Thermally Switchable Nanogate Based on Polymer Phase Transition

Pauline J. Kolbeck; Dihia Benaoudia; Léa Chazot-Franguiadakis; Gwendoline Delecourt; Jérôme Mathé; Sha Li; Romeo Bonnet; Pascal Martin; Jan Lipfert; Anna Salvetti; Mordjane Boukhet; Véronique Bennevault; Jean Christophe Lacroix; Philippe Guégan; Fabien Montel

doi:10.1021/acs.nanolett.3c00438

Thermally Switchable Nanogate Based on Polymer Phase Transition

Pauline J. Kolbeck, Dihia Benaoudia, Léa Chazot-Franguiadakis, Gwendoline Delecourt, Jérôme Mathé, Sha Li, Romeo Bonnet, Pascal Martin, Jan Lipfert, Anna Salvetti, Mordjane Boukhet, Véronique Bennevault, Jean Christophe Lacroix, Philippe Guégan, Fabien Montel^*

^*Corresponding author for this work

Research output: Contribution to journal › Letter › Academic › peer-review

Abstract

Mimicking and extending the gating properties of biological pores is of paramount interest for the fabrication of membranes that could be used in filtration or drug processing. Here, we build a selective and switchable nanopore for macromolecular cargo transport. Our approach exploits polymer graftings within artificial nanopores to control the translocation of biomolecules. To measure transport at the scale of individual biomolecules, we use fluorescence microscopy with a zero-mode waveguide set up. We show that grafting polymers that exhibit a lower critical solution temperature creates a toggle switch between an open and closed state of the nanopore depending on the temperature. We demonstrate tight control over the transport of DNA and viral capsids with a sharp transition (∼1 °C) and present a simple physical model that predicts key features of this transition. Our approach provides the potential for controllable and responsive nanopores in a range of applications.

Original language	English
Pages (from-to)	4862-4869
Number of pages	8
Journal	Nano Letters
Volume	23
Issue number	11
DOIs	https://doi.org/10.1021/acs.nanolett.3c00438
Publication status	Published - 14 Jun 2023

Bibliographical note

Publisher Copyright:
© 2023 American Chemical Society.

Funding

The authors thank Jens Uwe-Sommer, Holger Merlitz, Cendrine Moskalenko, Martin Castelnovo, Saskia Brugère, Kassandra Gérard, Thomas Auger, Jean-Marc Di Meglio, Loic Auvray, Arthur Ermatov, Willem Vanderlinden, and Hermann Gaub for helpful comments and discussions. This work was supported by the Centre National de la Recherche Scientifique under the 80 Prime project ”NanoViro” and the ANR “Golden Gates”.

Funders	Funder number
Agence Nationale de la Recherche
CNRS Centre National de la Recherche Scientifique

Keywords

biomolecule filtration
coil-globule transition
nanopore
thermoresponsive polymer
zero-mode waveguide

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10.1021/acs.nanolett.3c00438

kolbeck-et-al-2023-thermally-switchable-nanogate-based-on-polymer-phase-transitionFinal published version, 3.22 MBLicence: Taverne

Cite this

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AU - Mathé, Jérôme

AU - Li, Sha

AU - Bonnet, Romeo

AU - Martin, Pascal

AU - Lipfert, Jan

AU - Salvetti, Anna

AU - Boukhet, Mordjane

AU - Bennevault, Véronique

AU - Lacroix, Jean Christophe

AU - Guégan, Philippe

AU - Montel, Fabien

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AB - Mimicking and extending the gating properties of biological pores is of paramount interest for the fabrication of membranes that could be used in filtration or drug processing. Here, we build a selective and switchable nanopore for macromolecular cargo transport. Our approach exploits polymer graftings within artificial nanopores to control the translocation of biomolecules. To measure transport at the scale of individual biomolecules, we use fluorescence microscopy with a zero-mode waveguide set up. We show that grafting polymers that exhibit a lower critical solution temperature creates a toggle switch between an open and closed state of the nanopore depending on the temperature. We demonstrate tight control over the transport of DNA and viral capsids with a sharp transition (∼1 °C) and present a simple physical model that predicts key features of this transition. Our approach provides the potential for controllable and responsive nanopores in a range of applications.

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Thermally Switchable Nanogate Based on Polymer Phase Transition

Abstract

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Keywords

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