A Universal Strategy for Aptamer‐Based Nanopore Sensing through Host–Guest Interactions inside α‐Hemolysin

“…An alternative approach to using electrophoretic approaches to increase the capture volume is to use the tried and trusted approach of magnetic capture.Thus far, such strategies have been used to preconcentrate the analyte [32] prior to the nanopore measurement instead of using magnetic nanoparticles to bring the analyte to the pores.…”

Section: Rapid Near-field Measurementsmentioning

confidence: 99%

Single‐Molecule Sensors: Challenges and Opportunities for Quantitative Analysis

Gooding¹,

2016

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Measurement science has been converging to smaller and smaller samples, such that it is now possible to detect single molecules. This Review focuses on the next generation of analytical tools that combine single-molecule detection with the ability to measure many single molecules simultaneously and/or process larger and more complex samples. Such single-molecule sensors constitute a new type of quantitative analytical tool, as they perform analysis by molecular counting and thus potentially capture the heterogeneity of the sample. This Review outlines the advantages and potential of these new, quantitative single-molecule sensors, the measurement challenges in making single-molecule devices suitable for analysis, the inspiration biology provides for overcoming these challenges, and some of the solutions currently being explored.

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“…In this approach, the phenanthroline coordinating a copper(II) ion has been employed as a host which can coordinate amino acids, and thus achieving the discrimination of the enantiomers of underivatized tyrosine. More recently, a versatile strategy was developed based on host‐guest interactions which allows for detecting a wide range of analytes by employing different aptamers (Figure a) . An aptamer is first hybridized with a DNA probe which is modified with a ferrocene⊂cucurbit[7]uril (Fc⊂CB[7]) complex.…”

Section: Host–guest Interactions Within Protein Nanoporesmentioning

confidence: 99%

Single‐Molecule Sensing with Nanopore Confinement: From Chemical Reactions to Biological Interactions

Yao

Ying

Gao

et al. 2018

Chemistry A European J

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The nanopore can generate an electrochemical confinement for single-molecule sensing that help understand the fundamental chemical principle in nanoscale dimensions. By observing the generated ionic current, individual bond-making and bond-breaking steps, single biomolecule dynamic conformational changes and electron transfer processes that occur within pore can be monitored with high temporal and current resolution. These single-molecule studies in nanopore confinement are revealing information about the fundamental chemical and biological processes that cannot be extracted from ensemble measurements. In this Concept article, we introduce and discuss the electrochemical confinement effects on single-molecule covalent reactions, conformational dynamics of individual molecules and host-guest interactions in protein nanopores. Then, we extend the concept of nanopore confinement effects to confine electrochemical redox reactions in solid-state nanopores for developing new sensing mechanisms.

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A Universal Strategy for Aptamer‐Based Nanopore Sensing through Host–Guest Interactions inside α‐Hemolysin

Cited by 98 publications

References 34 publications

Nanopore Sensing

Nanopore Sensing

Single‐Molecule Sensors: Challenges and Opportunities for Quantitative Analysis

Single‐Molecule Sensing with Nanopore Confinement: From Chemical Reactions to Biological Interactions

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