Versatile cyclodextrin nanotube synthesis with functional anchors for efficient ion channel formation: design, characterization and ion conductance

Mamad-Hemouch, Hajar; Bacri, Laurent; Huin, Cécile; Przybylski, Cédric; Thiébot, Bénédicte; Patriarche, G.; Jarroux, Nathalie; Pelta, Juan

doi:10.1039/c8nr02623h

Cited by 12 publications

(7 citation statements)

References 130 publications

(134 reference statements)

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Section:  D Nanochannel-structured Membranesmentioning

confidence: 95%

“…CDNTs with controlled lengths, diameters, and number of cyclodextrins and selective chemical modifications were used as ion nanochannels and inserted into lipid bilayers to transport ions. [ 107,108 ] As shown by the I – V curves of the CDNTs (Figure 4C), their conductance was found to be 0.077 ± 0.005 nS. [ 108 ] In addition, a COF with oligo(ethylene oxide) chains exhibited enhanced lithium‐ion transport through a vehicle mechanism in contrast to a COF without oligo(ethylene oxide) chains on the ordered 1D nanochannel walls (Figure 4D), [ 109 ] which provides new inspiration for developing ion conductors.…”

Section: Nanochannel‐structured Membranesmentioning

confidence: 99%

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Rational ion transport management mediated through membrane structures

et al. 2021

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Unique membrane structures endow membranes with controlled ion transport properties in both biological and artificial systems, and they have shown broad application prospects from industrial production to biological interfaces. Herein, current advances in nanochannel‐structured membranes for manipulating ion transport are reviewed from the perspective of membrane structures. First, the controllability of ion transport through ion selectivity, ion gating, ion rectification, and ion storage is introduced. Second, nanochannel‐structured membranes are highlighted according to the nanochannel dimensions, including single‐dimensional nanochannels (i.e., 1D, 2D, and 3D) functioning by the controllable geometrical parameters of 1D nanochannels, the adjustable interlayer spacing of 2D nanochannels, and the interconnected ion diffusion pathways of 3D nanochannels, and mixed‐dimensional nanochannels (i.e., 1D/1D, 1D/2D, 1D/3D, 2D/2D, 2D/3D, and 3D/3D) tuned through asymmetric factors (e.g., components, geometric parameters, and interface properties). Then, ultrathin membranes with short ion transport distances and sandwich‐like membranes with more delicate nanochannels and combination structures are reviewed, and stimulus‐responsive nanochannels are discussed. Construction methods for nanochannel‐structured membranes are briefly introduced, and a variety of applications of these membranes are summarized. Finally, future perspectives to developing nanochannel‐structured membranes with unique structures (e.g., combinations of external macro/micro/nanostructures and the internal nanochannel arrangement) for mediating ion transport are presented.

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Section:  D Nanochannel-structured Membranesmentioning

confidence: 95%

Section: Nanochannel‐structured Membranesmentioning

confidence: 99%

Rational ion transport management mediated through membrane structures

et al. 2021

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“…It has been shown that cyclodextrin-based channels can insert into biological membranes and exhibit ion transport activity without causing any cytotoxicity . Alpha, beta, and gamma cyclodextrins are all capable of forming ion channels, with the current through the channel increasing linearly with externally applied voltage. , A detailed picture of the ion transport mechanism through these cyclodextrin channels and how the alpha, beta, and gamma cyclodextrin channels respond to permeation of different ions, however, are not understood.…”

Section: Introductionmentioning

confidence: 99%

Ion Selectivity and Permeation Mechanism in a Cyclodextrin-Based Channel

Musunuru

Padhi

2021

J. Phys. Chem. B

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Synthetic ion channels are a promising technology in the medical and materials sciences because of their ability to conduct ions. Channels based on cyclodextrin, a cyclic oligomer of glucose, are of particular interest because of their nontoxicity and biocompatibility. Using molecular dynamics-based free energy calculations, this study identifies cyclodextrin channel types that are best suited to serve as synthetic ion channels. Free energy profiles show that the connectivity in the channel determines whether the channel is cation-selective or anion-selective. Furthermore, the energy barrier for ion transport is governed by the number of glucose molecules making up the cyclodextrin units of the channel. A detailed mechanism is proposed for ion transport through these channels. Findings from this study will aid in designing cyclodextrin-based channels that could be either cation-selective or anion-selective, by modifying the linkages of the channel or the number of glucose molecules in the cyclodextrin rings.

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“…At first, the protein channels were the main sensors used to perform numerous studies 7-9 . Thanks to material science, chemistry, nanoscience and molecular biology, it is now possible to design and manufacture new classes of nanopores: solid-state sensors 10,11 , DNA origami nanopores 12,13 , carbon 14,15 or cyclodextrin nanotubes [16][17][18] , hybrid nanopores 19-21 and glass 22,23 or quartz nanopores 24 with DNA aptamers 25 . The increased interest in nanopore research has been mainly associated to the ultra-fast DNA sequencing challenge, recently achieved by Oxford Nanopore Technology [26][27][28][29] .…”

mentioning

confidence: 99%

“…Nanopore technology has become a sensitive, selective, low cost, label-free, real-time, and transportable tool for sensing a wide variety of molecules, including ions, polymers, polyelectrolytes, viruses, ligand–molecule complexes, and biomolecules. It allows for the analysis of transport properties, conformations, folding, size, sequence, or chemical modifications. − At first, the protein channels were the main sensors used to perform numerous studies. − Thanks to material science, chemistry, nanoscience, and molecular biology, it is now possible to design and manufacture new classes of nanopores: solid-state sensors, , DNA origami nanopores, , carbon , or cyclodextrin nanotubes, − hybrid nanopores, − and glass , or quartz nanopores with DNA aptamers . The increased interest in nanopore research has been mainly associated with the ultrafast DNA sequencing challenge, recently achieved by Oxford Nanopore Technology. − The objectives at the horizon of this field comprise proteomic sequencing, ,− biomarker detection (of micro-RNAs as well as infinitesimal peptides and proteins quantities), and single-molecule mass spectrometry. ,− Up to now, the best sensitivity for biotechnological or heath applications is obtained through biological channels.…”

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confidence: 99%

Aerolysin, a Powerful Protein Sensor for Fundamental Studies and Development of Upcoming Applications

et al. 2019

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Nanopore electrical approach is a breakthrough in single molecular level detection of particles as small as ions, and complex as biomolecules. This technique can be used for molecule analysis, and characterization as well as for the understanding of confined medium dynamics in chemical or biological reactions. Altogether, the information obtained from these kinds of experiments will allow to address challenges in a variety of biological fields. The sensing, design and manufacture of nanopores is crucial to obtain these objectives. For some time now, aerolysin, a pore forming toxin, and its mutants have shown high potential in real time analytical chemistry, size discrimination of neutral polymers, oligosaccharides, oligonucleotides and peptides at monomeric resolution, sequence identification, chemical modification on DNA, potential biomarkers detection and protein folding analysis. This review focuses, on the results obtained with aerolysin nanopores on the fields of chemistry, biology, physics and biotechnology. We discuss and compare as well the results obtained with other protein channel sensors.For the past two decades, the number of papers and the citations in the field of nanopores has increased exponentially. Nanopore technology has become a sensitive, selective, low cost, label-free, real-time and transportable tool for sensing a wide variety of molecules, including ions, polymers, polyelectrolytes, viruses, ligand-molecule complexes and biomolecules. It allows for the analysis of transport properties, conformations, folding, size, sequence or chemical modifications 1-6 . At first, the protein channels were the main sensors used to perform numerous studies 7-9 . Thanks to material science, chemistry, nanoscience and molecular biology, it is now possible to design and manufacture new classes of nanopores: solid-state sensors 10,11 , DNA origami nanopores 12,13 , carbon 14,15 or cyclodextrin nanotubes [16][17][18] , hybrid nanopores 19-21 and glass 22,23 or quartz nanopores 24 with DNA aptamers 25 . The increased interest in nanopore research has been mainly associated to the ultra-fast DNA sequencing challenge, recently achieved by Oxford Nanopore Technology [26][27][28][29] . The objectives at the horizon of this field comprise of proteomic sequencing 6,30-33 , biomarker detection (of micro-RNAs 34 as well as infinitesimal peptides and proteins quantities) and single-molecule mass spectrometry 32,[35][36][37][38][39][40][41][42] . Up to now, the best sensitivity for biotechnological or heath applications is obtained through biological channels.A member of the pore-forming toxin (PFTs) 43 family, aerolysin is a beta structure toxin that has recently been at the center of extensive fundamental studies and some biotechnology applications 32,38,39,[44][45][46][47][48] . In this review we first introduce the molecular mechanism of channel formation, from soluble inactive monomers to a functional pore into a lipid membrane (figure 1); we delve into the structure of monomeric and heptameric aerolysin along with...

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Versatile cyclodextrin nanotube synthesis with functional anchors for efficient ion channel formation: design, characterization and ion conductance

Cited by 12 publications

References 130 publications

Rational ion transport management mediated through membrane structures

Rational ion transport management mediated through membrane structures

Ion Selectivity and Permeation Mechanism in a Cyclodextrin-Based Channel

Aerolysin, a Powerful Protein Sensor for Fundamental Studies and Development of Upcoming Applications

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