PVA-AWP/tyrosinase functionalized screen-printed electrodes for dopamine determinationElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ay01395c

The development of highly sensitive amperometric biosensors for dopamine determination using commercially available SPEs in combination with the PVA-AWP photopolymer as the enzyme immobilization matrix is described in this work. This research focuses on (i) the optimization of the conditions for SPE...

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Main Authors Stoytcheva, M, Zlatev, R, Gonzalez Navarro, F. F, Velkova, Z, Gochev, V, Montero, G, Ayala Bautista, A. G, Toscano-Palomar, L
Format Journal Article
Published 30.06.2016
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Summary:The development of highly sensitive amperometric biosensors for dopamine determination using commercially available SPEs in combination with the PVA-AWP photopolymer as the enzyme immobilization matrix is described in this work. This research focuses on (i) the optimization of the conditions for SPE biofunctionalization by tyrosinase entrapment in PVA-AWP and of the working conditions for dopamine determination by mathematical model application, and (ii) the evaluation of the analytical performances of the PVA-AWP/tyrosinase functionalized SPEs. Dopamine determination under optimum conditions for electrode biofunctionalization (PVA-AWP 3%, 60 min UV light exposure) and under optimum working conditions (pH 6.5, 25 °C) was performed in the dynamic concentration range of 0.9-500 μmol L −1 , 0.2-400 μmol L −1 , and 0.03-150 μmol L −1 , using respectively C SPE, MWCNT-GNP/C SPE, and graphene-GNP/C SPE. The LOD was found to be 300 nmol L −1 , 60 nmol L −1 , and as low as 10 nmol L −1 , correspondingly. The excellent analytical performances of the graphene-GNP C SPE and MWCNT-GNP C SPE were associated with their large active area (19.72 mm 2 and 15.3 mm 2 ) and enhanced electrocatalytic properties ( k o = 8.1 × 10 −3 cm s −1 and 4.4 × 10 −3 cm s −1 ) compared with the bare C SPE (12.47 mm 2 and k o = 3.0 × 10 −3 cm s −1 ). The developed biosensors were stable, reproducible, and more sensitive than most of the known biosensors for dopamine determination. They were successfully applied for dopamine determination in injections. Taking into consideration the fact that the selected enzyme immobilization approach using a water-soluble photopolymer opens the possibility of SPE biofunctionalization by photolithography, the developed biosensors are promising for fast, simple, sensitive, selective, and cost effective analysis of dopamine. Highly sensitive biosensors for dopamine determination were developed using commercially available SPEs in combination with the PVA-AWP photopolymer as the enzyme immobilization matrix.
Bibliography:10.1039/c6ay01395c
Electronic supplementary information (ESI) available. See DOI
ISSN:1759-9660
1759-9679
DOI:10.1039/c6ay01395c