Simulation of electrophoretic stretching of DNA in a microcontraction using an obstacle array for conformational preconditioning

Trahan, Daniel W.; Doyle, Patrick S.

doi:10.1063/1.3055275

Cited by 20 publications

(16 citation statements)

References 57 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A common approach to alleviate this problem is to "pre-condition" DNA so they adopt conformations more suitable for being stretched. Various conformation preconditioning strategies found in the literature include pre-shearing DNA, 19 passing DNA through a gel matrix 7 or obstacle arrays, 15,20 and exposing DNA to an oscillating extensional flow. 19 However, these methods are either troublesome to apply or having vary limited benefit.…”

Section: Introductionmentioning

confidence: 99%

“…Earlier simulations with the same assumptions yielded results in good agreement with the experimental data at small to moderate electric field (or Deborah number (De)). 20,23,26 With the help of computer simulations, we developed a new pre-conditioning approach called "pre-stretching." 1 The approach uses an expansion in front of the microcontraction to generate an electric field gradient to pre-stretch DNA.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

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

Lee

Hsieh

2013

Biomicrofluidics

View full text Add to dashboard Cite

We examined the performance of three microfluidic devices for stretching DNA. The first device is a microchannel with a contraction, and the remaining two are the modifications to the first. The modified designs were made with the help of computer simulations [C. C. Hsieh and T. H. Lin, Biomicrofluidics 5(4), 044106 (2011) and C. C. Hsieh, T. H. Lin, and C. D. Huang, Biomicrofluidics 6, 044105 (2012)] and they were optimized for operating with electric field. In our experiments, we first used DC electric field to stretch DNA. However, the experimental results were not even in qualitative agreement with our simulations. More detailed investigation revealed that DNA molecules adopt a globular conformation in high DC field and therefore become more difficult to stretch. Owing to the similarity between flow field and electric field, we turned to use flow field to stretch DNA with the same devices. The evolution patterns of DNA conformation in flow field were found qualitatively the same as our prediction based on electric field. We analyzed the maximum values, the evolution and the distributions of DNA extension at different Deborah number in each device. We found that the shear and the hydrodynamic interaction have significant influence on the performance of the devices. V C 2013 American Institute of Physics.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

Lee

Hsieh

2013

Biomicrofluidics

View full text Add to dashboard Cite

show abstract

“…In addition to the simulation results, the dotted line is given to indicate the maximum possible DNA extension. It is estimated using a dumbbell model at a homogeneous field (infinite strain), 43 and the result is independent of the molecular weight of DNA. From Fig.…”

Section: Resultsmentioning

confidence: 99%

“…46 Moreover, electric field gradient at the expansion and contraction of the proposed devices might induce dielectrophoresis effect that could polarize DNA and result in unpredictable influence to DNA behavior. 43,47 To summarize, in order to have an affordable but useful prediction, we use coarsed-grained models that hopefully preserve the most important physics but only leave away the unimportant ones. From the reasonable agreement between the previous experiments 28,33 and simulations, 26,48 the FEM-BD simulations used here should be capable to catch the behavior of the DNA in microfluidic devices.…”

Section: Resultsmentioning

confidence: 99%

Simulation guided design of a microfluidic device for electrophoretic stretching of DNA

2012

View full text Add to dashboard Cite

We have used Brownian dynamics-finite element method (BD-FEM) to guide the optimization of a microfluidic device designed to stretch DNA for gene mapping. The original design was proposed in our previous study [C. C. Hsieh and T. H. Lin, Biomicrofluidics 5(4), 044106 (2011)] for demonstrating a new pre-conditioning strategy to facilitate DNA stretching through a microcontraction using electrophoresis. In this study, we examine the efficiency of the original device for stretching DNA with different sizes ranging from 48.5 kbp (k-DNA) to 166 kbp (T4-DNA). The efficiency of the device is found to deteriorate with increasing DNA molecular weight. The cause of the efficiency loss is determined by BD-FEM, and a modified design is proposed by drawing an analogy between an electric field and a potential flow. The modified device does not only regain the efficiency for stretching large DNA but also outperforms the original device for stretching small DNA. V C 2012 American Institute of Physics. [http://dx

show abstract

“…5,6 Typical methods of stretching biopolymers include applying a force by a tweezers to an object attached to the free end of biopolymers or exerting a force to the biopolymers along its contour length by electric or hydrodynamic flow fields. [7][8][9] Those procedures are usually performed in single-phase flow system. Recently, it is further reported that biopolymers can also be stretched in two-phase flow microfluidics.…”

Section: Introductionmentioning

confidence: 99%

Polymer stretch in two-phase microfluidics: Effect of wall wettability

Sheng

Tsao

2012

Biomicrofluidics

View full text Add to dashboard Cite

Polymer stretching in two-phase microfluidics is investigated by dissipative particle dynamics. The flow patterns can be controlled by wall wettability, flowrate ratio between two phases, and Reynolds number (Re). For neutral and partially wettable walls, segmented flows are formed and polymer stretching can be controlled by Re and segment length. At high Re, stratified flows are observed and the extension ratio can be tuned by the flowrate ratio. For nonwettable walls, slug flows are formed and polymer stretching can be controlled by Re and slug length. At high Re or flowrate ratio, annular flows are observed and high extension ratio can be easily attained. V C 2012 American Institute of Physics.

show abstract

Simulation of electrophoretic stretching of DNA in a microcontraction using an obstacle array for conformational preconditioning

Cited by 20 publications

References 57 publications

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

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

Simulation guided design of a microfluidic device for electrophoretic stretching of DNA

Polymer stretch in two-phase microfluidics: Effect of wall wettability

Contact Info

Product

Resources

About