Automated Fabrication of 2‐nm Solid‐State Nanopores for Nucleic Acid Analysis

Briggs, Kyle; Kwok, Harold; Tabard‐Cossa, Vincent

doi:10.1002/smll.201303602

Cited by 151 publications

(162 citation statements)

References 44 publications

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“…In addition to the The same phenomena also showed in addition to experimental studies, the entropic barrier also discussed theoretically based on different parameters such as effect of solvent, nanopore size and adsorption [51][52][53]. For our study, an entropic barrier applies to 50-bp DNA molecules to complete a translocation that a threshold voltage above 200 mV would be necessary to drive the DNA through the PC nanopore [41,54]. Figure 8A).…”

Section: …(Ii)mentioning

confidence: 65%

Nanopore detection of double stranded DNA using a track-etched polycarbonate membrane

Keçeci

San

Kaya

2015

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Section: …(Ii)mentioning

confidence: 65%

Nanopore detection of double stranded DNA using a track-etched polycarbonate membrane

Keçeci

San

Kaya

2015

Talanta

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“…42 At an applied potential of 400 mV, the mean residence time of dsDNA in the pore is ≈440 μ s, more than an order of magnitude longer than the characteristic time constant of the system ( τ = 10 μ s; B = 100 kHz). Both algorithms produce two distinct peaks in the blockade depth histogram (〈 i 〉/〈 i 0 〉 = 0.070 ± 0.001 and 0.488 ± 0.004).…”

Section: Resultsmentioning

confidence: 99%

MOSAIC: A Modular Single-Molecule Analysis Interface for Decoding Multistate Nanopore Data

et al. 2016

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Biological and solid-state nanometer-scale pores are the basis for numerous emerging analytical technologies for use in precision medicine. We developed Modular Single-Molecule Analysis Interface (MOSAIC), an open source analysis software that improves the accuracy and throughput of nanopore-based measurements. Two key algorithms are implemented: ADEPT, which uses a physical model of the nanopore system to characterize short-lived events that do not reach their steady-state current, and CUSUM+, a version of the cumulative sum statistical method optimized for longer events that do. We show that ADEPT detects previously unreported conductance states that occur as double-stranded DNA translocates through a 2.4 nm solid-state nanopore and reveals new interactions between short single-stranded DNA and the vestibule of a biological pore. These findings demonstrate the utility of MOSAIC and the ADEPT algorithm, and offer a new tool that can improve the analysis of nanopore-based measurements.

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“…For example, modifications to solid-state nanopores have included adjusting the nanopore diameter to increase friction [58][59][60], modulating the nanopore surface charge with laser light [61], functionalizing the nanopore with hydrogen-bonding molecules [62] or coating it with a lipid bilayer [63], and altering the properties of a pH-responsive organic nanopore coating [64]. Additional methods have been proposed, including local heating of a gold layer surrounding the nanopore to stretch the DNA [65,66] and ratcheting of nucleotide strands through introduction of a third electrode [67,68].…”

Section: The Nanoporementioning

confidence: 99%

“…Note that this nanopore size is chosen to ensure single-file passage of dsDNA, while at the same time avoiding translocations in the friction-dominated regime [58,60]. As shown in Figure 2.2, agarose slows down some of the DNA molecules substantially, by as much as 3 orders of magnitude (from tens of µs to tens of ms), while other DNA molecules pass through the gel with a dwell time similar to that observed in a bare nanopore of similar dimensions.…”

Section: Nanopores Interfaced With Agarose Gelmentioning

confidence: 99%

Interfacing solid‐state nanopores with gel media to slow DNA translocations

et al. 2015

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We demonstrate the ability to slow DNA translocations through solid‐state nanopores by interfacing the trans side of the membrane with gel media. In this work, we focus on two reptation regimes: when the DNA molecule is flexible on the length scale of a gel pore, and when the DNA behaves as persistent segments in tight gel pores. The first regime is investigated using agarose gels, which produce a very wide distribution of translocation times for 5 kbp dsDNA fragments, spanning over three orders of magnitude. The second regime is attained with polyacrylamide gels, which can maintain a tight spread and produce a shift in the distribution of the translocation times by an order of magnitude for 100 bp dsDNA fragments, if intermolecular crowding on the trans side is avoided. While previous approaches have proven successful at slowing DNA passage, they have generally been detrimental to the S/N, capture rate, or experimental simplicity. These results establish that by controlling the regime of DNA movement exiting a nanopore interfaced with a gel medium, it is possible to address the issue of rapid biomolecule translocations through nanopores—presently one of the largest hurdles facing nanopore‐based analysis—without affecting the signal quality or capture efficiency.

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Automated Fabrication of 2‐nm Solid‐State Nanopores for Nucleic Acid Analysis

Cited by 151 publications

References 44 publications

Nanopore detection of double stranded DNA using a track-etched polycarbonate membrane

Nanopore detection of double stranded DNA using a track-etched polycarbonate membrane

MOSAIC: A Modular Single-Molecule Analysis Interface for Decoding Multistate Nanopore Data

Interfacing solid‐state nanopores with gel media to slow DNA translocations

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