AbstractA method is presented to rapidly and precisely measure the conformation, length, speed, and fluorescence intensity of single DNA molecules constrained by a nanochannel. DNA molecules were driven electrophoretically from a nanoslit into a nanochannel to confine and dynamically elongate them beyond their equilibrium length for repeated detection via laser-induced fluorescence spectroscopy. A single-molecule analysis algorithm was developed to analytically model bursts of fluorescence and determine the folding conformation of each stretched molecule. This technique achieved a molecular length resolution of 114nm and an analysis time of around 20ms per molecule, which enabled the sensitive investigation of several aspects of the physica...
Nanofludic devices provide a great platform for single molecular analysis. The unique phenomena in n...
AbstractThe need for low-cost DNA sequence detection in clinical applications is driving development...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 2006.Includes...
AbstractA method is presented to rapidly and precisely measure the conformation, length, speed, and ...
The electrophoretically-driven transport of double-stranded λ-phage DNA through focused ion beam (FI...
The effect of a cationic-neutral diblock polypeptide on the conformation of single DNA molecules con...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, February 2011...
Single DNA molecule techniques have revolutionized our understanding of DNA-protein interactions. Tr...
A nanofluidic device is described that is capable of electrically monitoring the driven translocatio...
This dissertation investigates DNA extension and transport characteristics in nanochannel confinemen...
The power of nanofluidic channels to analyze DNA is described along with practical experimental hint...
When stretching and imaging DNA molecules in nanofluidic devices, it is important to know the relati...
AbstractEach species from bacteria to human has a distinct genetic fingerprint. Therefore, a mechani...
The successful design of nanofluidic devices for the manipulation of biopolymers requires an underst...
We report an approach to study the in situ conformational response of single biomolecules such as DN...
Nanofludic devices provide a great platform for single molecular analysis. The unique phenomena in n...
AbstractThe need for low-cost DNA sequence detection in clinical applications is driving development...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 2006.Includes...
AbstractA method is presented to rapidly and precisely measure the conformation, length, speed, and ...
The electrophoretically-driven transport of double-stranded λ-phage DNA through focused ion beam (FI...
The effect of a cationic-neutral diblock polypeptide on the conformation of single DNA molecules con...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, February 2011...
Single DNA molecule techniques have revolutionized our understanding of DNA-protein interactions. Tr...
A nanofluidic device is described that is capable of electrically monitoring the driven translocatio...
This dissertation investigates DNA extension and transport characteristics in nanochannel confinemen...
The power of nanofluidic channels to analyze DNA is described along with practical experimental hint...
When stretching and imaging DNA molecules in nanofluidic devices, it is important to know the relati...
AbstractEach species from bacteria to human has a distinct genetic fingerprint. Therefore, a mechani...
The successful design of nanofluidic devices for the manipulation of biopolymers requires an underst...
We report an approach to study the in situ conformational response of single biomolecules such as DN...
Nanofludic devices provide a great platform for single molecular analysis. The unique phenomena in n...
AbstractThe need for low-cost DNA sequence detection in clinical applications is driving development...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Chemical Engineering, 2006.Includes...