Sensing strategy based on Carbon Quantum Dots obtained from riboflavin for the identification of pesticides

Sensing strategy based on Carbon Quantum Dots obtained from riboflavin for the identification of pesticides

•CQD and AgNP were combined to develop a pesticides sensing strategy using FRET phenomenon.•A fast pesticide identification was applied in real samples of rice, carrot, orange and pepper.•The sensibility of the sensing strategy achieved 250 ng.mL−1. In this work, a fluorescent sensing strategy was d...

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Veröffentlicht in:Sensors and actuators. B, Chemical Chemical, 2019-12, Vol.301, p.127149, Article 127149
Hauptverfasser: Carneiro, S.V., de Queiroz, V.H.R., Cruz, A.A.C., Fechine, L.M.U.D., Denardin, J.C., Freire, R.M., do Nascimento, R.F., Fechine, P.B.A.
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Sprache:eng
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Carbon
Carbon Quantum Dots
Chlorpyrifos
Confidence intervals
Design of experiments
Detection
Discriminant analysis
Energy transfer
Fluorescence
Food
Nanoparticles
Pesticides
Quantum dots
Riboflavin
Sensor
Silver
Silver nanoparticles
Strategy
Synthesis
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container_issue
container_start_page 127149
container_title Sensors and actuators. B, Chemical
container_volume 301
creator Carneiro, S.V.
de Queiroz, V.H.R.
Cruz, A.A.C.
Fechine, L.M.U.D.
Denardin, J.C.
Freire, R.M.
do Nascimento, R.F.
Fechine, P.B.A.
description •CQD and AgNP were combined to develop a pesticides sensing strategy using FRET phenomenon.•A fast pesticide identification was applied in real samples of rice, carrot, orange and pepper.•The sensibility of the sensing strategy achieved 250 ng.mL−1. In this work, a fluorescent sensing strategy was developed for identification of pesticides in food, which was obtained thought the interaction of carbon quantum dots (CQDs) and silver nanoparticles (AgNPs). The CQDs were synthesized from riboflavin according to an experimental design. On this basis, the most appropriate samples were selected and structurally characterized, where AgNPs efficiently quench the fluorescence of CQDs due a fluorescence resonance energy transfer (FRET). The CQDs was titrationed with AgNPs (Ag@PAA and Ag@bPEI), determining the best concentration of quenching (0.228 and 3.030 pmol.L−1, respectively). Furthermore, a strategy of sensing was developed in order to identify the pesticides propanyl, parathion, dimethoate, chlorpyrifos and pyrimicarb, which were also verified in real samples of rice, carrot, orange and pepper. The results were analyzed by linear discriminant analysis (LDA), obtaining different response patterns against pesticide concentrations, with confidence level of 95%. After that, assays were performed using lower concentrations of the analytes. It was verified that in pepper extract, the sensibility of the sensing strategy was 250 ng.mL−1. Therefore, the CQDs synthesized in this work may be considered a powerful tool to identify pesticides in food samples.
doi_str_mv 10.1016/j.snb.2019.127149
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In this work, a fluorescent sensing strategy was developed for identification of pesticides in food, which was obtained thought the interaction of carbon quantum dots (CQDs) and silver nanoparticles (AgNPs). The CQDs were synthesized from riboflavin according to an experimental design. On this basis, the most appropriate samples were selected and structurally characterized, where AgNPs efficiently quench the fluorescence of CQDs due a fluorescence resonance energy transfer (FRET). The CQDs was titrationed with AgNPs (Ag@PAA and Ag@bPEI), determining the best concentration of quenching (0.228 and 3.030 pmol.L−1, respectively). Furthermore, a strategy of sensing was developed in order to identify the pesticides propanyl, parathion, dimethoate, chlorpyrifos and pyrimicarb, which were also verified in real samples of rice, carrot, orange and pepper. The results were analyzed by linear discriminant analysis (LDA), obtaining different response patterns against pesticide concentrations, with confidence level of 95%. After that, assays were performed using lower concentrations of the analytes. It was verified that in pepper extract, the sensibility of the sensing strategy was 250 ng.mL−1. 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B, Chemical</title><description>•CQD and AgNP were combined to develop a pesticides sensing strategy using FRET phenomenon.•A fast pesticide identification was applied in real samples of rice, carrot, orange and pepper.•The sensibility of the sensing strategy achieved 250 ng.mL−1. In this work, a fluorescent sensing strategy was developed for identification of pesticides in food, which was obtained thought the interaction of carbon quantum dots (CQDs) and silver nanoparticles (AgNPs). The CQDs were synthesized from riboflavin according to an experimental design. On this basis, the most appropriate samples were selected and structurally characterized, where AgNPs efficiently quench the fluorescence of CQDs due a fluorescence resonance energy transfer (FRET). The CQDs was titrationed with AgNPs (Ag@PAA and Ag@bPEI), determining the best concentration of quenching (0.228 and 3.030 pmol.L−1, respectively). 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subjects Carbon
Carbon Quantum Dots
Chlorpyrifos
Confidence intervals
Design of experiments
Detection
Discriminant analysis
Energy transfer
Fluorescence
Food
Nanoparticles
Pesticides
Quantum dots
Riboflavin
Sensor
Silver
Silver nanoparticles
Strategy
Synthesis
title Sensing strategy based on Carbon Quantum Dots obtained from riboflavin for the identification of pesticides
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