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PPDiffuse: A Quantitative Prediction Tool for Diffusion of Charged Polymers in a Nanopore
Nanopore-based sensing of charged biopolymers is a powerful single-molecule method. In aconventional nanopore experiment, a single biological (proteinaceous) or solid-state nanopore perforates a thin membrane that is wetted by, and electrically isolates, two opposing reservoirs of electrolyte soluti...
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| Published in: | Journal of research of the National Institute of Standards and Technology 2020-06, Vol.125, p.125018, Article 125018 |
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| Main Author: | |
| Format: | Article |
| Language: | English |
| Citations: | Items that this one cites Items that cite this one |
| Online Access: | Get full text |
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| Summary: | Nanopore-based sensing of charged biopolymers is a powerful single-molecule
method. In aconventional nanopore experiment, a single biological (proteinaceous) or
solid-state nanopore perforates a thin membrane that is wetted by, and electrically
isolates, two opposing reservoirs of electrolyte solution. A potential is applied across
the membrane via external electronics coupled to the electrolyte reservoirs with
electrochemical electrodes, actuating the system. The electric field set up by the
applied potential in the nanopore and its immediate environment plays two roles:
supporting an ionic current through the nanopore, which reports on the properties of the
pore and its contents; and acting on analyte molecules to attract them to, and drive
them into, the nanopore. The presence of a large biopolymer in the pore modulates the
ionic current
(
). The duration of the ionic current modulation corresponds to the
length of time the polymer spends in the pore from capture to its ultimate escape,
either by retraction to the reservoir from which it was captured, or by translocation to
the opposite reservoir . The probabilities of retraction or translocation, or splitting
probabilities, and the corresponding distributions of escape times (
esc
), are
particularly sensitive to the size and charge of the analyte molecule and have been the
focus of much theoretical, computational, and experimental effort. An underlying
physical framework in which the distribution of escape times is modeled as a
first-passage time from a one-dimensional potential is quantitatively predictive for a
wide range of experiments. The complexity of this potential for the general case,
however, requires calculations to guide experimental design that can be tedious to
implement. PPDiffuse is intended to remove this burden from the nanopore research
community and enable convenient, rational design of nanopore experiments with complex
substrates such as polypeptides. |
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| ISSN: | 1044-677X 2165-7254 2165-7254 |
| DOI: | 10.6028/jres.125.018 |