Active-electrode integrated biosensor array and methods for use thereof

The invention claimed is: 1. A method for detecting DNA polymerization using active-electrode biosensors, the method comprising: immobilizing a plurality of identical primed DNA molecules in a reaction chamber containing an aqueous solution on top of an active-electrode biosensor system; interfacing said active-electrode biosensor system to said plurality of primed DNA molecules via an insulating layer, wherein said active-electrode biosensor system comprises a sensing electrode, a stack of metal layers disposed adjacent to said sensing electrode and a detection circuitry adjacent to said stack of metal layers, wherein said stack of metal layers comprises one or more metal layers separated by an insulating material, wherein said detection circuitry is operatively coupled to said sensing electrode, wherein said detection circuitry having an operational amplifier and a capacitor where said capacitor is in a parallel configuration with respect to said operational amplifier, wherein said detection circuitry further comprises an array of active-electrode sensors built on a semiconductor substrate, wherein said active-electrode biosensor system further comprises a microwell built on its top with openings to hold a single bead on which DNA strands are immobilized; introducing nucleotides into said reaction chamber in the presence of a DNA polymerase enzyme; measuring an output voltage of said active-electrode biosensor system; estimating an ionic current using said measured output voltage of said active-electrode biosensor system; and identifying an occurrence and amount of DNA polymerization events for said primed DNA molecules interfaced to said active-electrode biosensor using said estimated ionic current. 2. The method as recited in claim 1 , wherein said measuring of said output voltage of said active-electrode biosensor system comprises: incorporating an analyte-recognition layer within a double layer of said active-electrode biosensor system; and creating ionic currents within a biosensing reaction volume that are indicative of analyte-recognition layer interactions; wherein said incorporating said analyte-recognition layer within said double layer of said active-electrode biosensor system and said creating ionic currents within said biosensing reaction volume that are indicative of said analyte-recognition layer interactions are performed concurrently. 3. The method as recited in claim 1 further comprising: introducing a single type of nucleotide in the presence of said DNA polymerase enzyme; monitoring said DNA polymerization events in response to introducing said single type of nucleotide in the presence of said DNA polymerase enzyme; and removing remaining nucleotides from said reaction chamber after said introduction of said single type of nucleotide in the presence of said DNA polymerase enzyme. 4. The method as recited in claim 3 further comprising: repeating all previously recited steps for a different nucleotide. 5. The method as recited in claim 3 , wherein said single type of nucleotide comprises one of the following: dATP, dTTP, dCTP and dGTP. 6. The method as recited in claim 1 further comprising: finding a sequence of primed DNA strands using said identified occurrence and amount of said DNA polymerization events. 7. The method as recited in claim 1 , wherein said primed DNA molecules are identical.