Communication—Accessing Stability of Oxidase-Based Biosensors via Stabilizing the Advanced H<sub>2</sub>O<sub>2</sub>Transducer

Карпова, Е. В.; Karyakina, Elena E.; Karyakin, Arkady A.

doi:10.1149/2.0091705jes

Cited by 20 publications

(20 citation statements)

References 26 publications

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“…ferrocyanide is also possible and may be desirable when a less acidic pH is required to preserve the activity of enzymes or other biomolecules. [15] Chemical growth, on the other hand, may also be used to produce Prussian Blue films, both on electrodes [26,30,31] and on inert surfaces [32] in many different ways. [33] However, this is not an ideal approach because it lacks the surface selectivity and much of the control that electrochemical methods enjoy.…”

Section: Preparation Of Pbmentioning

confidence: 99%

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Pellitero

Fremeau

Villa

et al. 2019

Sensors and Actuators B: Chemical

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Highlights We present the production of an electrochromic screen-printable paste based on Prussian Blue. These blue electrodes display excellent spectroelectrochemical reversibility and high catalytic activity towards the reduction of H2O2.  These blue electrodes enable both the electrochemical and optical quantitative determination of hydrogen peroxide.  The reported blue electrodes are highly suitable transducers for the construction of oxidase-based biosensors.  A glucose biosensor is presented to demonstrate the spectroelectrochemical capabilities of these new electrodes. AbstractPrussian Blue (PB)-modified graphite screen-printed electrodes are increasingly being used in electrochemical biosensors. However, they do not allow the observation of the electrochromism of PB. This work presents the construction of PB-based, electrochromic screen-printed biosensors. Although electrically more resistive than their graphite counterparts, these new PBbased electrodes enable both the amperometric and colorimetric detection of hydrogen peroxide.This is the first time that this has been achieved using screen-printed electrodes, and we demonstrate it spectroelectrochemically on a glucose biosensor. The biosensor electrochemical performance equals that of previously reported PB/graphite electrodes, being able to detect down to 4 µM H2O2 and 54 µM glucose. At the same time, and in contrast to PB/graphite electrodes, the new PB-based electrodes afford the optical detection of these two analytes down to 1.2 µM and 15 µM, respectively. The dynamic ranges of the glucose biosensors obtained at the PBbased electrodes are 0.1-1 mM (amperometric) and 0.025-2.5 mM (Colorimetric), matching the physiological glucose concentration range in body fluids other than blood or serum.

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Section: Preparation Of Pbmentioning

confidence: 99%

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Pellitero

Fremeau

Villa

et al. 2019

Sensors and Actuators B: Chemical

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“…21 Operational stability of the oxide-based electrochemical sensor characterised in this study, like the oxidase-based biosensors, is of particular importance as it significantly improves the sensor performance and applicability in the relevant environment. 22 One requirement for electromotive force (emf) measurements is that both the electrolyte and electrodes are chemically stable in the operating environment. 23 Thus, emf measurements can be conveniently used to measure the more active element in an alloy, as illustrated in this study where the activity of Mg has been measured in molten Al.…”

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confidence: 99%

Assessment of MgZr₄P₆O₂₄as a Solid Electrolyte for Sensing Mg in Molten Non-Ferrous Alloys

Adamu

Jacob

Kale

2020

J. Electrochem. Soc.

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The potential solid electrolyte, MgZr4P6O24 was prepared using a modified sol-gel method. Both structural and electrical properties of the solid electrolyte were determined. DSC-TGA analysis indicated that pure dried xerogel when calcined at 900 o C converts to single phase MgZr4P6O24 nanopowder with good crystallinity. Pellets of 13mm diameter and 3.8mm thickness made by uniaxial compression were sintered at 1300 o C for 24h. XRD and HR-TEM indicated that the crystalline phase is monoclinic having crystallite size of approximately 40nm. The sintered pellets were stable in the temperature range from 1000 to 1300 o C, with minor extraneous peaks indicating traces of a coexistent second phase (Zr2P2O9) at the higher temperature. Using impedance spectroscopy, the electrical conductivity of MgZr4P6O24 was determined as 7.23 x 10-3 Scm-1 at 725 o C. MgZr4P6O24 pellet was successfully used for fabrication of a solid-state Mg-sensor for measuring Mg concentration in molten Al at 700±5 o C, with biphasic powder mixture of MgCr2O4+Cr2O3 as ceramic reference electrode in air. A linear dependence of emf on logarithm of Mg concentration was obtained. The results indicate that the transport number of Mg 2+-cation in MgZr4P6O24 is 0.85±0.03 at 700 o C. The solid electrolyte has likely applications in high-temperature electrochemical sensors.

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“…Enzymes‐oxidases‐oxidize their specific substrates in the presence of molecular oxygen and forms hydrogen peroxide as one of reaction product . Therefore, the application of different metal hexacyanoferrates in modified electrodes has been extensively studied and these materials are becoming used as redox mediators in biosensors based on oxidase‐type enzymes as the biological recognition element.…”

Section: Introductionmentioning

confidence: 99%

“…However, the mechanism of hydrogen peroxide reduction catalysis by transition metals hexacyanoferrates is not discovered yet . Moreover, it is claimed that the electrocatalytic activity of non‐iron transition metals hexacyanoferrates occurs due to presence of some Prussian blue in the crystal lattice of these hexacyanoferrates . Recently Sitnikova et.…”

Section: Introductionmentioning

confidence: 99%

“…Even though composite Prussian blue‐non‐iron metal hexacyanoferrate layers have been created successfully , according to the best of our knowledge, glucose biosensor containing composite Prussian blue/non‐iron metal hexacyanoferrate (PB‐Me non‐iron HCF) layer have not been reported yet. An important advantage in the formation of PB‐Me non‐iron HCF layer is simplicity of deposition procedure.…”

Section: Introductionmentioning

confidence: 99%

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Physicochemical Characteristics of Polypyrrole/(Glucose oxidase)/(Prussian Blue)‐based Biosensor Modified with Ni‐ and Co‐Hexacyanoferrates

et al. 2018

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In this work, three types of electrodes suitable for amperometric glucose biosensors were designed. One type of electrode was based on bio‐selective layer of polypyrrole/(glucose oxidase)/(Prussian Blue) (Ppy/GOx/PB) and it was used as a control electrode regarding to which electrochemical properties of two other types of electrodes were compared. During the formation of Prussian blue layers graphite electrodes were additionally modified by Ni‐hexacyanoferrate (NiHCF) and by Co‐hexacyanoferrate (CoHCF) in order to design Ppy/GOx/PB‐NiHCF and Ppy/GOx/PB‐CoHCF electrodes, respectively. Some physicochemical characteristics of all three types of electrodes were evaluated and compared. The Ppy/GOx/PB‐NiHCF electrode showed wider linear range of the calibration curve than Ppy/GOx/PB and Ppy/GOx/PB‐CoHCF electrodes. The effect of temperature on analytical performance of the Ppy/GOx/PB‐NiHCF based biosensor has been evaluated and activation energy of enzyme catalysed reaction has been calculated within the temperature range of 15 °C to 30 °C.

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Communication—Accessing Stability of Oxidase-Based Biosensors via Stabilizing the Advanced H₂O₂Transducer

Cited by 20 publications

References 26 publications

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Assessment of MgZr₄P₆O₂₄as a Solid Electrolyte for Sensing Mg in Molten Non-Ferrous Alloys

Physicochemical Characteristics of Polypyrrole/(Glucose oxidase)/(Prussian Blue)‐based Biosensor Modified with Ni‐ and Co‐Hexacyanoferrates

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Communication—Accessing Stability of Oxidase-Based Biosensors via Stabilizing the Advanced H2O2Transducer

Cited by 20 publications

References 26 publications

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Electrochromic biosensors based on screen-printed Prussian Blue electrodes

Assessment of MgZr4P6O24as a Solid Electrolyte for Sensing Mg in Molten Non-Ferrous Alloys

Physicochemical Characteristics of Polypyrrole/(Glucose oxidase)/(Prussian Blue)‐based Biosensor Modified with Ni‐ and Co‐Hexacyanoferrates

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Communication—Accessing Stability of Oxidase-Based Biosensors via Stabilizing the Advanced H₂O₂Transducer

Assessment of MgZr₄P₆O₂₄as a Solid Electrolyte for Sensing Mg in Molten Non-Ferrous Alloys