Tailoring Electrode Surface Charge to Achieve Discrimination and Quantification of Chemically Similar Small Molecules with Electrochemical Aptamers

Electrochemical biosensors based on structure‐switching aptamers offer many advantages because they can operate directly in complex samples and offer the potential to integrate with miniaturized electronics. Unfortunately, these biosensors often suffer from cross‐reactivity problems when measuring a...

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Veröffentlicht in:	Advanced functional materials 2023-01, Vol.33 (1), p.n/a
Hauptverfasser:	Kesler, Vladimir, Fu, Kaiyu, Chen, Yihang, Park, Chan Ho, Eisenstein, Michael, Murmann, Boris, Soh, H. Tom
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Sprache:	eng
Schlagworte:	Biosensors Chemical composition cross‐reactivity drug discrimination drug quantification electrochemical aptamer biosensors Hydroxyl groups Materials science Metabolites nanostructured electrodes Reagents Surface charge
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creator	Kesler, Vladimir Fu, Kaiyu Chen, Yihang Park, Chan Ho Eisenstein, Michael Murmann, Boris Soh, H. Tom
description	Electrochemical biosensors based on structure‐switching aptamers offer many advantages because they can operate directly in complex samples and offer the potential to integrate with miniaturized electronics. Unfortunately, these biosensors often suffer from cross‐reactivity problems when measuring a target in samples containing other chemically similar molecules, such as precursors or metabolites. While some progress has been made in selecting highly specific aptamers, the discovery of these reagents remains slow and costly. In this work, a novel strategy is demonstrated to distinguish molecules with miniscule difference in chemical composition (such as a single hydroxyl group)—with cross reactive aptamer probes—by tuning the charge state of the surface on which the aptamer probes are immobilized. As an exemplar, it is shown that the strategy can distinguish between DOX and many structurally similar analytes, including its primary metabolite doxorubicinol (DOXol). Then the ability to accurately quantify mixtures of these two molecules based on their differential response to sensors with different surface‐charge properties is demonstrated. It is believed that this methodology is general and can be extended to a broad range of applications. A novel strategy is demonstrated to distinguish molecules with miniscule physicochemical differences by tuning the surface charge of an interface on which cross‐reactive aptamer probes are immobilized. As an exemplar, the method is applied to distinguish between doxorubicin and many structural analogs. This strategy eliminates the need for exquisitely selective aptamers by instead modulating the signal transduction to obtain specificity
doi_str_mv	10.1002/adfm.202208534
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Tom</creatorcontrib><title>Tailoring Electrode Surface Charge to Achieve Discrimination and Quantification of Chemically Similar Small Molecules with Electrochemical Aptamers</title><title>Advanced functional materials</title><addtitle>Adv Funct Mater</addtitle><description>Electrochemical biosensors based on structure‐switching aptamers offer many advantages because they can operate directly in complex samples and offer the potential to integrate with miniaturized electronics. Unfortunately, these biosensors often suffer from cross‐reactivity problems when measuring a target in samples containing other chemically similar molecules, such as precursors or metabolites. While some progress has been made in selecting highly specific aptamers, the discovery of these reagents remains slow and costly. 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subjects	Biosensors Chemical composition cross‐reactivity drug discrimination drug quantification electrochemical aptamer biosensors Hydroxyl groups Materials science Metabolites nanostructured electrodes Reagents Surface charge
title	Tailoring Electrode Surface Charge to Achieve Discrimination and Quantification of Chemically Similar Small Molecules with Electrochemical Aptamers
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