Glucose Oxidase-Based Glucose Biosensing with a Simple Dual Ag/AgCl Probe Conductivity Readout

We describe a conductometric assay of the enzymatic conversion of glucose to gluconic acid by dissolved glucose oxidase (GOx), using the generation of proton and gluconate from the reaction product dissociation for glucose detection. Simple basics of ionic conductivity, a silver/silver chloride wire...

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Veröffentlicht in:	Analytical chemistry (Washington) 2024-09, Vol.96 (38), p.15097-15101
Hauptverfasser:	Loha, Kawin, M. Soysa, H. Sasimali, Boonkoom, Thitikorn, Japrung, Deanpen, Schulte, Albert
Format:	Artikel
Sprache:	eng
Schlagworte:	analytical chemistry Assaying Beverages Biosensors Body fluids Conductivity dissociation Electrical measurement Electrochemistry Electrodes gluconates Gluconic acid Glucose Glucose oxidase Immobilization immobilized enzymes Ion currents Microfluidics Nanomaterials Nanotechnology Reaction products Silver Silver chloride
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creator	Loha, Kawin M. Soysa, H. Sasimali Boonkoom, Thitikorn Japrung, Deanpen Schulte, Albert
description	We describe a conductometric assay of the enzymatic conversion of glucose to gluconic acid by dissolved glucose oxidase (GOx), using the generation of proton and gluconate from the reaction product dissociation for glucose detection. Simple basics of ionic conductivity, a silver/silver chloride wire pair, and a small applied potential translate glucose-dependent GOx activity into a scalable cell current. Enzyme immobilization and complex sensor design, involving extra nanomaterials or microfabrication of electrode structures, are entirely avoided, in contrast to all modern electrochemical glucose biosensors. Assay calibration showed a response linearity up to 500 μM, with a sensitivity of about 1.3 nA/μM. Selectivity tests excluded signals from sugars other than glucose, and glucose quantifications with recovery rates close to 100% were reached with a model sample and a beverage. Easy use of elementary physicochemical phenomena and a satisfactory performance are assets of the proposed non-amperometric glucose biosensing strategy. Assay integration into a planar dual electrode platform, with or without microfluidic application option, is feasible because of the simplicity of the sensor readout and suggests a route to affordable glucose analysis in beverage, food, and body fluid samples.
doi_str_mv	10.1021/acs.analchem.4c03088
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subjects	analytical chemistry Assaying Beverages Biosensors Body fluids Conductivity dissociation Electrical measurement Electrochemistry Electrodes gluconates Gluconic acid Glucose Glucose oxidase Immobilization immobilized enzymes Ion currents Microfluidics Nanomaterials Nanotechnology Reaction products Silver Silver chloride
title	Glucose Oxidase-Based Glucose Biosensing with a Simple Dual Ag/AgCl Probe Conductivity Readout
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