Amperometric detection of triclosan with screen-printed carbon nanotube electrodes modified with Guinea Grass (Panicum maximum) peroxidase

Angie E. Orduz, Jorge A. Gutiérrez, Sergio I. Blanco, John J. Castillo

Research output: Articles / NotesScientific Articlepeer-review

5 Scopus citations

Abstract

Triclosan is a compound with antimicrobial activity broadly used in consumer products. Because of its well-documented toxicity, the amount of triclosan present in different products needs to be tightly controlled. This paper outlines a new amperometric sensor for triclosan detection consisting of a screen-printed carbon nanotube electrode (SPCNE) modified with Guinea grass peroxidase (GGP). The GGP-modified SPCNE was able to detect an enhanced electrochemical response of triclosan, unlike the bare SPCNE. The cyclic voltammograms of theGGP-modified SPCNE in a solution of potassium ferrocyanide showed an increase in the current values and linearity between scan rates and oxidation peak currents, suggesting a surface-controlled process. The GGP-modified SPCNE showed an excellent electrocatalytic activity to triclosan oxidation, at a redox potential of 370 mV, in the presence of hydrogen peroxide, exhibiting a linear response between 20mMto 80mMand a detection limit of 3 μM. This new amperometry system, based on carbon nanotubes integrated with GGP, becomes a potential tool for environmental analysis and food quality control.

Translated title of the contributionDetección amperométrica de triclosan con electrodos de nanotubos de carbono impresos en pantalla modificados con peroxidasa de Pasto Guinea (Panicum maximum)
Original languageEnglish
Pages (from-to)363-379
Number of pages17
JournalUniversitas Scientiarum
Volume24
Issue number2
DOIs
StatePublished - 2019
Externally publishedYes

Keywords

  • Amperometric biosensor
  • Carbon nanotubes
  • Guinea grass peroxidase
  • Screen printed electrodes
  • Triclosan

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