A Glucose Biosensor Employing a Stable Artificial Peroxidase Based on Ruthenium Purple Anchored Cinder

Zen, Jyh‐Myng; Kumar, Annamalai Senthil; Chung, Ching-Rue

doi:10.1021/ac020542u

Cited by 48 publications

(29 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is in contrast with our observations at neutral pH, where spectrophotometric analysis of the mixed-metal deposition solution revealed an absorption maximum at 670 nm, in comparison with 420 nm and 500 nm for the FeHCF and RuHCF modification solutions, respectively, indicating that the mixed-metal complex already exists in the modification solution. It is assumed that under the experimental conditions employed in this work, the simultaneous deposition of both cations and [Fe(CN) 6 ] 3À from the same solution precluded the formation of ruthenium-oxo species, which were found in several ruthenium-stabilized metal hexacyanoferrate films [33]. However, similar to observations described by Cataldis group [21,32,33], the ruthenium containing mixed-metal hexacyanoferrate film in our study exhibited increased stability when compared with mono-cationic FeHCF or RuHCF analogues.…”

Section: Deposition and Stability Study Of The Feruhcf Filmsupporting

confidence: 84%

“…The current increase is attributed to changes in the FeRuHCF film structure, possibly together with an increase in the film lattice spaces allowing H 2 O 2 to penetrate more easily into the film. However, reduction of Fe(CN) 6 3À to Fe(CN) 6…”

Section: Characteristic and Response Of The Feruhcf Microsensor To H mentioning

confidence: 99%

“…However, the mixed FeRuHCF film was composed of small crystals which covered the entire electrode surface, although different thicknesses of the film were observed while prepared under identical conditions. Cataldi et al describe the formation of an oxo-bridge between ruthenium cation and cyano group deposited from an acidic solution containing RuCl 3 and K 3 Fe(CN) 6 in the molar ratio of 1 : 1 [32]. This is in contrast with our observations at neutral pH, where spectrophotometric analysis of the mixed-metal deposition solution revealed an absorption maximum at 670 nm, in comparison with 420 nm and 500 nm for the FeHCF and RuHCF modification solutions, respectively, indicating that the mixed-metal complex already exists in the modification solution.…”

Section: Deposition and Stability Study Of The Feruhcf Filmmentioning

confidence: 99%

“…It is also a by-product of many biological oxidative reactions, e.g., glucose oxidase/glucose [5] and other oxidases, and is therefore an important parameter for monitoring biological processes. In particular, when meeting high demands addressing strict diabetes control, substantial research efforts have been focused toward development of reliable glucose sensors based on the electrochemical detection of hydrogen peroxide, which is formed during enzyme-catalyzed oxidation of glucose by dissolved oxygen [6,7]. Various, and particularly biomedical applications such as continuous in-vivo monitoring of hydrogen peroxide (and hence glucose) with, for example, implantable or needle-like sensors [8,9] and measurements in different microenvironments, e.g., plant cells [10], dictate the miniaturization of electrochemical sensors down to micro and submicrometer design.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Novel Electrochemical Microsensor for Hydrogen Peroxide based on Iron‐Ruthenium Hexacyanoferrate Modified Carbon Fiber Electrode

Pauliukaitė¹,

Hočevar

Hutton

et al. 2007

Electroanalysis

View full text Add to dashboard Cite

Novel electrochemical microsensor based on mixed iron-ruthenium hexacyanoferrate (FeRuHCF) modified carbon fiber microelectrode (CFME) is presented for voltammetric and amperometric measurement of hydrogen peroxide at physiological pH. The FeRuHCF coating was electrochemically deposited using a one step procedure onto the substrate carbon fiber microelectrode by cycling the potential between 0.0 and þ 1.0 V (vs. Ag/AgCl) in a solution containing all precursor salts. The microsensor displayed good stability in neutral and alkaline media and had a nonstop working lifetime of up to 12 hours. The amperometric response time varied from 5 to 15 s depending on the hydrogen peroxide concentration level. The newly developed electrochemical microsensor exhibited a highly linear behavior in the examined concentration range from 5 to 1000 mmol, and a favorable reproducibility with a calculated RSD of 2.9% (n ¼ 6) for 100 mmol L À1 hydrogen peroxide, thus holding great promise for its further application in real samples and its exploitation in combination with biorecognition elements in advanced microbiosensor design.

show abstract

Section: Deposition and Stability Study Of The Feruhcf Filmsupporting

confidence: 84%

Section: Characteristic and Response Of The Feruhcf Microsensor To H mentioning

confidence: 99%

Section: Deposition and Stability Study Of The Feruhcf Filmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Novel Electrochemical Microsensor for Hydrogen Peroxide based on Iron‐Ruthenium Hexacyanoferrate Modified Carbon Fiber Electrode

Pauliukaitė¹,

Hočevar

Hutton

et al. 2007

Electroanalysis

View full text Add to dashboard Cite

show abstract

“…When glucose levels in the bloodstream are not properly regulated, diseases such as diabetes can develop. Because of the high demand for blood-glucose monitoring, significant research has been devoted to producing reliable methods for in vitro or in vivo glucose measurement, such as fluorescence spectroscopy (Ballerstadt and Schultz, 2000), diffraction spectroscopy (Asher et al, 2003), surface-enhanced Raman scattering (Shafer et al, 2003), a wireless magnetoelastic sensor (Cai et al, 2004), an electrochemical transistor sensor (Forzani et al, 2004;Raffa et al, 2003), an enzyme-based amperometric sensor (Zen et al, 2003;Hrapovic et al, 2004;Lin et al, 2004;Yang et al, 2004;Zhou et al, 2005), a nanoenzymetric amperometric sensor (Park et al, 2003), nuclear magnetic resonance spectroscopy (Cline et al, 1998) and a potentiometric sensor (Shoji et al, 2001). Since the development of the first glucose biosensor, improvement of the response performance of enzyme electrodes has been the main focus of biosensor research (Raitman et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

Functionalised ZnO-nanorod-based selective electrochemical sensor for intracellular glucose

Asif

Ali

Nur

et al. 2010

Biosensors and Bioelectronics

128

View full text Add to dashboard Cite

In this article, we report a functionalised ZnO-nanorod-based selective electrochemical sensor for intracellular glucose. To adjust the sensor for intracellular glucose measurements, we grew hexagonal ZnO nanorods on the tip of a silver-covered borosilicate glass capillary (0.7 µm diameter) and coated them with the enzyme glucose oxidase. The enzyme-coated ZnO nanorods exhibited a glucose-dependent electrochemical potential difference versus an Ag/AgCl reference micro-electrode. The potential difference was linear over the concentration range of interest (0.5 µM -1000 µM). The measured glucose concentration in human adipocytes or frog oocytes using our ZnO nanorod sensor was consistent with values of glucose concentration reported in the literature; furthermore, the sensor was able to show that insulin increased the intracellular glucose concentration. This nanoelectrode device demonstrates a simple technique to measure intracellular glucose concentration.

show abstract

A Three‐Dimensional Gold‐Decorated Nanoporous Copper Core–Shell Composite for Electrocatalysis and Nonenzymatic Biosensing

Chen

Fujita

Ding

et al. 2010

Adv Funct Materials

161

View full text Add to dashboard Cite

Bimetallic core–shell nanostructures have attracted increasing attention due to their low material costs along with enhanced chemico‐physical properties in comparison with their monometallic counterparts. Here, a novel gold‐decorated nanoporous copper (Au@NPC) core–shell composite fabricated by a facile in situ hydrometallurgy approach is reported. Thin gold shells with a controllable thickness are homogeneously deposited onto the internal surfaces of 3D nanoporous copper via a spontaneous displacement reaction while nanoporous copper is utilized as a reduction agent as well as 3D template and substrate. The resulting inexpensive core–shell nanostructure exhibits significant electrocatalytic activity for the oxidation of methanol and high non‐enzymatic sensitivity in detecting glucose.

show abstract

A Glucose Biosensor Employing a Stable Artificial Peroxidase Based on Ruthenium Purple Anchored Cinder

Cited by 48 publications

References 34 publications

Novel Electrochemical Microsensor for Hydrogen Peroxide based on Iron‐Ruthenium Hexacyanoferrate Modified Carbon Fiber Electrode

Novel Electrochemical Microsensor for Hydrogen Peroxide based on Iron‐Ruthenium Hexacyanoferrate Modified Carbon Fiber Electrode

Functionalised ZnO-nanorod-based selective electrochemical sensor for intracellular glucose

A Three‐Dimensional Gold‐Decorated Nanoporous Copper Core–Shell Composite for Electrocatalysis and Nonenzymatic Biosensing

Contact Info

Product

Resources

About