Nanomolar detection of organic pollutant -tartrazine in food samples using zinc-metal organic framework/carbon nano fiber - composite modified screen-printed electrode

Nanomolar detection of organic pollutant -tartrazine in food samples using zinc-metal organic framework/carbon nano fiber - composite modified screen-printed electrode

In this study, we achieved a significant breakthrough by applying a binder-free Zn-MOF@CNF composite as a modifier on a screen-printed electrode (SPE) to achieve highly sensitive and selective detection of tartrazine (TRZ). This composite, with its unique rod-like structure for Zn-MOF and a curl thr...

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Veröffentlicht in:Journal of food composition and analysis 2024-09, Vol.133, p.106462, Article 106462
Hauptverfasser: Srinivasan, Praveenkannan, Sethuraman, Mathur Gopalakrishnan, Govindasamy, Mani, Gokulkumar, Kumar, Alothman, Asma A., Alanazi, Hasna A., Huang, Chi-Hsien
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Sprache:eng
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carbon
carbon nanofibers
detection limit
Electrochemical active surface area
electrochemistry
electrodes
electron transfer
food composition
ice cream
oxidation
pollutants
species
surface area
Synergistic interaction
tartrazine
Tartrazine detection
Zn-MOF@CNF composite
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container_issue
container_start_page 106462
container_title Journal of food composition and analysis
container_volume 133
creator Srinivasan, Praveenkannan
Sethuraman, Mathur Gopalakrishnan
Govindasamy, Mani
Gokulkumar, Kumar
Alothman, Asma A.
Alanazi, Hasna A.
Huang, Chi-Hsien
description In this study, we achieved a significant breakthrough by applying a binder-free Zn-MOF@CNF composite as a modifier on a screen-printed electrode (SPE) to achieve highly sensitive and selective detection of tartrazine (TRZ). This composite, with its unique rod-like structure for Zn-MOF and a curl thread-like morphology for carbon nanofibers (CNF), demonstrated a remarkable threefold increase in the sensing current of TRZ at a lower anodic oxidation potential (0.92 V) compared to the bare SPE. The Zn-MOF@CNF/SPE also exhibited a reduced charge transfer resistance of 61.9 Ω, elevated electrochemical active surface area of 0.416 cm2, and high heterogeneous electron transfer rate constant (k0) of 9.77×10−5 cm s−1. Furthermore, it displayed a broad linear range from 0.2 μM to 1000 μM with a remarkable sensitivity of 0.136 µAµM−1cm−2 and an impressive detection limit of 54 nM. Ultimately, the developed Zn-MOF@CNF/SPE sensor demonstrated excellent selectivity amidst various structurally similar overlapping species, outstanding repeatability, reproducibility, and stability in TRZ detection. The practical applicability of Zn-MOF@CNF/SPE was validated through 97 – 100.9 % recovery results in food samples such as jelly, ice cream, soft drinks, and candies. •The Zn-MOF@CNF composite was synthesized using the sonochemical method.•The fabricated Zn-MOF@CNF/SPE probe has a high sensitivity towards TRZ detection.•The Zn-MOF@CNF/SPE sensor possessed a wide linear range with a low detection limit.•The proposed sensor has excellent recovery results for detecting TRZ in food samples.
doi_str_mv 10.1016/j.jfca.2024.106462
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The practical applicability of Zn-MOF@CNF/SPE was validated through 97 – 100.9 % recovery results in food samples such as jelly, ice cream, soft drinks, and candies. •The Zn-MOF@CNF composite was synthesized using the sonochemical method.•The fabricated Zn-MOF@CNF/SPE probe has a high sensitivity towards TRZ detection.•The Zn-MOF@CNF/SPE sensor possessed a wide linear range with a low detection limit.•The proposed sensor has excellent recovery results for detecting TRZ in food samples.</abstract><pub>Elsevier Inc</pub><doi>10.1016/j.jfca.2024.106462</doi></addata></record>
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source Elsevier ScienceDirect Journals
subjects carbon
carbon nanofibers
detection limit
Electrochemical active surface area
electrochemistry
electrodes
electron transfer
food composition
ice cream
oxidation
pollutants
species
surface area
Synergistic interaction
tartrazine
Tartrazine detection
Zn-MOF@CNF composite
title Nanomolar detection of organic pollutant -tartrazine in food samples using zinc-metal organic framework/carbon nano fiber - composite modified screen-printed electrode
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