Nano-sensors for nucleic acid detection and discrimination

The invention claimed is: 1. A nucleic acid detection device, comprising: a graphene chip that comprises a substrate, a graphene surface on the substrate, a conducting substance at two ends of the graphene surface to form a first electrode and a second electrode, and an insulating substance to insulate the first electrode and the second electrode, wherein the insulating substance further forms a solution reservoir on the graphene surface to receive a nucleic acid probe and a sample nucleic acid; a double-stranded nucleic acid probe attached to the graphene surface of the reservoir, wherein the nucleic acid probe comprises a normal strand having a toehold at one end and a weak strand comprising one or more inosines substituting guanines; and a microcontroller board that comprises a digital meter to measure electric current that passes through the graphene chip when an input voltage is applied to the graphene chip, and a communication module to send values of the measured electric current and the input voltage, wherein the microcontroller board further comprises a low-pass filter to filter input voltage. 2. The nucleic acid detection device of claim 1 , further comprising a mobile device that receives the values from the communication module and processes the values to show resistance changes. 3. The nucleic acid detection device of claim 1 , wherein the microcontroller board further comprises a moving-average filter. 4. The nucleic acid detection device of claim 3 , wherein the microcontroller board further comprises a second-order moving-average filter. 5. The nucleic acid detection device of claim 1 , wherein the substrate includes silicon dioxide coated wafer. 6. The nucleic acid detection device of claim 1 , wherein the conducting substance includes conducting silver paste. 7. The nucleic acid detection device of claim 1 , wherein the insulating substance includes silicone rubber. 8. The nucleic acid detection device of claim 1 , wherein the communication module supports wireless communication. 9. A method of detecting or discriminating a nucleic acid having one or more mismatches, comprising: contacting a double-stranded nucleic acid probe in a solution reservoir on a graphene chip such that the nucleic acid probe is attached to a graphene surface of the graphene chip, wherein the nucleic acid probe comprises a normal strand having a toehold at one end and a weak strand comprising one or more inosines substituting guanines; contacting a control nucleic acid that is completely complementary to the normal strand with the nucleic acid probe attached to the graphene surface such that strand displacement occurs between the nucleic acid probe and the control nucleic acid; measuring electric current that passes through the graphene chip when an input voltage is applied to the graphene chip during the strand displacement between the nucleic acid probe and the control nucleic acid using a microcontroller board that comprises a digital meter to obtain a first I-V curve, wherein the microcontroller board further comprises a low-pass filter to filter input voltage; contacting a target nucleic acid that is partially complementary to the normal strand with the nucleic acid probe attached to the graphene surface such that strand displacement occurs between the nucleic acid probe and the target nucleic acid; measuring electric current that passes through the graphene chip when an input voltage is applied to the graphene chip during the strand displacement between the nucleic acid probe and the target nucleic acid using the microcontroller board to obtain a second I-V curve; sending the measured electric current and the input voltage using a communication module; and comparing the second I-V curve with the first I-V curve, wherein a shift in the curve indicating the presence of one or more mismatches in the target nucleic acid. 10. The method of claim 9 , wherein the measured electric current and the input voltage are transmitted to a mobile device using wireless communication.