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Spatially multiplexed single-molecule translocations through a nanopore at controlled speeds.

Samuel M LeitaoV NavikasH MiljkovicB DrakeS MarionG Pistoletti BlanchetKaikai ChenS F MayerUlrich Felix KeyserAlexandre KuhnGeorg Ernest FantnerAleksandra Radenović
Published in: Nature nanotechnology (2023)
In current nanopore-based label-free single-molecule sensing technologies, stochastic processes influence the selection of translocating molecule, translocation rate and translocation velocity. As a result, single-molecule translocations are challenging to control both spatially and temporally. Here we present a method using a glass nanopore mounted on a three-dimensional nanopositioner to spatially select molecules, deterministically tethered on a glass surface, for controlled translocations. By controlling the distance between the nanopore and glass surface, we can actively select the region of interest on the molecule and scan it a controlled number of times and at a controlled velocity. Decreasing the velocity and averaging thousands of consecutive readings of the same molecule increases the signal-to-noise ratio by two orders of magnitude compared with free translocations. We demonstrate the method's versatility by assessing DNA-protein complexes, DNA rulers and DNA gaps, achieving down to single-nucleotide gap detection.
Keyphrases
  • single molecule
  • label free
  • atomic force microscopy
  • living cells
  • blood flow
  • computed tomography
  • magnetic resonance imaging
  • single cell
  • air pollution
  • high resolution
  • real time pcr