Functionalized Solid-State Nanopore Integrated in a Reusable Microfluidic Device for a Better Stability and Nanoparticle Detection.

Jean Roman Nathalie Jarroux Gilles Patriarche Olivier Français Juan Pelta Bruno Le Pioufle Laurent Bacri

ACS Appl Mater Interfaces

LAMBE, Université Evry, CNRS, CEA, Université Paris-Saclay, Evry F-91025, France.

Published: December 2017

Single nanopores enable efficient detection of biomolecules and particles, but require improved surface control of their supporting membranes.
A microfluidic system was developed to integrate a decorated membrane, simplifying the exchange of analytes and buffers.
This system significantly enhances the ionic conductance and longevity of the nanopore, demonstrating reliability through successful detection of gold nanorods and spherical proteins.

Electrical detection based on single nanopores is an efficient tool to detect biomolecules, particles and study their morphology. Nevertheless the surface of the solid-state membrane supporting the nanopore should be better controlled. Moreover, nanopore should be integrated within microfluidic architecture to facilitate control fluid exchanges. We built a reusable microfluidic system integrating a decorated membran, rendering the drain and refill of analytes and buffers easier. This process enhances strongly ionic conductance of the nanopore and its lifetime. We highlight the reliability of this device by detecting gold nanorods and spherical proteins.

Download full-text PDF	Source
http://dx.doi.org/10.1021/acsami.7b14717	DOI Listing

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