Use of sinusoidal voltages with fixed frequency in the preparation of tyrosinase based electrochemical biosensors for dopamine electroanalysis

Use of sinusoidal voltages with fixed frequency in the preparation of tyrosinase based electrochemical biosensors for dopamine electroanalysis

•Electrochemical biosensors were prepared using sinusoidal voltages of selected frequency.•The beneficial effect of the sinusoidal voltages on biosensors preparation has been demonstrated.•The biosensor was successfully applied to dopamine electroanalysis in pharmaceutical products. Sinusoidal volta...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Vol. 240; no. 240; pp. 801 - 809
Main Authors: Lete, Cecilia, Lakard, Boris, Hihn, Jean-Yves, del Campo, Francisco Javier, Lupu, Stelian
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 01-03-2017
Elsevier Science Ltd
Elsevier
Subjects:
Arrays
Biomedical materials
Biosensors
Chemical Sciences
Conducting polymers
Devices
Dopamine
Electric potential
Electrochemical biosensor
Electrodes
Electrolytic analysis
Gold
Hydroquinone
Infrared reflection
Microelectrode arrays
Microelectrodes
Morphology
Organic chemistry
Polymer matrix composites
Polymerization
Polymers
Porosity
Repeatability
Reproducibility
Scanning electron microscopy
Sensitivity analysis
Silver chloride
Sinusoidal voltages
Stability analysis
Tyrosinase
Hydroquinone
Sinusoidal voltages
Electrochemical biosensor
Dopamine
Microelectrode arrays
Tyrosinase
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Summary:•Electrochemical biosensors were prepared using sinusoidal voltages of selected frequency.•The beneficial effect of the sinusoidal voltages on biosensors preparation has been demonstrated.•The biosensor was successfully applied to dopamine electroanalysis in pharmaceutical products. Sinusoidal voltages (SV) of fixed frequency were used in the preparation of electrochemical biosensors based on gold (Au) disk microelectrode arrays (MEAs) modified with a bio-composite material consisting of poly(3,4-ethylenedioxythiophene) conducting polymer (PEDOT) and tyrosinase (Tyr). The SV was applied over a d.c. potential of 0.60V vs. Ag/AgCl/KCl (3M) in order to assess the contribution of the sinusoidal signal to the electrochemical polymerization of the monomer. The use of SV with fixed frequency ensured the preparation of bio-composite materials with given properties. A high porosity is expected, as the Tyr enzyme is entrapped within the polymeric layer by electrostatic interactions during the electrochemical polymerization process. The morphology and the chemical nature of the prepared coatings were studied by scanning electron microscopy, optical profilometry, and infrared reflection absorption spectroscopy. The MEA devices present two independent arrays separated by an insulating gap. One electrode from the device was modified by a PEDOT-Tyr layer, while the second electrode was modified with a PEDOT layer. The analytical determination of dopamine and hydroquinone was carried out via bipotentiostatic measurements by simultaneous polarization of both PEDOT-Tyr and PEDOT modified electrodes from one device using cyclic voltammetry. The analytical performance in terms of linear range, detection and quantification limits, sensitivity, repeatability, re-usability and operational stability, have been assessed. The PEDOT-Tyr based biosensor, prepared at 0.60V d.c. potential value and SV signal with 50mHz frequency and ±350mV amplitude, exhibited a low detection limit of 2.4×10−7M dopamine, an excellent repeatability of 4.1%, and a recovery of 100.2% were achieved for dopamine determination. The proposed biosensor was also successfully applied in dopamine electroanalysis in pharmaceutical products.
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ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2016.09.045