An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation

An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation

Utilizing a simple fluidic structure, we demonstrate the improved performance of oxidase-based enzymatic biosensors. Electrolysis of water is utilized to generate bubbles to manipulate the oxygen microenvironment close to the biosensor in a fluidic channel. For the proper enzyme reactions to occur,...

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Bibliographic Details
Main Authors: Chang-Soo Kim, Jongwon Park, Nitin Radhakrishnan
Format: Article
Language:English
Published: MDPI AG 2012-06-01
Series:Sensors
Subjects:
bubble
electrolysis
oxygen
hydrogen
biosensor
oxidase
Online Access:http://www.mdpi.com/1424-8220/12/7/8955
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spelling doaj-2f495a6f1726473b8854c22cb277b8c42020-11-25T01:05:14ZengMDPI AGSensors1424-82202012-06-011278955896510.3390/s120708955An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen ManipulationChang-Soo KimJongwon ParkNitin RadhakrishnanUtilizing a simple fluidic structure, we demonstrate the improved performance of oxidase-based enzymatic biosensors. Electrolysis of water is utilized to generate bubbles to manipulate the oxygen microenvironment close to the biosensor in a fluidic channel. For the proper enzyme reactions to occur, a simple mechanical procedure of manipulating bubbles was developed to maximize the oxygen level while minimizing the pH change after electrolysis. The sensors show improved sensitivities based on the oxygen dependency of enzyme reaction. In addition, this oxygen-rich operation minimizes the ratio of electrochemical interference signal by ascorbic acid during sensor operation (<em>i.e.</em>, amperometric detection of hydrogen peroxide). Although creatinine sensors have been used as the model system in this study, this method is applicable to many other biosensors that can use oxidase enzymes (e.g., glucose, alcohol, phenol, <em>etc</em>.) to implement a viable component for in-line fluidic sensor systems.http://www.mdpi.com/1424-8220/12/7/8955bubbleelectrolysisoxygenhydrogenbiosensoroxidase
collection DOAJ
language English
format Article
sources DOAJ
author Chang-Soo Kim
Jongwon Park
Nitin Radhakrishnan
spellingShingle Chang-Soo Kim
Jongwon Park
Nitin Radhakrishnan
An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
Sensors
bubble
electrolysis
oxygen
hydrogen
biosensor
oxidase
author_facet Chang-Soo Kim
Jongwon Park
Nitin Radhakrishnan
author_sort Chang-Soo Kim
title An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
title_short An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
title_full An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
title_fullStr An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
title_full_unstemmed An Oxidase-Based Electrochemical Fluidic Sensor with High-Sensitivity and Low-Interference by On-Chip Oxygen Manipulation
title_sort oxidase-based electrochemical fluidic sensor with high-sensitivity and low-interference by on-chip oxygen manipulation
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2012-06-01
description Utilizing a simple fluidic structure, we demonstrate the improved performance of oxidase-based enzymatic biosensors. Electrolysis of water is utilized to generate bubbles to manipulate the oxygen microenvironment close to the biosensor in a fluidic channel. For the proper enzyme reactions to occur, a simple mechanical procedure of manipulating bubbles was developed to maximize the oxygen level while minimizing the pH change after electrolysis. The sensors show improved sensitivities based on the oxygen dependency of enzyme reaction. In addition, this oxygen-rich operation minimizes the ratio of electrochemical interference signal by ascorbic acid during sensor operation (<em>i.e.</em>, amperometric detection of hydrogen peroxide). Although creatinine sensors have been used as the model system in this study, this method is applicable to many other biosensors that can use oxidase enzymes (e.g., glucose, alcohol, phenol, <em>etc</em>.) to implement a viable component for in-line fluidic sensor systems.
topic bubble
electrolysis
oxygen
hydrogen
biosensor
oxidase
url http://www.mdpi.com/1424-8220/12/7/8955
work_keys_str_mv AT changsookim anoxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
AT jongwonpark anoxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
AT nitinradhakrishnan anoxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
AT changsookim oxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
AT jongwonpark oxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
AT nitinradhakrishnan oxidasebasedelectrochemicalfluidicsensorwithhighsensitivityandlowinterferencebyonchipoxygenmanipulation
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