SERS-Based Nanosensor Detects Pesticides on Fruit

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SOLNA, Sweden, June 13, 2022 — Researchers at the Karolinska Institutet in Sweden developed a nanosensor based on surface-enhanced Raman spectroscopy or scattering (SERS). The proof-of-concept method uses flame-sprayed silver nanoparticles to increase the signal of chemicals.

SERS can be used to increase the diagnostic signals of biomolecules on a metal surface by more than 1 million times. It has been used in chemical and environmental analysis to detect biomarkers for various diseases. High production costs and limited batch-to-batch reproducibility, however, have so far hindered widespread application in food safety diagnostics.

The researchers hope that the newly developed sensors could be used to uncover food pesticides before consumption.

“Reports show that up to half of all fruits sold in the EU contain pesticide residues that in larger quantities have been linked to human health problems,” said Georgios Sotiriou, principal researcher at the institute's Department of Microbiology, Tumor and Cell Biology and the study’s corresponding author. “However, current techniques for detecting pesticides on single products before consumption are restricted in practice by the high cost and cumbersome manufacturing of its sensors. To overcome this, we developed inexpensive and reproducible nanosensors that could be used to monitor traces of fruit pesticides at, for example, the store.”

The researchers’ SERS nanosensor uses flame spray — a well-established and cost-effective technique for depositing metallic coating — to deliver small droplets of silver nanoparticles onto a glass surface. “The flame spray can be used to quickly produce uniform SERS films across large areas, removing one of the key barriers to scalability,” said Haipeng Li, a postdoctoral researcher in Sotiriou’s lab, as well as the study’s first author.

The researchers fine-tuned the distance between the individual silver nanoparticles to enhance their sensitivity. To test the sensors’ substance-detecting ability, the team applied a thin layer of tracer dye on top of the sensors and used a spectrometer to uncover their molecular fingerprints. The sensors reliably and uniformly detected the molecular signals. Additionally, tests after 2.5 months showed that their performance remained intact, underscoring their shelf life potential and feasibility for large-scale production, according to the researchers.

Flame nanoparticle deposition was used to produce robust nanosensors that can detect pesticide residues on apple surfaces within minutes. Researchers at Karolinska Institutet developed nanosensors that canbe used to detect the presence of pesticides on food items prior to consumption. Courtesy of Haipeng Li and Georgios A Sotiriou.
Flame nanoparticle deposition was used to produce robust nanosensors that can detect pesticide residues on apple surfaces within minutes. Researchers at Karolinska Institutet developed nanosensors that can be used to detect the presence of pesticides on food items before consumption. Courtesy of Haipeng Li and Georgios A Sotiriou. 
To test for practical application, the researchers calibrated the sensors to detect low concentrations of a toxic agricultural pesticide, and a small amount of the pesticide was placed on part of an apple. The residues were then collected with a cotton swab that was immersed in a solution to dissolve the pesticide molecules. The solution was dropped on the sensor, which confirmed the presence of pesticides. 

Following the proof-of-concept demonstration, the researchers will explore whether the nanosensors can be applied to other areas. The researchers identified one such application as biomarker discovery for specific diseases at the point-of-care in resource-limited settings.

The research was published in Advanced Science (

Published: June 2022
The use of atoms, molecules and molecular-scale structures to enhance existing technology and develop new materials and devices. The goal of this technology is to manipulate atomic and molecular particles to create devices that are thousands of times smaller and faster than those of the current microtechnologies.
surface-enhanced raman spectroscopy
Surface-enhanced Raman spectroscopy (SERS) is an analytical technique that combines the principles of Raman spectroscopy with the enhancement provided by nanostructured metallic surfaces. Raman spectroscopy is a method used to study vibrational, rotational, and other low-frequency modes in a system by measuring the inelastic scattering of monochromatic light, typically from a laser source. SERS enhances the Raman signal by many orders of magnitude, enabling the detection and identification of...
Research & TechnologyspectroscopydetectionSensors & DetectorsKarolinska InstitutetSwedenAdvanced ScienceMaterialssilvernanoparticlesnanotechnologySERSsurface-enhanced Raman spectroscopyHaipeng LiGeorgios A Sotiriouchemicals

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