Modifications of poly(o-phenylenediamine) permselective layer on Pt-Ir for biosensor application in neurochemical monitoring
Academic Article
Publication Date:
2007
Short description:
Modifications of poly(o-phenylenediamine) permselective layer on Pt-Ir for biosensor application in neurochemical monitoring / Rocchitta, Gaia Giovanna Maria; Serra, Pier Andrea; Kirwan, Sarah M.; Craig, Jennifer D.; Killoran, Sarah J.; Lowry, John P.; O’Neill, Robert D.; Mcmahon, Colm P.; O’Brien, Kylie B.. - In: SENSORS. - ISSN 1424-8220. - 7:4(2007), pp. 420-437. [10.3390/s7040420]
abstract:
Reports that globular proteins could enhance the interference blocking ability of
the PPD (poly(o-phenylenediamine) layer used as a permselective barrier in biosensor
design, prompted this study where a variety of modifying agents were incorporated into PPD during its electrosynthesis on Pt-Ir electrodes. Trapped molecules, including fibrous proteins and β-cyclodextrin, altered the polymer/modifier composite selectivity by affecting the sensitivity to both H2O2(signal molecule in many enzyme-based biosensors) and the archetypal interference species, ascorbic acid. A comparison of electrochemical properties of Pt and a Pt-Ir alloy suggests that the benefits of the latter, more rigid, metal can be exploited in PPD-based biosensor design without significant loss of backward compatibility with studies involving pure Pt.
the PPD (poly(o-phenylenediamine) layer used as a permselective barrier in biosensor
design, prompted this study where a variety of modifying agents were incorporated into PPD during its electrosynthesis on Pt-Ir electrodes. Trapped molecules, including fibrous proteins and β-cyclodextrin, altered the polymer/modifier composite selectivity by affecting the sensitivity to both H2O2(signal molecule in many enzyme-based biosensors) and the archetypal interference species, ascorbic acid. A comparison of electrochemical properties of Pt and a Pt-Ir alloy suggests that the benefits of the latter, more rigid, metal can be exploited in PPD-based biosensor design without significant loss of backward compatibility with studies involving pure Pt.
Iris type:
1.1 Articolo in rivista
Keywords:
Platinum-iridium electrodes; polymer electrosynthesis; cyclic voltammetry; amperometry; proteins; cyclodextrins; ascorbate; hydrogen peroxide; brain analysis
List of contributors:
Rocchitta, Gaia Giovanna Maria; Serra, Pier Andrea; Kirwan, Sarah M.; Craig, Jennifer D.; Killoran, Sarah J.; Lowry, John P.; O’Neill, Robert D.; Mcmahon, Colm P.; O’Brien, Kylie B.
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