Electrokinetic Concentration of DNA Polymers in Nanofluidic Channels
Abstract
DNA molecules can be concentrated in a narrow region of a nanochannel when driven electrokinetically in submillimolar salt solutions. Transport experiments and theoretical modeling reveal the interplay of electrophoresis, electro-osmosis, and the unique statistical properties of confined polymers that lead to DNA aggregation. A finite conductance through the bulk of the device also plays a crucial role by influencing the electric fields in the nanochannel. We build on this understanding by demonstrating how a nanofluidic device with integrated electrodes can preconcentrate DNA at selected locations and at physiological salt concentrations that are relevant to lab-on-a-chip applications- Dataset
- Dataset
- Biophysics
- Biochemistry
- Medicine
- Microbiology
- Genetics
- Biotechnology
- Inorganic Chemistry
- Space Science
- Biological Sciences not elsewhere classified
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- DNA Polymers
- nanofluidic device
- Nanofluidic ChannelsDNA molecules
- Electrokinetic Concentration
- transport experiments
- submillimolar salt solutions
- DNA aggregation
- preconcentrate DNA
- nanochannel
- salt concentrations
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Last time updated on 16/03/2018
This paper was published in The Francis Crick Institute.
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