We address the general question of the extent to which the hydrodynamic behaviour of microscopic freely fluctuating objects can be reproduced by macrosopic rigid objects. In particular, we compare the sedimentation speeds of knotted DNA molecules undergoing gel electrophoresis to the sedimentation speeds of rigid stereolithographic models of ideal knots in both water and silicon oil. We find that the sedimentation speeds grow roughly linearly with the average crossing number of the ideal knot configurations, and that the correlation is stronger within classes of knots. This is consistent with previous observations with DNA knots in gel electrophoresis
AbstractManipulation of individual DNA molecules by optical tweezers has made it possible to tie the...
We use an accurate coarse-grained model for DNA and stochastic molecular dynamics simulations to stu...
Knots in DNA occur in biological systems, serve as a model system for polymer entanglement, and affe...
We address the general question of the extent to which the hydrodynamic behaviour of microscopic fre...
We address the general question of the extent to which the hydrodynamic behaviour of microscopic fre...
We used optical tweezers to tie individual DNA molecules in knots. Although these knots become highl...
AbstractGel electrophoresis allows one to separate knotted DNA (nicked circular) of equal length acc...
Gel electrophoresis is a powerful experimental method to probe the topology of DNA and other biopol...
The effect of knotting and unknotting of biopolymers, such as DNA, has a significant role in many bi...
Various site-specific recombination enzymes produce different types of knots or catenanes while acti...
Various site-speci®c recombination enzymes produce different types of knots or catenanes while actin...
Ropes or yarns, especially when disorderly packed, are prone to develop knots. Polymers are no excep...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Chemical Engineering, 2015.Cata...
We present Brownian dynamics simulations of initially knotted double-stranded DNA molecules untying ...
Knots are ubiquitous objects and decorative elements that have been studied since antiquity. During ...
AbstractManipulation of individual DNA molecules by optical tweezers has made it possible to tie the...
We use an accurate coarse-grained model for DNA and stochastic molecular dynamics simulations to stu...
Knots in DNA occur in biological systems, serve as a model system for polymer entanglement, and affe...
We address the general question of the extent to which the hydrodynamic behaviour of microscopic fre...
We address the general question of the extent to which the hydrodynamic behaviour of microscopic fre...
We used optical tweezers to tie individual DNA molecules in knots. Although these knots become highl...
AbstractGel electrophoresis allows one to separate knotted DNA (nicked circular) of equal length acc...
Gel electrophoresis is a powerful experimental method to probe the topology of DNA and other biopol...
The effect of knotting and unknotting of biopolymers, such as DNA, has a significant role in many bi...
Various site-specific recombination enzymes produce different types of knots or catenanes while acti...
Various site-speci®c recombination enzymes produce different types of knots or catenanes while actin...
Ropes or yarns, especially when disorderly packed, are prone to develop knots. Polymers are no excep...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Chemical Engineering, 2015.Cata...
We present Brownian dynamics simulations of initially knotted double-stranded DNA molecules untying ...
Knots are ubiquitous objects and decorative elements that have been studied since antiquity. During ...
AbstractManipulation of individual DNA molecules by optical tweezers has made it possible to tie the...
We use an accurate coarse-grained model for DNA and stochastic molecular dynamics simulations to stu...
Knots in DNA occur in biological systems, serve as a model system for polymer entanglement, and affe...