Modified graphene-based nanocomposite material for smart textile biosensor to detect lactate from human sweat

Hydrophobic cotton fabric and chemically modified G-PU-RGO-PB paste based electrochemical wearable lactate biosensor provides on body monitoring for patient. Sensor contains three electrodes system designed by template method where working electrode (WE) and counter electrodes (CE) filled with modif...

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Published inBiosensors and bioelectronics. X Vol. 10; p. 100103
Main Authors Khan, Ashaduzzaman, Winder, Maximilian, Hossain, Gaffar
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.05.2022
Elsevier
Subjects
Embroider conductive yarn
Enzyme immobilization
Lactate
Modified graphene
Smart textile
Wearable biosensor
Wearable biosensor
Enzyme immobilization
Embroider conductive yarn
Modified graphene
Lactate
Smart textile
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Abstract Hydrophobic cotton fabric and chemically modified G-PU-RGO-PB paste based electrochemical wearable lactate biosensor provides on body monitoring for patient. Sensor contains three electrodes system designed by template method where working electrode (WE) and counter electrodes (CE) filled with modified G-PU-RGO-PB paste and Ag/AgCl were used to fill the reference electrode. In addition, embroidered conductive silver yarn work as a conductor was used to secure connection between printed electrodes and the device. Here, we present a suitable technique to get stable electron transfer catalytic activity while enzyme was immobilized over the working electrode. Electrode's performance was examined, using cyclic voltammetry technique (CV) in ferricyanide solution (5.0 mM-25mM), and found linear relationship with relative standard deviations (RSD) ∼0.2%. Lactate oxidase and chitosan solution was combined to the electrode surface for amperometric and differential pulse voltametric sensing. The limit of detection (LOD) of 0.4 mM and the limit of quantification (LOQ) of 1.3 mM for lactate was obtained from human sweat, respectively. This sensor gives excellent reproducibility to the lactate concentration after washing the sensor by domestic washing machine and its RSD was found 3.06%. We anticipate that the results, which have been achieved after analysis, would open up the fundamental studies in the area of wearable textile-based sensor for real time health care monitoring and medical diagnosis. •Graphene based nanocomposite material for wearable biosensor.•Smart-textile biosensor for lactate analysis from sweat.•Electrochemical non-invasive biosensor for lactate analysis.•Wearable smart-textile sensor for real-time lactate analysis from sweat.
AbstractList Hydrophobic cotton fabric and chemically modified G-PU-RGO-PB paste based electrochemical wearable lactate biosensor provides on body monitoring for patient. Sensor contains three electrodes system designed by template method where working electrode (WE) and counter electrodes (CE) filled with modified G-PU-RGO-PB paste and Ag/AgCl were used to fill the reference electrode. In addition, embroidered conductive silver yarn work as a conductor was used to secure connection between printed electrodes and the device. Here, we present a suitable technique to get stable electron transfer catalytic activity while enzyme was immobilized over the working electrode. Electrode's performance was examined, using cyclic voltammetry technique (CV) in ferricyanide solution (5.0 mM-25mM), and found linear relationship with relative standard deviations (RSD) ∼0.2%. Lactate oxidase and chitosan solution was combined to the electrode surface for amperometric and differential pulse voltametric sensing. The limit of detection (LOD) of 0.4 mM and the limit of quantification (LOQ) of 1.3 mM for lactate was obtained from human sweat, respectively. This sensor gives excellent reproducibility to the lactate concentration after washing the sensor by domestic washing machine and its RSD was found 3.06%. We anticipate that the results, which have been achieved after analysis, would open up the fundamental studies in the area of wearable textile-based sensor for real time health care monitoring and medical diagnosis.
Hydrophobic cotton fabric and chemically modified G-PU-RGO-PB paste based electrochemical wearable lactate biosensor provides on body monitoring for patient. Sensor contains three electrodes system designed by template method where working electrode (WE) and counter electrodes (CE) filled with modified G-PU-RGO-PB paste and Ag/AgCl were used to fill the reference electrode. In addition, embroidered conductive silver yarn work as a conductor was used to secure connection between printed electrodes and the device. Here, we present a suitable technique to get stable electron transfer catalytic activity while enzyme was immobilized over the working electrode. Electrode's performance was examined, using cyclic voltammetry technique (CV) in ferricyanide solution (5.0 mM-25mM), and found linear relationship with relative standard deviations (RSD) ∼0.2%. Lactate oxidase and chitosan solution was combined to the electrode surface for amperometric and differential pulse voltametric sensing. The limit of detection (LOD) of 0.4 mM and the limit of quantification (LOQ) of 1.3 mM for lactate was obtained from human sweat, respectively. This sensor gives excellent reproducibility to the lactate concentration after washing the sensor by domestic washing machine and its RSD was found 3.06%. We anticipate that the results, which have been achieved after analysis, would open up the fundamental studies in the area of wearable textile-based sensor for real time health care monitoring and medical diagnosis. •Graphene based nanocomposite material for wearable biosensor.•Smart-textile biosensor for lactate analysis from sweat.•Electrochemical non-invasive biosensor for lactate analysis.•Wearable smart-textile sensor for real-time lactate analysis from sweat.
ArticleNumber 100103
Author Hossain, Gaffar
Winder, Maximilian
Khan, Ashaduzzaman
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Keywords Wearable biosensor
Enzyme immobilization
Embroider conductive yarn
Modified graphene
Lactate
Smart textile
Language English
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Snippet Hydrophobic cotton fabric and chemically modified G-PU-RGO-PB paste based electrochemical wearable lactate biosensor provides on body monitoring for patient....
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SubjectTerms Embroider conductive yarn
Enzyme immobilization
Lactate
Modified graphene
Smart textile
Wearable biosensor
Title Modified graphene-based nanocomposite material for smart textile biosensor to detect lactate from human sweat
URI https://dx.doi.org/10.1016/j.biosx.2021.100103
https://doaj.org/article/6945abe38f294bcfa5eae8670e8171b5
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