Solid-State Nanopore Technologies for Nanopore-Based DNA Analysis

Healy, Ken; Schiedt, B.; Morrison, Alan P.

doi:10.2217/17435889.2.6.875

Cited by 199 publications

(164 citation statements)

References 106 publications

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“…Nowadays, synthetic membranes with assigned pore density and patterns are made commercially available. Moreover, by means of increasingly sophisticated growth methods, irradiation ͑Fleischer et nanofabrication techniques ͑Li et al, 2001;Storm et al, 2003;Dekker, 2007;Healy et al, 2007͒, the cross sections of membrane pores can be modulated along their axis. As a result, transport in artificial ion channels fabricated from asymmetric single pores of the most diverse geometries have become accessible to experiments ͑Siwy and Fuliń ski, 2004; Healy et al, 2007͒; see also Sec.…”

Section: Transport In Nanoporesmentioning

confidence: 99%

Artificial Brownian motors: Controlling transport on the nanoscale

2009

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In systems possessing spatial or dynamical symmetry breaking, Brownian motion combined with unbiased external input signals, deterministic and random alike, can assist directed motion of particles at submicron scales. In such cases, one speaks of "Brownian motors." In this review the constructive role of Brownian motion is exemplified for various physical and technological setups, which are inspired by the cellular molecular machinery: the working principles and characteristics of stylized devices are discussed to show how fluctuations, either thermal or extrinsic, can be used to control diffusive particle transport. Recent experimental demonstrations of this concept are surveyed with particular attention to transport in artificial, i.e., nonbiological, nanopores, lithographic tracks, and optical traps, where single-particle currents were first measured. Much emphasis is given to two-and three-dimensional devices containing many interacting particles of one or more species; for this class of artificial motors, noise rectification results also from the interplay of particle Brownian motion and geometric constraints. Recently, selective control and optimization of the transport of interacting colloidal particles and magnetic vortices have been successfully achieved, thus leading to the new generation of microfluidic and superconducting devices presented here. The field has recently been enriched with impressive experimental achievements in building artificial Brownian motor devices that even operate within the quantum domain by harvesting quantum Brownian motion. Sundry akin topics include activities aimed at noise-assisted shuttling other degrees of freedom such as charge, spin, or even heat and the assembly of chemical synthetic molecular motors. This review ends with a perspective for future pathways and potential new applications.

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Section: Transport In Nanoporesmentioning

confidence: 99%

Artificial Brownian motors: Controlling transport on the nanoscale

2009

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“…In nanopore analytics, single molecules are detected via the passage-induced changes in ionic current. [2][3][4][5][6][7] The approach can be implemented with protein 4,[8][9][10] and solid-state nanopores [10][11][12][13][14][15][16] and has gained popularity 17 due to its simplicity, the wide range of accessible analytes, 2,13,[18][19][20] and the prospect of DNA sequencing [21][22][23] based on nucleic acid sensing. [24][25][26][27] The translocation of protein and DNA strands through protein channels is also a biologically relevant process in pathogenic bacteria and human cells.…”

Section: Introductionmentioning

confidence: 99%

Disentangling Steric and Electrostatic Factors in Nanoscale Transport Through Confined Space

et al. 2013

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The voltage-driven passage of biological polymers through nanoscale pores is an analytically, technologically, and biologically relevant process. Despite various studies on homopolymer translocation there are still several open questions on the fundamental aspects of the pore transport. One of the most important unresolved issues revolves around the passage of biopolymers which vary in charge and volume along their sequence. Here we exploit an experimentally tunable system to disentangle and quantify electrostatic and steric factors. This new, fundamental framework facilitates the understanding of how complex biopolymers are transported through confined space and indicates how biopolymer translocation can be slowed down to enable future sensing methods.SYNOPSIS: The voltage-driven translocation of complex biopolymers through a protein nanopore is biophysically modeled to disentangle and quantify electrostatic and steric factors which can oppose electrophoretic movement.

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“…[1][2][3][4] The nanopore method uses the native electrical charge of nucleic acids or polypeptides present in an electrolyte solution to capture and slide the biopolymers through these pores. As this occurs it removes a portion of the solvent molecules present in the pore, giving rise to a time-dependent ionic current signal, which provides information on the biopolymers' dynamics, [5][6][7] length, 8,9 secondary structure, 10,11 and possible interactions with other biomolecules.…”

Section: Introductionmentioning

confidence: 99%

Synchronous optical and electrical detection of biomolecules traversing through solid-state nanopores

Soni

Singer

et al. 2010

Review of Scientific Instruments

101

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We present a novel method for integrating two single-molecule measurement modalities, namely, total internal reflection microscopy and electrical detection of biomolecules using nanopores. Demonstrated here is the electrical measurement of nanopore based biosensing performed simultaneously and in-sync with optical detection of analytes. This method makes it possible, for the first time, to visualize DNA and DNA-protein complexes translocating through a nanopore with high temporal resolution ͑1000 frames/s͒ and good signal to background. This paper describes a detailed experimental design of custom optics and data acquisition hardware to achieve simultaneous high resolution electrical and optical measurements on labeled biomolecules as they traverse through a ϳ4 nm synthetic pore. In conclusion, we discuss new directions and measurements, which this technique opens up.

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Solid-State Nanopore Technologies for Nanopore-Based DNA Analysis

Cited by 199 publications

References 106 publications

Artificial Brownian motors: Controlling transport on the nanoscale

Artificial Brownian motors: Controlling transport on the nanoscale

Disentangling Steric and Electrostatic Factors in Nanoscale Transport Through Confined Space

Synchronous optical and electrical detection of biomolecules traversing through solid-state nanopores

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