Laccase-based biosensors for detection of phenolic compounds

Rodríguez-Delgado, Melissa Marlene; Alemán‐Nava, Gibrán S.; Rodríguez-Delgado, José Manuel; Dieck-Assad, Graciano; Martínez-Chapa, Sergio O.; Barceló, Damià; Parra‐Saldívar, Roberto

doi:10.1016/j.trac.2015.05.008

Cited by 264 publications

(164 citation statements)

References 134 publications

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“…Laccase enzymes are widespread among plants,f ungi and bacteria.T hey catalyzet he oxidation of variousa romatic compounds as neurotransmitters [7],p harmaceuticals [24][25][26],h alogenated pesticides [27] and wastewaters from industrial processes [11,23].T his plethora of substrates have prompted laccases to emerge as promising recognition elements for the construction of sensors with diverse applications [28].W ec onsidert hat the unification of the way in which different laccases can be immobilized on as ensor surface is ar esult of technological relevance. Thep latform presented in this work is based on screen printing electrodes and its modification with silica nanospheres with ap Ia round 2 [ 29] allows the adsorption of fungal and plant laccases,d ue to their isoelectric points (pI) rangingf rom 3t o9 [ 30].T he approacht aken in this work is similar to the one usedf or the fabrication of glucose meters,acombination of screen printing with noncontact dispensing technologies [31,32].A lso,t he measurement procedure,c hronoamperometry,i st he same.…”

Section: Resultsmentioning

confidence: 99%

“…Thep latform presented in this work is based on screen printing electrodes and its modification with silica nanospheres with ap Ia round 2 [ 29] allows the adsorption of fungal and plant laccases,d ue to their isoelectric points (pI) rangingf rom 3t o9 [ 30].T he approacht aken in this work is similar to the one usedf or the fabrication of glucose meters,acombination of screen printing with noncontact dispensing technologies [31,32].A lso,t he measurement procedure,c hronoamperometry,i st he same. Therefore,i ts hould be possible to adapt ag reat number of the tests already presented in the literature to this format, avoidingt he use of moree xpensive surfaces as glassy carbon or gold, or more chemicald emanding procedures,l ike covalent or crosslinking bonding,r ecently reviewed by Parra and co-workers [28].…”

Section: Resultsmentioning

confidence: 99%

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Versatile Electrochemical Platform for the Determination of Phenol‐like Compounds Based on Laccases from Different Origins

2016

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Simple and fast methods for the monitoring of phenol‐like compounds are relevant in diverse fields ranging from waste management to neurosciences. Laccases are copper‐containing enzymes, which, depending on their origin, are able to oxidize different phenol compounds at different pH conditions. Through adequate laccase immobilization, disposable screen printed electrodes can be used as interphase to build amperometric phenol sensors. In this work three different laccases were studied for the determination of phenol‐like compounds, two of them are isoenzymes from Trametes trogii and the third one from Rhus vernicifera. Their immobilization on screen printed electrodes is presented for the construction of amperometric sensors. The electrode substrate is composed by graphite screen printed electrodes modified with carbon nanotubes and silica microspheres where, depending on the application, one of the three laccases is adsorbed. As each laccase shows an optimum working pH, they were conveniently selected to determine dopamine at physiological pH and catechol at acid pH. Determinations in the micromolar range were possible in both cases. Chronoamperometry shows to be an effective technique for their determinations, simpler than other electrochemical methods already presented in the literature.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Versatile Electrochemical Platform for the Determination of Phenol‐like Compounds Based on Laccases from Different Origins

2016

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“…They catalyze the oxidation of various organic substances such as o ‐ and p ‐diphenols, polyphenols, aminophenols, lignin, and inorganic ions with the concomitant reduction of molecular oxygen to water . They are widely used in a variety of industrial branches including paper, textile, food, cosmetics, but also as recognition element in biosensors for phenolic compounds . Since they were the first enzymes which effectively catalyze the cathodic reduction of dissolved oxygen at (carbon) electrodes they have been frequently applied as biocatalyst for oxygen reduction in biofuel cells …”

Section: Introductionmentioning

confidence: 99%

Electrosynthesized Molecularly Imprinted Polymer for Laccase Using the Inactivated Enzyme as the Target

Yarman

2018

Bulletin Korean Chem Soc

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The first molecularly imprinted polymer (MIP) for the recognition of the copper‐enzyme laccase was successfully prepared by electropolymerizing scopoletin in the presence of alkaline‐inactivated enzyme. Laccase‐MIP and the control polymer without laccase (nonimprinted polymer, NIP) were characterized by voltammetry using the redox marker ferricyanide. After electropolymerization, the signals for ferricyanide for both the MIP and the NIP were almost completely suppressed and increased after removal of the target from the polymer layer. Rebinding of both inactivated and active laccase decreased the ferricyanide peak currents to almost equal extent. The relative decrease of signal suppression approached saturation above 10 nM. Furthermore, the surface activity of rebound laccase toward the oxidation of catechol was investigated. The surface activity approached saturation above 10 nM, a value close to the value of the measurements with ferricyanide. Interaction of NIP with laccase brought about a six times smaller signal of catechol oxidation.

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“…Among the various fungi, white rot fungi are the well-known and potent producers of laccase. In recent years laccase have attracted commercial significance due to their extensive use in food (Minussi et al 2002;Rodrìguez and Toca Herrera 2006), textile (Abadulla et al 2000), pulp and paper industry, waste water treatment (Casa et al 2003), bioremediation (Duran and Esposito 2000), nano-biotechnology, agrobiotechnology and pharmaceutical industries (Rodríguez-Delgado et al 2015;Legerská et al 2016). Laccase can be produced by batch, fed-batch or continuous cultivation.…”

Section: Introductionmentioning

confidence: 99%

Statistical optimization for enhanced production of extracellular laccase from Aspergillus sp. HB_RZ4 isolated from bark scrapping

Bhamare

Jadhav

Sayyed

2018

Environmental Sustainability

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Laccase enzyme has gained tremendous demand in various industries, waste water treatment, bioremediation and nanobiotechnology. This compels the availability of enzyme in greater yields that can be achieved by employing potential laccase producing cultures and statistical optimization. Use of Plackett-Burman design (PBD) that evaluates various medium components and having two level factorial design help to determine the factor and its level to increase the yield of product. Present paper reports the screening of laccase producting fungus identified as Aspergillus sp. by 18S rDNA of internal transcribed spacer regions and the large subunit. Aspergillus sp. HB_RZ4 isolated from tree bark scrapping showed enhanced production of laccase in minimal medium by applying two-stage statistical approach, as PBD and Response Surface Methodology using central composite design (CCD). In the first stage of optimization, out of 8 variables of minimal medium, glucose, yeast extract, CuSO 4 and temperature were found as significant components that influenced laccase production. Aspergillus sp. HB_RZ4 produced highest amount (7.27 Uml −1 ) of extracellular laccase. Further optimization using CCD revealed that 34 °C temperature, 2.1 gL −1 of glucose (carbon source), 2.5 gL −1 of yeast extract (nitrogen source) and 0.0025 gLCuSO 4 (inducer) were the optimum values that yielded maximum laccase. The optimization by PBD statistical design studies revealed optimum laccase yield with conditions being; pH, 6.0; temperature, 34 °C; incubation, 9 days; glucose, 2.1 gL −1 ; yeast extract, 2.5 gL −1 and CuSO 4 ., 0.0025 gL −1 .

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Laccase-based biosensors for detection of phenolic compounds

Cited by 264 publications

References 134 publications

Versatile Electrochemical Platform for the Determination of Phenol‐like Compounds Based on Laccases from Different Origins

Versatile Electrochemical Platform for the Determination of Phenol‐like Compounds Based on Laccases from Different Origins

Electrosynthesized Molecularly Imprinted Polymer for Laccase Using the Inactivated Enzyme as the Target

Statistical optimization for enhanced production of extracellular laccase from Aspergillus sp. HB_RZ4 isolated from bark scrapping

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