Development of label-free impedimetric platform based on new conductive polyaniline polymer and three-dimensional interdigitated electrode array for biosensor applications

Electrochimica Acta

Volumn 173, Issue , 2015, Pages 59-66

  Voitechovic E ^a   Bratov, A ^b   Abramova, N ^b,d   Razumiene, J ^c   Kirsanov, D ^a,d   Legin, A ^a,d   Lakshmi, D ^e   Piletsky, S ^f   Whitcombe, M ^f   Ivanova Mitseva, P K ^f  

^a ST PETERSBURG STATE UNIVERSITY   (Russian Federation)

^b INSTITUTO DE MICROELECTRÓNICA DE BARCELONA   (Spain)

^c VILNIUS UNIVERSITY   (Lithuania)

^d ITMO UNIVERSITY   (Russian Federation)

^e Sai Sarathy Limited   (United Kingdom)

^f UNIVERSITY OF LEICESTER   (United Kingdom)

Author keywords

biosensor; DET; Interdigitated electrode array; polyaniline; PQQ dependent enzyme

Indexed keywords

ANALYTIC EQUIPMENT; BIOSENSORS; CHEMICAL SENSORS; CHRONOAMPEROMETRY; COST EFFECTIVENESS; ELECTROCHEMICAL IMPEDANCE SPECTROSCOPY; ELECTRODES; ENZYMES; POLYANILINE; POLYMER FILMS; POLYMERS; REDOX REACTIONS; SEMICONDUCTING FILMS;

BIOSENSOR APPLICATIONS; CONDUCTING MATERIALS; CONDUCTIVE POLYANILINE; DET; DIRECT ELECTRON TRANSFER; ENZYME ACTIVE SITES; GLUCOSE DEHYDROGENASE; INTERDIGITATED ELECTRODE ARRAYS;

ENZYME ELECTRODES;

EID: 84929324355     PISSN: 00134686     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.electacta.2015.05.011     Document Type: Article

References (61)

1. P. Monk Fundamentals of Electroanalytical Chemistry 2007 John Wiley & Sons, Ltd.
2. A. Bratov, and N. Abramova Chemical sensors and biosensors based on impedimetric interdigitated electrode array transducers D.E. Suarez, Smart Sensor and Sensing Technology 2013 Nova Science Publisher Inc. New York 155 164
3. U. Lange, N.V. Roznyatovskaya, and V.M. Mirsky Conducting polymers in chemical sensors and arrays Anal. Chim. Acta 614 2008 1 26
4. O.A. Sadik, A.O. Aluoch, and A. Zhou Status of biomolecular recognition using electrochemical techniques Biosensors Bioelectron. 24 2009 2749 2765
5. B.Y. Chang, and S.M. Park Electrochemical impedance spectroscopy Annu. Rev. Anal. Chem. 2010 207 229
6. P.V. Bernhardt Enzyme electrochemistry - biocatalysis on an electrode Aust. J. Chem. 59 2006 233 256
7. Y. Li, L. Syed, J. Liu, D.H. Hua, and J. Li Label-free electrochemical impedance detection of kinase and phosphatase activities using carbon nanofiber nanoelectrode arrays Anal. Chim. Acta 744 2012 45 53
8. Y. Fu, Z. Callaway, J. Lum, R. Wang, J. Lin, and Y. Li Exploiting enzyme catalysis in ultra-low ion strength media for impedance biosensing of avian influenza virus using a bare interdigitated electrode Anal. Chem. 86 2014 1965 1971
9. A. Bratov, J. Ramon-Azcon, N. Abramova, A. Merlos, J. Adrian, F. Sanchez-Baeza, M.P. Marco, and C. Dominguez Three-dimensional interdigitated electrode array as a transducer for label-free biosensors Biosens. Bioelectron. 24 2008 729 735
10. A. Bratov, and N. Abramova Chemical sensors and biosensors based on impedimetric interdigitated electrode array transducers R.V. Harrison, Chemical Sensors: Properties, Performance and Applications 2010 Nova Science Publisher Inc. New York 91 115
11. B. Lindholm-Sethson, J. Nystrom, M. Malmsten, L. Ringstad, A. Nelson, and P. Geladi Electrochemical impedance spectroscopy in label-free biosensor applications: multivariate data analysis for an objective interpretation Anal. Bioanal. Chem. 398 2010 2341 2349
12. J.R. Macdonald Impedance spectroscopy Ann. Biomed. Eng. 20 1992 289 305
13. M. Riedel, J. Kartchemnik, M.J. Schöning, and F. Lisdat Impedimetric DNA detection-steps forward to sensorial application Anal. Chem. 86 2014 7867 7874
14. M. Shamsipur, M. Asgari, M.F. Mousavi, and R. Davarkhah A novel hydrogen peroxide sensor based on the direct electron transfer of catalase immobilized on nano-sized NiO/MWCNTs composite film Electroanalysis 24 2012 357 367
15. A. Guimerà, G. Gabriel, E. Prats-Alfonso, N. Abramova, A. Bratov, and R. Villa Effect of surface conductivity on the sensitivity of interdigitated impedimetric sensors and their design considerations Sensors Actuators B: Chem. 207 Part B 2015 1010 1018
16. C. Berggren, B. Bjarnason, and G. Johansson Capacitive Biosensors Electroanalysis 13 2001 173 180
17. A. Bratov, N. Abramova, J. Ramón-Azcón, A. Merlos, F. Sánchez-Baeza, M.P. Marco, and C. Domínguez Characterisation of the interdigitated electrode array with tantalum silicide electrodes separated by insulating barriers Electrochem. Commun. 10 2008 1621 1624
18. A. Bratov, N. Abramova, M.P. Marco, and F. Sanchez-Baeza Three-Dimensional Interdigitated Electrode Array as a Tool for Surface Reactions Registration Electroanalysis 24 2012 69 75
19. R.S. Freire, C.A. Pessoa, L.D. Mello, and L.T. Kubota Direct electron transfer: an approach for electrochemical biosensors with higher selectivity and sensitivity J. Braz. Chem. Soc. 14 2003 230 243
20. D. Nelson, and M. Cox Lehninger. Principles of biochemistry W.H. Freeman, 5 ed. 2009 Freeman New York
21. P. Bartlett Bioelectrochemistry Fundamentals, experimental techniques and applications 2008 John Wiley & Sons Chichester
22. D. Leech, P. Kavanagh, and W. Schuhmann Enzymatic fuel cells: recent progress Electrochim. Acta 84 2012 223 234
23. A. Galdikas, V. Bukauskas, S. Kaciulis, V. Laurinavicius, R. Meskys, A. Mezzi, A. Mironas, J. Razumiene, and A. Setkus Properties of the planar ADH-dry-layer structures based on electrically controlled coupling between enzyme molecules and metal surfaces Sensors Actuators B: Chem. 118 2006 60 66
24. S. Shleev, J. Tkac, A. Christenson, T. Ruzgas, A.I. Yaropolov, J.W. Whittaker, and L. Gorton Direct electron transfer between copper-containing proteins and electrodes Biosens. Bioelectron. 20 2005 2517 2554
25. P. Arora, A. Sindhu, N. Dilbaghi, and A. Chaudhury Biosensors as innovative tools for the detection of food borne pathogens Biosens. Bioelectron. 28 2011 1 12
26. K.E. Mach, P.K. Wong, and J.C. Liao Biosensor diagnosis of urinary tract infections: a path to better treatment? Trends Pharmacol. Sci. 32 2011 330 336
27. V. Flexer, F. Durand, S. Tsujimura, and N. Mano Efficient direct electron transfer of PQQ-glucose dehydrogenase on carbon cryogel electrodes at neutral pH Anal. Chem. 83 2011 5721 5727
28. J. Tkac, J. Svitel, I. Vostiar, M. Navratil, and P. Gemeiner Membrane-bound dehydrogenases from Gluconobacter sp.: Interfacial electrochemistry and direct bioelectrocatalysis Bioelectrochemistry 76 2009 53 62
29. B.L. Treu, R. Arechederra, and S.D. Minteer Bioelectrocatalysis of ethanol via PQQ-dependent dehydrogenases utilizing carbon nanomaterial supports J. Nanosci. Nanotechnol. 9 2009 2374 2380
30. T. Ikeda, D. Kobayashi, F. Matsushita, T. Sagara, and K. Niki Bioelectrocatalysis at electrodes coated with alcohol-dehydrogenase, a quinohemoprotein with heme-c serving as a built-in mediator J. Electroanal. Chem. 361 1993 221 228
31. V. Laurinavicius, J. Razumiene, B. Kurtinaitiene, I. Lapenaite, I. Bachmatova, L. Marcinkeviciene, R. Meskys, and A. Ramanavicius Bioelectrochemical application of some PQQ-dependent enzymes Bioelectrochemistry 55 2002 29 32
32. J. Razumiene, J. Barkauskas, V. Kubilius, R. Meskys, and V. Laurinavicius Modified graphitized carbon black as transducing material for reagentless H2O2 and enzyme sensors Talanta 67 2005 783 790
33. J. Razumiene, A. Vilkanauskyte, V. Gureviciene, J. Barkauskas, R. Meskys, and V. Laurinavicius Direct electron transfer between PQQ dependent glucose dehydrogenases and carbon electrodes: An approach for electrochemical biosensors Electrochim. Acta 51 2006 5150 5156
34. W. Schuhmann, H. Zimmermann, K.V. Habermuller, and V. Laurinavicius Electron-transfer pathways between redox enzymes and electrode surfaces: reagentless biosensors based on thiol-monolayer-bound and polypyrrole-entrapped enzymes Faraday Discuss. 116 2000 245 255
35. I.W. Schubart, G. Göbel, and F. Lisdat A pyrroloquinolinequinone-dependent glucose dehydrogenase (PQQ-GDH)-electrode with direct electron transfer based on polyaniline modified carbon nanotubes for biofuel cell application Electrochim. Acta 82 2012 224 232
36. P.K. Ivanova-Mitseva, V. Fragkou, D. Lakshmi, M.J. Whitcombe, F. Davis, A. Guerreiro, J.A. Crayston, D.K. Ivanova, P.A. Mitsev, E.V. Piletska, and S.A. Piletsky Conjugated polymers with pendant iniferter units: versatile materials for grafting Macromolecules 44 2011 1856 1865
37. S. Nambiar, and J.T.W. Yeow Conductive polymer-based sensors for biomedical applications Biosens. Bioelectron. 26 2011 1825 1832
38. S. Ameen, M.S. Akhtar, and M. Husain Polyaniline and its nanocomposites: synthesis, processing, electrical properties and applications Sci. Adv. Mater. 2 2010 441 462
39. P. Novak, K. Muller, K.S.V. Santhanam, and O. Haas Electrochemically active polymers for rechargeable batteries Chem. Rev. 97 1997 207 281
40. K. Grennan, A.J. Killard, C.J. Hanson, A.A. Cafolla, and M.R. Smyth Optimisation and characterisation of biosensors based on polyaniline Talanta 68 2006 1591 1600
41. W. Wongsan, W. Aeungmaitrepirom, O. Chailapakul, W. Ngeontae, and T. Tuntulani Bifunctional polymeric membrane ion selective electrodes usingphenylboronic acid as a precursor of anionic sites and fluoride as aneffector: A potentiometric sensor for sodium ion and an impedimetricsensor for fluoride ion Electrochim. Acta 111 2013 234 241
42. J. Janata, and M. Josowicz Conducting polymers in electronic chemical sensors Nat. Mater. 2 2003 19 24
43. G.P. Kittlesen, H.S. White, and M.S. Wrighton Chemical derivatization of microelectrode arrays by oxidation of pyrrole and N-methylpyrrole: fabrication of molecule-based electronic devices J. Am. Chem. Soc. 106 1984 7389 7396
44. E.W. Paul, A.J. Ricco, and M.S. Wrighton Resistance of polyaniline films as a function of electrochemical potential and the fabrication of polyaniline-based microelectronic devices J. Phys. Chem. 89 1985 1441 1447
45. J.W. Thackeray, and M.S. Wrighton Chemically responsive microelectrochemical devices based on platinized poly(3-methylthiophene): variation in conductivity with variation in hydrogen oxygen, or pH in aqueous solution J. Phys. Chem. 90 1986 6674 6679
46. D.T. Hoa, T.N.S. Kumar, N.S. Punekar, R.S. Srinivasa, R. Lal, and A.Q. Contractor Biosensor based on conducting polymers Anal. Chem. 64 1992 2645 2646
47. H. Sangodkar, S. Sukeerthi, R.S. Srinivasa, R. Lal, and A.Q. Contractor A biosensor array based on polyaniline Anal. Chem. 68 1996 779 783
48. N.G. Skinner, and E.A.H. Hall Investigation of the origin of the glucose response in a glucose oxidase vertical bar polyaniline system J. Electroanal. Chem. 420 1997 179 188
49. D. Lakshmi, M.J. Whitcombe, F. Davis, I. Chianella, E.V. Piletska, A. Guerreiro, S. Subrahmanyam, P.S. Brito, S.A. Fowler, and S.A. Piletsky Chimeric polymers formed from a monomer capable of free radical, oxidative and electrochemical polymerisation Chem. Commun. 0 2009 2759 2761
50. D. Lakshmi, A. Bossi, M.J. Whitcombe, I. Chianella, S.A. Fowler, S. Subrahmanyam, E.V. Piletska, and S.A. Piletsky Electrochemical sensor for catechol and dopamine based on a catalytic molecularly imprinted polymer-conducting polymer hybrid recognition element Anal. Chem. 81 2009 3576 3584
51. L. Marcinkeviciene, I. Bachmatova, R. Semenaite, R. Rudomanskis, G. Brazenas, R. Meskiene, and R. Meskys Purification and characterisation of alcohol dehydrogenase from Gluconobacter sp. 33 Biologija 2 1999 6
52. H. Toyama, Z.W. Chen, M. Fukumoto, O. Adachi, K. Matsushita, and F.S. Mathews Molecular cloning and structural analysis of quinohemoprotein alcohol dehydrogenase ADH-IIG from Pseudomonas putida HK5 J. Mol. Biol. 352 2005 91 104
53. P. Dokter, J.T. Pronk, B.J. van Schie, J.P. van Dijken, and J.A. Duine The in vivo and in vitro substrate specificity of quinoprotein glucose dehydrogenase of Acinetobacter calcoaceticus LMD79.41 FEMS Microbiol. Lett. 43 1987 195 200
54. A. Malinauskas, and R. Holze An in situ spectroelectrochemical study of redox reactions at polyaniline-modified ITO electrodes Electrochim. Acta 43 1998 2563 2575
55. Z. Mandić, and L. Duić Polyaniline as an electrocatalytic material J. Electroanal. Chem. 403 1996 133 141
56. L. Marcinkeviciene, J. Stankeviciute, I. Bachmatova, R. Vidziunaite, A. Chaleckaja, and R. Meskys Biocatalytic properties of quinohemoprotein alcohol dehydrogenase IIG from Pseudomonas putida HK5 Chemija 23 2012 223 232
57. V.L. Davidson Electron transfer in quinoproteins Arch. Biochem. Biophys. 428 2004 32 40
58. A. Oubrie Structure and mechanism of soluble glucose dehydrogenase and other PQQ-dependent enzymes BBA-Proteins Proteomics 1647 2003 143 151
59. A. Malinauskas Self-doped polyanilines J. Power Sources 126 2004 214 220
60. E.A. Andreyev, M.A. Komkova, V.N. Nikitina, N.V. Zaryanov, O.G. Voronin, E.E. Karyakina, A.K. Yatsimirsky, and A.A. Karyakin Reagentless Polyol Detection by Conductivity Increase in the Course of Self-Doping of Boronate-Substituted Polyaniline Anal. Chem. 86 2014 11690 11695
61. A. Setkus, A. Galdikas, V. Laurinavicius, R. Meskys, A. Mironas, and J. Razumiene Electric charge transport in the symmetric metal-enzyme junctions affected by biochemical interaction Colloids Surf. Physicochem. Eng. Aspects 249 2004 141 143