This paper uses computer simulations to reveal unprecedented details about linearization of deoxyribonucleic acid (DNA) inside dynamic nanochannels that can be repeatedly widened and narrowed. We first analyze the effect of rate of channel narrowing on DNA linearization dynamics. Quick (similar to 0.1 s) narrowing of nanoscale channels results in rapid overstretching of the semi-flexible chain followed by a slower (similar to 0.1-10 s) relaxation to an equilibrium extension. Two phenomena that induce linearization during channel narrowing, namely, elongational-flow and confinement, occur simultaneously, regardless of narrowing speed. Interestingly, although elongational flow is a minimum at the mid-point of the channel and increases towards...
University of Minnesota Ph.D. dissertation. May 2014. Major: Chemical Engineering. Advisor: Kevin Da...
International audienceThe control over DNA elongation in nanofluidic devices holds great potential f...
University of Minnesota Ph.D. dissertation. January 2016. Major: Material Science and Engineering. ...
This paper describes a novel nanofluidic phenomenon where untethered DNA and chromatin are linearize...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
This paper describes a novel nanofluidic phenomenon where untethered DNA and chromatin are linearize...
The successful design of nanofluidic devices for the manipulation of biopolymers requires an underst...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
Microfluidic channels are investigated here with a view to unravel and deliver long genomic DNA stra...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 2008.Includes...
The control over DNA elongation in nanofluidic devices holds great potential for large-scale genomic...
Knots in long DNA molecules are prevalent in biological systems and serve as a model system for inve...
A theory is presented of the elongation of double-stranded DNA confined in a nanochannel based on a ...
We show that genomic-length DNA molecules imaged in nano-channels have an extension along the channe...
Langevin dynamics simulations are used to characterize the typical mechanisms governing the spontane...
University of Minnesota Ph.D. dissertation. May 2014. Major: Chemical Engineering. Advisor: Kevin Da...
International audienceThe control over DNA elongation in nanofluidic devices holds great potential f...
University of Minnesota Ph.D. dissertation. January 2016. Major: Material Science and Engineering. ...
This paper describes a novel nanofluidic phenomenon where untethered DNA and chromatin are linearize...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
This paper describes a novel nanofluidic phenomenon where untethered DNA and chromatin are linearize...
The successful design of nanofluidic devices for the manipulation of biopolymers requires an underst...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
Microfluidic channels are investigated here with a view to unravel and deliver long genomic DNA stra...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 2008.Includes...
The control over DNA elongation in nanofluidic devices holds great potential for large-scale genomic...
Knots in long DNA molecules are prevalent in biological systems and serve as a model system for inve...
A theory is presented of the elongation of double-stranded DNA confined in a nanochannel based on a ...
We show that genomic-length DNA molecules imaged in nano-channels have an extension along the channe...
Langevin dynamics simulations are used to characterize the typical mechanisms governing the spontane...
University of Minnesota Ph.D. dissertation. May 2014. Major: Chemical Engineering. Advisor: Kevin Da...
International audienceThe control over DNA elongation in nanofluidic devices holds great potential f...
University of Minnesota Ph.D. dissertation. January 2016. Major: Material Science and Engineering. ...