- No file added yet -
Functional design of electrolytic biosensor
Version 2 2022-10-18, 04:38Version 2 2022-10-18, 04:38
Version 1 2021-01-18, 13:47Version 1 2021-01-18, 13:47
journal contribution
posted on 2022-10-18, 04:38 authored by DM Gamage Preethichandra, EMI Mala Ekanayake, M OnodaA novel amperometric biosensbased on conjugated polypyrrole (PPy) deposited on a Pt modified ITO (indium tin oxide) conductive glass substrate and their performances are described. We have presented a method of developing a highly sensitive and low-cost nano-biosensor for blood glucose measurements. The fabrication method proposed decreases the cost of production significantly as the amount of noble metals used is minimized. A nano-corrugated PPy substrate was developed through pulsed electrochemical deposition. The sensitivity achieved was 325 mA/(Mcm2) and the linear range of the developed sensor was 50-60 mmol/l. Then the application of the electrophoresis helps the glucose oxidase (GOx) on the PPy substrate. The main reason behind this high enzyme loading is the high electric field applied across the sensor surface (working electrode) and the counter electrode where that pushes the nano-scale enzyme particles floating in the phosphate buffer solution towards the substrate. The novel technique used has provided an extremely high sensitivities and very high linear ranges for enzyme (GOx) and therefore can be concluded that this is a very good technique to load enzyme onto the conducting polymer substrates. © Published under licence by IOP Publishing Ltd.
History
Volume
924Issue
Conference 1Start Page
1End Page
12Number of Pages
12eISSN
1742-6596ISSN
1742-6588Publisher
Institute of Physics Publishing , UKPublisher DOI
Additional Rights
CC BY 3.0Peer Reviewed
- Yes
Open Access
- Yes
External Author Affiliations
University of Hyogo, JapanEra Eligible
- Yes
Journal
Journal of Physics: Conference SeriesUsage metrics
Categories
Licence
Exports
RefWorksRefWorks
BibTeXBibTeX
Ref. managerRef. manager
EndnoteEndnote
DataCiteDataCite
NLMNLM
DCDC