Enhancement of the enzymatic biosensor response through targeted electrode surface roughness
Enhancement of the enzymatic biosensor response through targeted electrode surface roughness
The field of enzymatic biosensors applied to brain electrochemistry has rapidly expanded over the last few years, thanks in part to their excellent selectivity to specific target species. Much current research is therefore focused on enhancing the electrochemical signal, which often involves the detection of stoichiometric amounts of H2O2 formed as part of the enzyme mechanism. This opens the possibility of enhancing a biosensor's performance by facilitating the H2O2 oxidation signal through surface modification. Here, we investigate the impact of the roughness of the platinum surface on the biosensor response, where rougher platinum surfaces show greater activity for H2O2 oxidation, and therefore enhanced biosensor sensitivity. Through careful manipulation of the electrode surface roughness, we are able to show a significant improvement to the LOD when using a rougher electrode surface. Additionally, we have shown that this enhanced surface roughness has no detrimental effects toward the electrode response time. This suggests that surface roughness could be a simple and easy to implement means of enhancing the sensitivity of electrode-based enzymatic biosensors, and is an important factor to consider when studying other aspects of biosensor fabrication.
Perry, Samuel C.
8e204d86-4a9c-4a5d-9932-cf470174648e
Gateman, Samantha M.
55ceb3a2-dd5d-48c2-b3a2-6ac8e86f2790
Sifakis, Joseph
70619942-5e03-4aa1-8362-81f2ed3d576b
Pollegioni, Loredano
d0e713a9-0952-4f77-9b3e-8f61095e6e30
Mauzeroll, Janine
af84f034-1e52-4419-a1c2-ce7116db5b07
27 July 2018
Perry, Samuel C.
8e204d86-4a9c-4a5d-9932-cf470174648e
Gateman, Samantha M.
55ceb3a2-dd5d-48c2-b3a2-6ac8e86f2790
Sifakis, Joseph
70619942-5e03-4aa1-8362-81f2ed3d576b
Pollegioni, Loredano
d0e713a9-0952-4f77-9b3e-8f61095e6e30
Mauzeroll, Janine
af84f034-1e52-4419-a1c2-ce7116db5b07
Perry, Samuel C., Gateman, Samantha M., Sifakis, Joseph, Pollegioni, Loredano and Mauzeroll, Janine
(2018)
Enhancement of the enzymatic biosensor response through targeted electrode surface roughness.
Journal of the Electrochemical Society, 165 (12), [G3074].
(doi:10.1149/2.0121812jes).
Abstract
The field of enzymatic biosensors applied to brain electrochemistry has rapidly expanded over the last few years, thanks in part to their excellent selectivity to specific target species. Much current research is therefore focused on enhancing the electrochemical signal, which often involves the detection of stoichiometric amounts of H2O2 formed as part of the enzyme mechanism. This opens the possibility of enhancing a biosensor's performance by facilitating the H2O2 oxidation signal through surface modification. Here, we investigate the impact of the roughness of the platinum surface on the biosensor response, where rougher platinum surfaces show greater activity for H2O2 oxidation, and therefore enhanced biosensor sensitivity. Through careful manipulation of the electrode surface roughness, we are able to show a significant improvement to the LOD when using a rougher electrode surface. Additionally, we have shown that this enhanced surface roughness has no detrimental effects toward the electrode response time. This suggests that surface roughness could be a simple and easy to implement means of enhancing the sensitivity of electrode-based enzymatic biosensors, and is an important factor to consider when studying other aspects of biosensor fabrication.
Text
Perry_2018_J._Electrochem._Soc._165_G3074
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Submitted date: 19 April 2018
Published date: 27 July 2018
Identifiers
Local EPrints ID: 491246
URI: http://eprints.soton.ac.uk/id/eprint/491246
ISSN: 0013-4651
PURE UUID: bc3df175-4b3e-44e3-9647-2990c324a4f7
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Date deposited: 18 Jun 2024 16:42
Last modified: 19 Jun 2024 01:55
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Contributors
Author:
Samuel C. Perry
Author:
Samantha M. Gateman
Author:
Joseph Sifakis
Author:
Loredano Pollegioni
Author:
Janine Mauzeroll
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