Development of the BAT-26 mutation-based electrochemical genosensor for identifying microsatellite instability in relationship to cancer

Development of the BAT-26 mutation-based electrochemical genosensor for identifying microsatellite instability in relationship to cancer

Screening for microsatellite instability is one of the biggest challenges in the cancer diagnosis due to its association with different types of cancer development. In this sense, the development of fast and highly sensitive analytical devices for early the cancer detection is a high priority. In th...

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Bibliographic Details
Published in:Sensing and Bio-Sensing Research Vol. 44; p. 100651
Main Authors: Garcia-Melo, Luis Fernando, Chagoya Pio, Norma Andrea, Campoy Ramírez, Jorge Alfredo, Madrigal-Bujaidar, Eduardo, Álvarez-González, Isela, Morales-González, José A., Madrigal-Santillán, Eduardo O., Batina, Nikola
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2024
Elsevier
Subjects:
BAT-26 biomarker
cancer detection
Genosensor
Microsatellite instability
Mutation
LOD
cancer detection
MSI
SDS
Aelec
sNC
Genosensor
Microsatellite instability
DPV
Dox
STM
CV
MMR
BAT-26 biomarker
DNA
MUA
Mutation
MUCS
SPGE
SAM
ssDNA
dsDNA
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Summary:Screening for microsatellite instability is one of the biggest challenges in the cancer diagnosis due to its association with different types of cancer development. In this sense, the development of fast and highly sensitive analytical devices for early the cancer detection is a high priority. In the present work, a highly sensitive electrochemistry genosensor is developed and described for BAT-26 mutation detection using: differential pulse voltammetry (DPV), and cyclic voltametric (CV) supported by scanning tunnel microscopy (STM). The redox reaction of Fe(CN)63−/4– was monitored to probe the presence DNA target. The results demonstrate that modifying the screen-printed gold electrode surface (SPGE) 250AT with a combination of 11-mercaptoundecanoic acid (MUA) and a single-stranded DNA oligonucleotide successfully altered the electrode's properties, particularly its affinity for detecting the BAT-26 mutation under physiological conditions. The genosensor exhibited a wide linear range (100 aM to 1 μM) and achieved a low detection limit of 71.74 aM under optimal parameters. These characteristics, coupled with its high sensitivity and rapid analysis time, make it a promising candidate for development into a portable microsatellite instability diagnostic kit. •Development of an Electrochemical Biosensor for Detecting Mutations in the BAT-26 Gene.•The genosensor achieved attomolar detection limits for the BAT-26 mutation.•The electrochemical genosensor may be of help in the diagnosis of microsatellite instability
ISSN:2214-1804
2214-1804
DOI:10.1016/j.sbsr.2024.100651