Nanofluidic device for charge analysis of straightened molecules

What is claimed is: 1. A nanofluidic sensing device comprising: a) a channel comprising a floor and a ceiling, wherein said floor and said ceiling are spaced by less than 1 μm and the channel comprises an entrance end and an exit end that define the longitudinal axis of said channel; b) an array of charge sensors in the floor and/or ceiling of said channel, arranged along the longitudinal axis of said channel; c) a capture area in the floor and/or ceiling of said channel at the entrance end of said channel, wherein said capture area comprises surface exposed groups that affix an end of a functionalized nucleic acid molecule to the capture area; and d) a first electrode and a second electrode, wherein said first and second electrodes are positioned to provide an electrophoretic force along the longitudinal axis of said channel, thereby straightening any nucleic acid molecule that is attached to said capture area and placing a region of interest of said nucleic acid molecule in proximity with a plurality of said charge sensors. 2. The nanofluidic device of claim 1 , wherein the floor and ceiling of said channel are spaced by less than 100 nm. 3. The nanofluidic device of claim 1 , wherein said channel is up to 100 μm in length. 4. The nanofluidic device of claim 1 , wherein the entrance end and an exit end of said channel are adapted for connection with a source of reagents and a waste line, respectively. 5. The nanofluidic device of claim 1 , wherein said charge sensors are ion sensitive field effect transistors. 6. The nanofluidic device of claim 1 , wherein said channel is not linear along its longitudinal axis. 7. The nanofluidic device of claim 1 , wherein said nanofluidic device comprises at least 10 of said charge sensors. 8. The nanofluidic device of claim 1 , wherein said charge sensors are spaced from one another by less than 1 μm. 9. The nanofluidic device of claim 1 , wherein said surface exposed groups comprise gold atoms or streptavidin. 10. The nanofluidic device of claim 1 , wherein said channel comprises: a plurality of distinct regions that are in direct contact with one another and that comprise different surface charges, wherein at least one region has a wall surface that provides a negative zeta potential, and at least one region has a wall surface that provides a positive zeta potential, wherein the different surface charges in the distinct regions cause: enrichment of mobile counter-ions and depletion of mobile co-ions in the fluidic regions contained within the distinct channel regions; and diode-like behavior of the channel when forward and reverse biases are applied across the channel length. 11. A nanofluidic system comprising: a nanofluidic sensing device comprising: a) a channel comprising a floor and a ceiling, wherein said floor and said ceiling are spaced by less than 1 μm and the channel comprises an entrance end and an exit end that define the longitudinal axis of said channel; b) an array of charge sensors in the floor and/or ceiling of said channel, arranged along the longitudinal axis of said channel; c) a capture area in the floor and/or ceiling of said channel at the entrance end of said channel, wherein said capture area comprises surface exposed groups that affix an end of a functionalized nucleic acid molecule to the capture area; and d) a first electrode and a second electrode, wherein said first and second electrodes are positioned to provide an electrophoretic force along the longitudinal axis of said channel, thereby straightening any nucleic acid molecule that is attached to said capture area and placing a region of interest of said nucleic acid molecule in proximity with a plurality of said charge sensors; e) a source of reagents that is operably connected to the entrance end of said channel; and f) a waste line that is operably connected to the exit end of said channel. 12. The nanofluidic system of claim 11 , wherein the source of reagents comprises: DNA polymerase, nucleotides and DNA polymerase reaction buffer.