Highly selective electrochemical detection of serotonin on polypyrrole and gold nanoparticles-based 3D architecture

Electrochemistry Communications

Volumn 75, Issue , 2017, Pages 43-47

  Tertiș, Mihaela ^a   Cernat, Andreea ^a   Lacatiș, Daniela ^a   Florea, Anca ^a   Bogdan, Diana ^b   Suciu, Maria ^b   Săndulescu, Robert ^a   Cristea, Cecilia ^a  

^a IULIU HATIEGANU UNIVERSITY OF MEDICINE AND PHARMACY   (Romania)

^b NATIONAL INSTITUTE FOR RESEARCH AND DEVELOPMENT OF ISOTOPIC AND MOLECULAR TECHNOLOGIES   (Romania)

Author keywords

Electropolymerization; Gold nanoparticles; Polypyrrole; Serotonin

Indexed keywords

ELECTROPOLYMERIZATION; FIBER OPTIC SENSORS; GOLD; METAL NANOPARTICLES; NANOPARTICLES; NANOSTRUCTURES; POLYPYRROLES; PRECIOUS METALS;

ACTIVE SURFACE AREA; ANALYTICAL PERFORMANCE; CATALYTIC EFFECTS; COMPOSITE SURFACE; ELECTROCHEMICAL DETECTION; GOLD NANOPARTICLES; INTERFERING SPECIES; SEROTONIN;

CHEMICAL DETECTION;

EID: 85007413329     PISSN: 13882481     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.elecom.2016.12.015     Document Type: Article

References (37)

1. [1] Shiigi, H., Okamura, K., Kijima, D., Deore, B., Sree, U., Nagaoka, T., An overoxidized polypyrrole/dodecylsulfonate micelle composite film for amperometric serotonin sensing. J. Electrochem. Soc. 150:5 (2003), H119–H123.
2. [2] Cesarino, I., Galesco, H.V., Machado, S.A.S., Determination of serotonin on platinum electrode modified with carbon nanotubes/polypyrrole/silver nanoparticles nanohybrid. Mater. Sci. Eng. C 40 (2014), 49–54.
3. 2 nanoparticles-carbon nanotube composite modified glassy carbon electrode as a sensor for simultaneous determination of dopamine and serotonin in the presence of ascorbic acid. Sensors Actuators B 176 (2013), 543–551.
4. [4] Özcan, A., Ilkbaş, S., Poly(pyrrole-3-carboxylic acid)-modified pencil graphite electrode for the determination of serotonin in biological samples by adsorptive stripping voltammetry. Sensors Actuators B 215 (2015), 518–524.
5. [5] Sun, C.L., Lee, H.H., Yang, J.M., Wu, C.C., The simultaneous electrochemical detection of ascorbic acid, dopamine, and uric acid using graphene/size-selected Pt nanocomposites. Biosens. Bioelectron. 26 (2011), 3450–3455.
6. [6] Li, J., Lin, X., Simultaneous determination of dopamine and serotonin on gold nanocluster/overoxidized-polypyrrole composite modified glassy carbon electrode. Sensors Actuators B 124 (2007), 486–493.
7. [7] Wang, F., Wu, Y., Lu, K., Ye, B., A simple but highly sensitive and selective calixarene-based voltammetric sensor for serotonin. Electrochim. Acta 87 (2013), 756–762.
8. [8] Xue, C., Wang, X., Zhu, W., Han, Q., Zhu, C., Hong, J., Zhou, X., Jiang, H., Electrochemical serotonin sensing interface based on double-layered membrane of reduced graphene oxide/polyaniline nanocomposites and molecularly imprinted polymers embedded with gold nanoparticles. Sensors Actuators B 196 (2014), 57–63.
9. [9] Song, M.-J., Kim, S., Min, N.K., Jin, J.-H., Electrochemical serotonin monitoring of poly(ethylenedioxythiophene): poly(sodium 4-styrenesulfonate)-modified fluorine-doped tin oxide by predeposition of self-assembled 4-pyridylporphyrin. Biosens. Bioelectron. 52 (2014), 411–416.
10. [10] Yao, H., Li, S., Tang, Y., Chen, Y., Chen, Y., Lin, X., Selective oxidation of serotonin and norepinephrine over eriochrome cyanine R film modified glassy carbon electrode. Electrochim. Acta 54 (2009), 4607–4612.
11. [11] Choudhary, M., Siwal, S., Nandi, D., Mallick, K., Single step synthesis of gold-amino acid composite, with the evidence of the catalytic hydrogen atom transfer (HAT) reaction, for the electrochemical recognition of serotonin. Phys. E. 77 (2016), 72–80.
12. [12] Mazloum-Ardakani, M., Khoshroo, A., High sensitive sensor based on functionalized carbon nanotube/ionic liquid nanocomposite for simultaneous determination of norepinephrine and serotonin. J. Electroanal. Chem. 717–718 (2014), 17–23.
13. [13] Ejaz, A., Joo, Y., Jeon, S., Fabrication of 1,4-bis(aminomethyl)benzene and cobalt hydroxide @ graphene oxide for selective detection of dopamine in the presence of ascorbic acid and serotonin. Sensors Actuators B 240 (2017), 297–307.
14. [14] Abbaspour, A., Noori, A., A cyclodextrin host-guest recognition approach to an electrochemical sensor for simultaneous quantification of serotonin and dopamine. Biosens. Bioelectron. 26:12 (2011), 4674–4680.
15. [15] Cesarino, I., Galesco, H.V., Moraes, F.C., Lanza, M.R.V., Machado, S.A.S., Biosensor based on electrocodeposition of carbon nanotubes/polypyrrole/laccase for neurotransmitter detection. Electroanalysis 25 (2013), 394–400.
16. [16] Ramanavicius, A., Rekertaité, A.I., Valiünas, R., Valiüniené, A., Single-step procedure for the modification of graphite electrode by composite layer based on polypyrrole, Prussian blue and glucose oxidase. Sensors Actuators B 240 (2017), 220–223.
17. [17] Garcia-Cruz, A., Zine, N., Sigaud, M., Lee, M., Marote, P., Lanteri, P., Bausells, J., Errachid, A., Controlled poly(pyrrole) patterning by microcontact printing on glass and poly(ethylene terephthalate) substrates. Microelectron. Eng. 121 (2014), 167–174.
18. [18] Yang, Y., Qi, S., Wang, J., Preparation and microwave absorbing properties of nickel-coated graphite nanosheet with pyrrole via in situ polymerization. J. Alloys Compd. 520 (2012), 114–121.
19. [19] Lu, J.-J., Ma, J.-Q., Yi, J.-M., Shen, Z.-L., Zhong, Y.-J., Mab, C.-A., Lia, M.-C., Electrochemical polymerization of pyrrole containing TEMPO side chain on Pt electrode and its electrochemical activity. Electrochim. Acta 130 (2014), 412–417.
20. [20] Fritea, L., Le Goff, A., Putaux, J.-L., Tertis, M., Cristea, C., Săndulescu, R., Cosnier, S., Design of a reduced-graphene-oxide composite electrode from an electropolymerizable graphene aqueous dispersion using a cyclodextrin-pyrrole monomer. Application to dopamine biosensing. Electrochim. Acta 178 (2015), 108–112.
21. [21] Fritea, L., Gorgy, K., Le Goff, A., Audebert, P., Galmiche, L., Săndulescu, R., Cosnier, S., Fluorescent and redox tetrazine films by host-guest immobilization of tetrazine derivatives within poly(pyrrole-β-cyclodextrin) films. J. Electroanal. Chem., 2016, 10.1016/j.jelechem.2016.07.010.
22. [22] Cernat, A., Bodoki, E., Farcau, C., Astilean, S., Griveau, S., Bedioui, F., Săndulescu, R., Surface modeling of nanopatterned polymer films obtained by colloidal templated electropolymerization. J. Nanosci. Nanotechnol. 15 (2015), 3359–3364.
23. [23] Cernat, A., Tertiș, M., Păpară, C.N., Bodoki, E., Săndulescu, R., Nanostructured platform based on graphene-polypyrrole composite for immunosensor fabrication. Int. J. Electrochem. Sci. 10 (2015), 4718–4731.
24. [24] Cernat, A., Le Goff, A., Holzinger, M., Săndulescu, R., Cosnier, S., Micro- to nanostructured poly(pyrrole-nitrilotriacetic acid) films via nanosphere templates: applications to 3D enzyme attachment by affinity interactions. Anal. Bioanal. Chem. 406 (2014), 1141–1147.
25. [25] Cernat, A., Griveau, S., Martin, P., Lacroix, J.C., Farcau, C., Săndulescu, R., Bedioui, F., Electrografted nanostructured platforms for click chemistry. Electrochem. Commun. 23 (2012), 141–144.
26. [26] Fritea, L., Haddache, F., Reuillard, B., Le Goff, A., Gorgy, K., Gondran, C., Holzinger, M., Săndulescu, R., Cosnier, S., Electrochemical nanopatterning of an electrogenerated photosensitive poly-[trisbipyridinyl-pyrrole ruthenium(II)] metallopolymer bynanosphere lithography. Electrochem. Commun. 46 (2014), 75–78.
27. [27] Besombes, J.L., Cosnier, S., Labbé, P., Improvement of poly(amphiphilicpyrrole) enzyme electrodes via the incorporation of synthetic laponite-clay-nanoparticles. Talanta 44 (1997), 2209–2215.
28. [28] Holzinger, M., Le Goff, A., Cosnier, S., Nanomaterials for biosensing applications: a review. Front. Chem., 2, 2014, 63.
29. [29] Plausinaitis, D., Ratautaite, V., Mikoliunaite, L., Sinkevicius, L., Ramanaviciene, A., Ramanavicius, A., Quartz crystal microbalance-based evaluation of the electrochemical formation of an aggregated polypyrrole particle-based layer. Langmuir 31:10 (2015), 3186–3193.
30. [30] Ansari Khalkhali, R., Price, W.E., Wallace, G.G., Quartz crystal microbalance studies of the effect of solution temperature on the ion-exchange properties of polypyrrole (PPY) conducting electroactive polymers. React. Funct. Polym. 56 (2003), 141–146.
31. [31] Munusamy, S., Giribabu, K., Manigandan, R., Muthamizh, S., Vijayalakshmi, L., Narayanan, V., Synthesis, characterization and electrochemical property of polypyrrole nanoparticles. Chem. Sci. Trans. 2 (2013), S71–S74, 10.7598/cst2013.16.
32. [32] Nagy, P.I., Takács-Novák, K., Tautomeric and conformational equilibria of biologically important (hydroxyphenyl)alkylamine in the gas phase and in aqueous solution. Phys. Chem. Chem. Phys. 6 (2004), 2838–2848.
33. [33] Cabezas, C., Pena, I., Lopez, J.C., Alonso, J.L., Seven conformers of neutral dopamine revealed in the gas phase. J. Phys. Chem. Lett. 4 (2013), 486–490.
34. [34] Urban, J.J., Cramer, C.J., Famini, G.R., A computational study of solvent effects on the conformation of dopamine. J. Am. Chem. Soc. 114 (1992), 8226–8231.
35. [35] Nagy, P.I., Competing intramolecular vs. intermolecular hydrogen bonds in solution. Int. J. Mol. Sci. 15 (2014), 19562–19633.
36. [36] Ribeiro, J.A., Fernandes, P.M.V., Pereira, C.M., Silva, F., Electrochemical sensors and biosensors for determination of catecholamine neurotransmitters: a review. Talanta 160 (2016), 653–679.
37. [37] Gomez, F.J.V., Martín, A., Silva, M.F., Escarpa, A., Screen-printed electrodes modified with carbon nanotubes or graphene for simultaneous determination of melatonin and serotonin. Microchim. Acta 182:11 (2015), 1925–1931.