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Quick, Cheap Method for Detecting Glyphosate

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News

Quick, Cheap Method for Detecting Glyphosate

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Glyphosate is a very widely used herbicide. It is suspected to be carcinogenic, which is why a quick, low-cost method for detecting glyphosate would be highly beneficial. Researchers at Leipzig University and Technische Universität Dresden have spent more than a year working on a solution in a collaborative project with three companies from Saxony. Professor Tilo Pompe from the Institute of Biochemistry at Leipzig University has now reported on the scientific basis of the project together with his colleagues in the journal “Biosensors and Bioelectronics”.

“Until now, scientists have used costly laboratory methods to detect glyphosate. The detection principle we have developed uses the natural reaction of glyphosate in plants. By imitating this mechanism, the detection principle is highly specific,” he said. The corresponding enzyme is bound to a chip surface. During detection, elastic hydrogel microparticles bind to this surface. If glyphosate is present in the detection solution, then depending on the concentration this inhibits the binding of the microparticles to the chip surface. “By using microparticle binding, the detection method offers an extremely high level of sensitivity with regard to pesticide limits for drinking water,” said Pompe. At the same time, the method could be applied in practice as a simple, mobile detection principle using optical readout procedures.


For this reason, the current research project is also working with Saxon companies to develop a mobile readout device. At the same time, a patent application has been filed for the detection principle and companies are currently being sought to bring it to market.

Reference
Picomolar glyphosate sensitivity of an optical particle-based sensor utilizing biomimetic interaction principles. David Rettke, Julia Döring, Steve Martin, Tom Venus, Irina Estrela-Lopis, Stephan Schmidt, Kai Ostermann, Tilo Pompe. Biosensors and Bioelectronics, Volume 165, 1 October 2020, 112262, https://doi.org/10.1016/j.bios.2020.112262.


This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.

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