Stretching DNA by electric field and flow field in microfluidic devices: An experimental validation to the devices designed with computer simulations

Lee, Cheng‐Han; Hsieh, Chia Chien

doi:10.1063/1.4790821

Cited by 8 publications

(7 citation statements)

References 42 publications

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“…13–17 Collapse can be brought about both by a.c. and d.c. electric fields. Furthermore, a series of prior observations is consistent with the notion that polyelectrolytes should collapse beyond a certain critical electric field strength.…”

Section: Introductionmentioning

confidence: 99%

Collapse of DNA under alternating electric fields

Zhou

Riehn

2015

Phys. Rev. E

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Recent studies have shown that double-stranded DNA can collapse in presence of a strong electric field. Here we provide an in-depth study of the collapse of DNA under weak confinement in microchannels as a function of buffer strength, driving frequency, applied electric field strength, and molecule size. We find that the critical electric field at which DNA molecules collapse (10s of kV/cm) is strongly dependent on driving frequency dependent (100 … 800 Hz) and molecular size (20 … 160 kbp), and weakly dependent on the ionic strength (8 … 60 mM). We argue that an apparent stretching at very high electric fields is an artifact of the finite frame time of video microscopy. PACS numbers: 87.14.gk, 36.20.Ey, 82.35.Lr, 82.35.Rs

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Section: Introductionmentioning

confidence: 99%

Collapse of DNA under alternating electric fields

Zhou

Riehn

2015

Phys. Rev. E

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“…Dynamic stretching utilizes the dynamic field or field gradient to unravel the DNA molecule in free solution and polymer-enhanced or porous medium. The field could be electric (DC and AC), 3-10 hydrodynamic, 2,[11][12][13][14] or combination of both. 15 DNA anchoring stretches tethered DNA by using external forces.…”

Section: Introductionmentioning

confidence: 99%

Simulation of single DNA molecule stretching and immobilization in a de-wetting two-phase flow over micropillar-patterned surface

Liao

Hu²,

Wang³

et al. 2013

Biomicrofluidics

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We investigate single DNA stretching dynamics in a de-wetting flow over micropillars using Brownian dynamics simulation. The Brownian dynamics simulation is coupled with transient flow field computation through a numerical particle tracking algorithm. The droplet formation on the top of the micropillar during the de-wetting process creates a flow pattern that allows DNA to stretch across the micropillars. It is found that DNA nanowire forms if DNA molecules could extend across the stagnation point inside the connecting water filament before its breakup. It also shows that DNA locates closer to the top wall of the micropillar has higher chance to enter the flow pattern of droplet formation and thus has higher chance to be stretched across the micropillars. Our simulation tool has the potential to become a design tool for DNA manipulation in complex biomicrofluidic devices.

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“…A more recent study using single-molecule fluorescence microscopy, however, showed that the bacterial phage T4 DNA becomes significantly more compact under a DC electric field and becomes a globule at a field strength of 250 V/cm or 2.5 × 10 –2 mV/nm . Similar observation was made in microfluidic experiments . The collapse of λ-DNA was also observed under AC electric fields at sufficiently high strength using fluorescence microscopy, , and the authors suggested that the earlier observation of DNA stretching was due to an artifact of video microscopy.…”

Section: Introductionmentioning

confidence: 67%

“…Comparison to Experiments and Theories of PE Chain Conformations in Electric Field. Single-molecule fluorescence microscopy 26 and microfluidic experiments 27 demonstrated that DNAs become compact under large electric fields. The backbone bending showed by our simulations of the 5-mer and 20-mer chitosan chains is consistent with these experiments.…”

Section: Resultsmentioning

confidence: 99%

“…26 Similar observation was made in microfluidic experiments. 27 The collapse of λ-DNA was also observed under AC electric fields at sufficiently high strength using fluorescence microscopy, 28,29 and the authors suggested that the earlier observation of DNA stretching was due to an artifact of video microscopy. However, the authors also noted that when the field strength was further increased above 1220 V/cm or 0.122 mV/nm, the DNA appeared to elongate in the direction of electric field.…”

Section: Introductionmentioning

confidence: 95%

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Polyelectrolyte in Electric Field: Disparate Conformational Behavior along an Aminopolysaccharide Chain

et al. 2020

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Electrical signals are increasingly used in fabrication of hydrogels (e.g., based on aminopolysaccharide chitosan) to guide the emergence of complex and anisotropic structure; however, how an imposed electric field affects the polymer chain conformation and orientation during the self-assembly process is not understood. Here, we applied nonequilibrium all-atom molecular dynamics simulations to explore the response of a charged chitosan chain comprising 5-or 20-monomer units to a constant uniform electric field in water and salt solution. While no conformational or orientational response was observed for the polyelectrolyte (PE) chains under the small electric fields within the simulation time, a field strength of 400 mV/nm induced significant changes. In water, a 5-mer chain is found to be slightly bent and oriented parallel to the field; however, surprisingly, a 20-mer chain displays candy-cane-like conformations whereby one half of the chain is collapsed and flexible, while the other half of the chain is stretched along the electric field. In salt solution, the disparity remains between the two halves of the 20-mer chain, although the backbone is extremely flexible with multiple bent regions and non-native conformations occur near the chain center in one of the three trajectories. The disparate conformational response along the polyelectrolyte chain may be attributed to the balancing forces between chain dynamics, electric polarization, counterion binding, and hydrodynamic pressure as well as friction. These findings reconcile existing experiments and theoretical studies and represent an important step toward understanding the complex roles of electric field and salt in controlling the structure and properties of soft matter.

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Stretching DNA by electric field and flow field in microfluidic devices: An experimental validation to the devices designed with computer simulations

Cited by 8 publications

References 42 publications

Collapse of DNA under alternating electric fields

Collapse of DNA under alternating electric fields

Simulation of single DNA molecule stretching and immobilization in a de-wetting two-phase flow over micropillar-patterned surface

Polyelectrolyte in Electric Field: Disparate Conformational Behavior along an Aminopolysaccharide Chain

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