Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors
Electrochemical biosensors consist of electrodes modified with nanomaterials that contain immobilized biomolecules for analyte recognition and utilize electrochemical transduction; a glucose meter is an example of such a biosensor. Innovation in glucose monitoring includes non-invasive sensing, wher...
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my.iium.irep.702532020-03-06T01:33:21Z http://irep.iium.edu.my/70253/ Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors Ismail, Nur Alya Batrisya Abd-Wahab, Firdaus Bader, Mamoun M. Wan Salim, Wan Wardatul Amani TA164 Bioengineering TP248.13 Biotechnology Electrochemical biosensors consist of electrodes modified with nanomaterials that contain immobilized biomolecules for analyte recognition and utilize electrochemical transduction; a glucose meter is an example of such a biosensor. Innovation in glucose monitoring includes non-invasive sensing, where alternative body fluids such as saliva can be used in place of blood, eliminating finger-pricking. However, the concentration of glucose in saliva is twofold lower than in blood, demanding a more sensitive transducer. For a decade, research focused on enhancing the transduction layer by modifying electrodes with nanomaterials that can increase electron transfer, enabling detection of glucose at much lower concentrations. The contribution of these nanomaterials towards enhancement of electron transfer can be understood via electrochemical characterization techniques such as cyclic voltammetry (CV), linear sweep voltammetry (LSV), and electrical impedance spectroscopy (EIS). This chapter provides the basis of the voltammetry techniques and EIS with example graphs from our current research. The aforementioned techniques were performed on screen-printed glassy carbon electrodes modified with reduced graphene–conductive polymer composites, with voltammetry measurements providing CV and LSV and EIS measurements, with EIS resulting in Bode and Nyquist plots and Randles equivalent circuit. Results from our study show a reversible electrode reaction that is diffusion controlled. Springer International Publishing AG 2018-12-14 Book Chapter PeerReviewed application/pdf en http://irep.iium.edu.my/70253/1/70253_Electrochemical%20methods%20to%20characterize.pdf application/pdf en http://irep.iium.edu.my/70253/7/70253_Electrochemical%20methods%20to%20characterize_Scopus.pdf Ismail, Nur Alya Batrisya and Abd-Wahab, Firdaus and Bader, Mamoun M. and Wan Salim, Wan Wardatul Amani (2018) Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors. In: Nanotechnology: applications in energy, drug and food. Springer International Publishing AG, pp. 423-439. ISBN 978-3-319-99601-1 https://link.springer.com/chapter/10.1007/978-3-319-99602-8_20#citeas |
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TA164 Bioengineering TP248.13 Biotechnology Ismail, Nur Alya Batrisya Abd-Wahab, Firdaus Bader, Mamoun M. Wan Salim, Wan Wardatul Amani Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
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Electrochemical biosensors consist of electrodes modified with nanomaterials that contain immobilized biomolecules for analyte recognition and utilize electrochemical transduction; a glucose meter is an example of such a biosensor. Innovation in glucose monitoring includes non-invasive sensing, where alternative body fluids such as saliva can be used in place of blood, eliminating finger-pricking. However, the concentration of glucose in saliva is twofold lower than in blood, demanding a more sensitive transducer. For a decade, research focused on enhancing the transduction layer by modifying electrodes with nanomaterials that can increase electron transfer, enabling detection of glucose at much lower concentrations. The contribution of these nanomaterials towards enhancement of electron transfer can be understood via electrochemical characterization techniques such as cyclic voltammetry (CV), linear sweep voltammetry (LSV), and electrical impedance spectroscopy (EIS). This chapter provides the basis of the voltammetry techniques and EIS with example graphs from our current research. The aforementioned techniques were performed on screen-printed glassy carbon electrodes modified with reduced graphene–conductive polymer composites, with voltammetry measurements providing CV and LSV and EIS measurements, with EIS resulting in Bode and Nyquist plots and Randles equivalent circuit. Results from our study show a reversible electrode reaction that is diffusion controlled. |
format |
Book Chapter |
author |
Ismail, Nur Alya Batrisya Abd-Wahab, Firdaus Bader, Mamoun M. Wan Salim, Wan Wardatul Amani |
author_facet |
Ismail, Nur Alya Batrisya Abd-Wahab, Firdaus Bader, Mamoun M. Wan Salim, Wan Wardatul Amani |
author_sort |
Ismail, Nur Alya Batrisya |
title |
Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
title_short |
Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
title_full |
Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
title_fullStr |
Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
title_full_unstemmed |
Electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
title_sort |
electrochemical methods to characterize nanomaterial-based transducers for the development of noninvasive glucose sensors |
publisher |
Springer International Publishing AG |
publishDate |
2018 |
url |
http://irep.iium.edu.my/70253/1/70253_Electrochemical%20methods%20to%20characterize.pdf http://irep.iium.edu.my/70253/7/70253_Electrochemical%20methods%20to%20characterize_Scopus.pdf http://irep.iium.edu.my/70253/ https://link.springer.com/chapter/10.1007/978-3-319-99602-8_20#citeas |
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