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Main Authors: Zhao, Haijie, Liu, Zhe, Li, Jinghui, Yin, Tanji, Qin, Wei
Format: Artículo científico
Language:en
Published: Talanta 2026
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Online Access:https://pubmed.ncbi.nlm.nih.gov/40460683/
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author Zhao, Haijie
Liu, Zhe
Li, Jinghui
Yin, Tanji
Qin, Wei
author_facet Zhao, Haijie
Liu, Zhe
Li, Jinghui
Yin, Tanji
Qin, Wei
Zhao, Haijie
Liu, Zhe
Li, Jinghui
Yin, Tanji
Qin, Wei
collection PubMed - marine biology
contents Selection of azaspiracid-1 aptamers for potentiometric aptasensing. Zhao, Haijie Liu, Zhe Li, Jinghui Yin, Tanji Qin, Wei Aptamers, Nucleotide Marine Toxins Potentiometry Biosensing Techniques Spiro Compounds SELEX Aptamer Technique Graphite Limit of Detection Electrodes Polyether Toxins Azaspiracids (AZAs) are polyether marine toxins from shellfish that cause risks to human health. The bioreceptors for biosensing of AZAs are limited to antibodies. The selection of aptamers that specifically bind to AZAs with high affinities is highly required. In this work, aptamers with high affinities and specificities towards AZA1, which is the most abundant toxin in the AZAs group, have been selected via the magnetic reduced graphene oxide-based systematic evolution of ligands by exponential enrichment (MRGO-SELEX). A truncated aptamer (Apt-23b48) with a dissociation constant (K) of 29.8 ± 8.3 nM has been chosen as a bioreceptor for fabricating DNA self-assembled nanostructure-based magnetic beads via a hybridization chain reaction. A polycation-sensitive thin-membrane electrode using protamine as an indicator has been employed to detect the surface charge change of the DNA self-assembled nanostructure-based magnetic beads induced by the binding interaction between the selected aptamer and AZA1. The proposed potentiometric aptasensing platform shows a linear range of 10-250 pM with a detection limit of 8.5 pM, and has been successfully applied to the detection of AZA1 in spike seawater samples.
format Artículo científico
id pubmed_40460683
institution PubMed
language en
publishDate 2026
publisher Talanta
record_format pubmed
spellingShingle Selection of azaspiracid-1 aptamers for potentiometric aptasensing.
Zhao, Haijie
Liu, Zhe
Li, Jinghui
Yin, Tanji
Qin, Wei
Aptamers, Nucleotide
Marine Toxins
Potentiometry
Biosensing Techniques
Spiro Compounds
SELEX Aptamer Technique
Graphite
Limit of Detection
Electrodes
Polyether Toxins
Selection of azaspiracid-1 aptamers for potentiometric aptasensing. Zhao, Haijie Liu, Zhe Li, Jinghui Yin, Tanji Qin, Wei Aptamers, Nucleotide Marine Toxins Potentiometry Biosensing Techniques Spiro Compounds SELEX Aptamer Technique Graphite Limit of Detection Electrodes Polyether Toxins Azaspiracids (AZAs) are polyether marine toxins from shellfish that cause risks to human health. The bioreceptors for biosensing of AZAs are limited to antibodies. The selection of aptamers that specifically bind to AZAs with high affinities is highly required. In this work, aptamers with high affinities and specificities towards AZA1, which is the most abundant toxin in the AZAs group, have been selected via the magnetic reduced graphene oxide-based systematic evolution of ligands by exponential enrichment (MRGO-SELEX). A truncated aptamer (Apt-23b48) with a dissociation constant (K) of 29.8 ± 8.3 nM has been chosen as a bioreceptor for fabricating DNA self-assembled nanostructure-based magnetic beads via a hybridization chain reaction. A polycation-sensitive thin-membrane electrode using protamine as an indicator has been employed to detect the surface charge change of the DNA self-assembled nanostructure-based magnetic beads induced by the binding interaction between the selected aptamer and AZA1. The proposed potentiometric aptasensing platform shows a linear range of 10-250 pM with a detection limit of 8.5 pM, and has been successfully applied to the detection of AZA1 in spike seawater samples.
title Selection of azaspiracid-1 aptamers for potentiometric aptasensing.
topic Aptamers, Nucleotide
Marine Toxins
Potentiometry
Biosensing Techniques
Spiro Compounds
SELEX Aptamer Technique
Graphite
Limit of Detection
Electrodes
Polyether Toxins
url https://pubmed.ncbi.nlm.nih.gov/40460683/