Advances in enzyme bioelectrochemistry

Pereira, Andressa R.; Sedenho, Graziela C.; Souza, João Carlos Perbone de; Crespilho, Frank N.

doi:10.1590/0001-3765201820170514

Cited by 28 publications

(20 citation statements)

References 176 publications

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“…These biosensors require the enzyme immobilization on the electrode surface. The most frequently used methods for enzyme immobilization are noncovalent adsorption, covalent bonding, entrapment, cross-linking, and affinity, and they are discussed below [14].…”

Section: Enzymatic Biosensorsmentioning

confidence: 99%

“…hydrogen bonds, and electrostatic interactions [14]. In contrast, in the covalent bonding immobilization, the enzyme is anchored on the electrode surface by multiple covalent bonds between support functional groups and enzymes.…”

Section: Enzyme Immobilization On the Electrode Surfacementioning

confidence: 99%

“…Therefore, the enzymatic activity of the immobilized enzyme is decreased, when compared to native enzyme activity [15]. Cross-linking immobilization is an alternative, which requires the reaction between cross-linking protein molecules and a chemical cross-linker, usually glutaraldehyde [14]. The diversity of immobilization techniques allows the immobilization of enzymes in distinct materials, such as carbon nanostructures, (carbon black, nanotubes, and graphene and derivatives, among others), ceramic or polymeric matrices, and nanoparticles [16,17].…”

Section: Enzyme Immobilization On the Electrode Surfacementioning

confidence: 99%

See 2 more Smart Citations

Electrochemical Biosensors Containing Pure Enzymes or Crude Extracts as Enzyme Sources for Pesticides and Phenolic Compounds with Pharmacological Property Detection and Quantification

Colmati¹,

Sgobbi²,

Teixeira³

et al. 2019

Biosensors for Environmental Monitoring

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Biosensors are chemical sensors in which the recognition system is based on a biochemical mechanism. They perform the specific component detection in a sample through an appropriate analytical signal. Enzyme-based biosensors are the most prominent biosensors because of their high specificity and selectivity; besides being an alternative to the common immunosensors, they are more expensive and present a limited binding capacity with the antigen depending on assay conditions. This chapter approaches the use of enzymes modified electrodes in amperometric biosensing application to detect and quantify pesticides and phenolic compounds with pharmacological properties, as they have been a promising analytical tool in environmental monitoring. These biosensors may be prepared from pure enzymes or their crude extracts. Pure enzyme-based biosensors present advantages as higher substrate specificity and selectivity when compared to crude extract enzymatic biosensors; nevertheless, the enzyme high costs are their drawbacks. Enzymatic crude extract biosensors show lower specificity due to the fact that they may contain more than one type of enzyme, but they may be obtained from low-cost fabrication methods. In addition, they can contain enzyme cofactors besides using the enzyme in its natural conformation.

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Section: Enzymatic Biosensorsmentioning

confidence: 99%

Section: Enzyme Immobilization On the Electrode Surfacementioning

confidence: 99%

Section: Enzyme Immobilization On the Electrode Surfacementioning

confidence: 99%

See 1 more Smart Citation

Electrochemical Biosensors Containing Pure Enzymes or Crude Extracts as Enzyme Sources for Pesticides and Phenolic Compounds with Pharmacological Property Detection and Quantification

Colmati¹,

Sgobbi²,

Teixeira³

et al. 2019

Biosensors for Environmental Monitoring

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“…. CS, a natural biopolymer, showed good biocompatibility, nontoxicity, excellent film forming ability and high mechanical strength to immobilize proteins and also to act as dispersant for nanomaterials . The interesting inherent properties of the CTAB surfactant were used to obtain a good dispersion of GR without particles aggregation.…”

Section: Direct Electron Transfer Behavior Of Heme Proteins and Porphmentioning

confidence: 99%

Nitric Oxide Detection Using Electrochemical Third‐generation Biosensors – Based on Heme Proteins and Porphyrins

et al. 2018

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Nitric oxide radical (NO) is a signalling molecule involved in virtually all forms of life. Its relevance has been leading to the development of different analytical methodologies to assess the temporal and spatial fluxes of NO under the complex biological milieu. Third‐generation electrochemical biosensors are promising tools for in loco and in vivo NO quantification and, over the past years, heme proteins and porphyrins have been used in their design. Since there are some limitations with the biorecognition element directly adsorbed onto the electrode surface, nanomaterials (carbon nanotubes, gold nanoparticles, etc.) and polymers (cellulose, chitosan, nafion®, polyacrylamide, among others) have been explored to achieve high kinetics and better biosensor performance. In this review, a broad overview of the field of electrochemical third‐generation biosensors for NO electroanalysis is presented, discussing their main characteristics and aiming new outlooks and advances in this field.

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“…The most of studied sensors are based on enzymatic oxidation of glucose to gluconolactone by glucose oxidase (GOx) and further amperometric detection of hydrogen peroxide by using various electron mediators (e. g. Prussian blue) [10]. However, performance of such enzymatic sensors is limited by characteristic features of an enzyme itself.…”

Section: Introductionmentioning

confidence: 99%

A Flexible Nafion Coated Enzyme‐free Glucose Sensor Based on Au‐dimpled Ti Structures

et al. 2019

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The detection of glucose at low concentrations using electrochemical sensors is of great importance due to the possibility of using different human body fluids than blood, such as e. g. urine, saliva, sweat or tears. The interest behind those biofluids is related to their utility in non‐invasive sugar determination. In this work, we present flexible, fully biocompatible electrode material based on Au nanoparticles immobilized onto titanium dimples. Au−Ti heterostructures were obtained via electrochemical anodization of titanium foil in presence of fluoride anions followed by chemical etching, magnetron sputtering of gold and subsequent thermal dewetting in continuous regime. In the last step of fabrication, electrodes were modified by permselective Nafion membrane. The selection of the best electrode material among different configurations was carried out basing on the electrochemical activity in the contact with 5 mM glucose dissolved in neutral air‐saturated 0.1 M PBS. For the 10 nm Au dewetted gold film, limit of detection of 30 μM and high sensitivity of 93 mA cm−2 mM−1 were achieved. Application of Nafion membrane caused complete inhibition of the impact of various interference species onto the glucose detection. Good selectivity and repeatability combined with the resistance to prolonged mechanical stress suggest that prepared material can be used in non‐invasive glucose sensing.

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Advances in enzyme bioelectrochemistry

Cited by 28 publications

References 176 publications

Electrochemical Biosensors Containing Pure Enzymes or Crude Extracts as Enzyme Sources for Pesticides and Phenolic Compounds with Pharmacological Property Detection and Quantification

Electrochemical Biosensors Containing Pure Enzymes or Crude Extracts as Enzyme Sources for Pesticides and Phenolic Compounds with Pharmacological Property Detection and Quantification

Nitric Oxide Detection Using Electrochemical Third‐generation Biosensors – Based on Heme Proteins and Porphyrins

A Flexible Nafion Coated Enzyme‐free Glucose Sensor Based on Au‐dimpled Ti Structures

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