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American Chemical Society, Nano Letters, 8(12), p. 4117-4123, 2012

DOI: 10.1021/nl301655d

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Assessing Graphene Nanopores for Sequencing DNA

Journal article published in 2012 by David B. Wells, Maxim Belkin, Jeffrey Comer, Aleksei Aksimentiev ORCID
This paper is available in a repository.
This paper is available in a repository.

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Abstract

Using all-atom molecular dynamics and atomic-resolution Brownian dynamics, we simulate the translocation of single-stranded DNA through graphene nanopores and characterize the ionic current blockades produced by DNA nucleotides. We find that transport of single DNA strands through graphene nanopores may occur in single nucleotide steps. For certain pore geometries, hydrophobic interactions with the graphene membrane lead to a dramatic reduction in the conformational fluctuations of the nucleotides in the nanopores. Furthermore, we show that ionic current blockades produced by different DNA nucleotides are, in general, indicative of the nucleotide type, but very sensitive to the orientation of the nucleotides in the nanopore. Taken together, our simulations suggest that strand sequencing of DNA by measuring the ionic current blockades in graphene nanopores may be possible, given that the conformation of DNA nucleotides in the nanopore can be controlled through precise engineering of the nanopore surface.