Entropic Trapping and Escape of Long DNA Molecules at Submicron Size Constriction

Han, Jongyoon; Turner, Stephen W.; Craighead, Harold G.

doi:10.1103/physrevlett.83.1688

Cited by 382 publications

(467 citation statements)

References 12 publications

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“…These results are consistent with observations and in qualitative agreement with those of other simulation studies. 5,6,8 Conclusion CGH-MD showed comparatively good performance in simulating a typical polymer solution, ion distribution in a nanotube, and DNA electrophoresis in polymer solutions and in a nanofluidic device at significantly lower computing cost than those of more rigorous methods. As a computationally efficient explicitsolvent method, CGH-MD is potentially useful for simulating systems of large number of water particles to complement more rigorous methods.…”

Section: Ion Distribution Patternmentioning

confidence: 95%

“…[8][9][10]58,59 This device is schematically shown in Figure 7. The lengths of one repeating unit of the channel along the x-direction and the ydirection are L x 5 100 r and L y 5 50 r (r is comparable to the persistence length of the DNA chain, 50 nm, or about 150 bp.…”

Section: Ion Distribution Patternmentioning

confidence: 99%

“…These results are consistent with observations and are comparable to those of other simulation studies. 5,6,[8][9][10] The mobility of DNA chains of lengths N 5 100 and 50 as a function of the electric field is shown in Figure 10. The computed mobility of these DNA chains increases with increasing electric field and saturates at higher electric field.…”

Section: Ion Distribution Patternmentioning

confidence: 99%

“…6,7 These simulation studies have yielded good agreement with observations. [8][9][10][11] However, some of the explicit solvent effects such as nonuniformly distributed electrostatic interactions, hydrophobic effects, and bound and sequestered water molecules 12,13 cannot be fully considered without using explicit solvent methods. As these effects play important roles in electrophoresis and other processes, it is highly desired to explore explicit solvent methods in practical applications.…”

Section: Introductionmentioning

confidence: 99%

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Simulation of DNA electrophoresis in systems of large number of solvent particles by coarse‐grained hybrid molecular dynamics approach

Wang

Liu

et al. 2008

J Comput Chem

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Simulation of DNA electrophoresis facilitates the design of DNA separation devices. Various methods have been explored for simulating DNA electrophoresis and other processes using implicit and explicit solvent models. Explicit solvent models are highly desired but their applications may be limited by high computing cost in simulating large number of solvent particles. In this work, a coarse-grained hybrid molecular dynamics (CGH-MD) approach was introduced for simulating DNA electrophoresis in explicit solvent of large number of solvent particles. CGH-MD was tested in the simulation of a polymer solution and computation of nonuniform charge distribution in a cylindrical nanotube, which shows good agreement with observations and those of more rigorous computational methods at a significantly lower computing cost than other explicit-solvent methods. CGH-MD was further applied to the simulation of DNA electrophoresis in a polymer solution and in a well-studied nanofluidic device. Simulation results are consistent with observations and reported simulation results, suggesting that CGH-MD is potentially useful for studying electrophoresis of macromolecules and assemblies in nanofluidic, microfluidic, and microstructure array systems that involve extremely large number of solvent particles, nonuniformly distributed electrostatic interactions, bound and sequestered water molecules.

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Section: Ion Distribution Patternmentioning

confidence: 95%

Section: Ion Distribution Patternmentioning

confidence: 99%

Section: Ion Distribution Patternmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Simulation of DNA electrophoresis in systems of large number of solvent particles by coarse‐grained hybrid molecular dynamics approach

Wang

Liu

et al. 2008

J Comput Chem

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“…Inside these channels, the DNA molecules are stretched and prevented from exiting due to the entropic barrier provided by the narrower channels. 20,21 The buffer can subsequently be exchanged through the intersecting array of nanochannels in the other direction. The exchange time of the buffer is characterised by monitoring the current through the channels fol-lowing an increase in concentration of salt.…”

Section: Introductionmentioning

confidence: 99%

A nanofluidic device for single molecule studies with in situ control of environmental solution conditions

et al. 2013

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We report an approach to study the in-situ conformational response of single biomolecules such as DNA to a change in environmental solution conditions. These conditions are, for instance, the composition of the buffer or the presence of protein. For this purpose, we designed and fabricated a nanofluidic device featuring two arrays of parallel nanochannels in a perpendicular configuration. The cross-sections of the channels are rectangular with a diameter down to 175 nm. The lab-on-chip devices were made of polydimethylsiloxane (PDMS) cast on a high quality master stamp, obtained by proton beam writing and UV lithography. Biomolecules can be inserted into the device through the array of channels in one direction, whereas the buffer can be exchanged through the intersecting array of channels in the other direction. A buffer exchange time inside the grid of nanochannels of less than one second is measured by monitoring the conductivity of solutions of salt. The exchange time of protein is typically a few seconds, as determined by imaging of the influx of fluorescence labelled protamine. We demonstrate the functionality of the device by investigating the compaction of DNA by protamine and unpacking of pre-compacted DNA through an increase in concentration of salt.

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Theory of DNA electrophoresis: A look at some current challenges

et al. 2000

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Although electrophoresis is one of the basic methods of the modern molecular biology laboratory, new ideas are being suggested at an accelerated rate, in large part because of the pressing demands of the biomedical community. Although we now have, at least for some methods, a fairly good theoretical understanding of the physical mechanisms that lead to the observed peak spacings, widths and shapes, this knowledge is often too qualitative to be used to guide further technical developments and improvements. In this article, we review some selected elements of the current state of our theoretical ignorance, focusing mostly on DNA electrophoresis, and we offer several suggestions for further theoretical investigations.

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Entropic Trapping and Escape of Long DNA Molecules at Submicron Size Constriction

Cited by 382 publications

References 12 publications

Simulation of DNA electrophoresis in systems of large number of solvent particles by coarse‐grained hybrid molecular dynamics approach

Simulation of DNA electrophoresis in systems of large number of solvent particles by coarse‐grained hybrid molecular dynamics approach

A nanofluidic device for single molecule studies with in situ control of environmental solution conditions

Theory of DNA electrophoresis: A look at some current challenges

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