lydiabondareva@gmail.com

Nataliia Fedorova

Federal Scientific Center of Hygiene named after F.F. Erisman

编辑信件的主要联系方式.
Email: analyt1@yandex.ru

DSc (Biology), Chief Researcher, Department of an analytical control methods, Federal Scientific Center of Hygiene named after F.F. Erisman, Mytishchi, 141014, Russian Federation

e-mail: analyt1@yandex.ru

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