Title :
16-Channel CMOS Impedance Spectroscopy DNA Analyzer With Dual-Slope Multiplying ADCs
Author :
Jafari, Hossein ; Soleymani, L. ; Genov, Roman
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Toronto, Toronto, ON, Canada
Abstract :
We present a 16-channel, mixed-signal CMOS DNA analyzer that utilizes frequency response analysis (FRA) to extract the real and imaginary impedance components of the biosensor. Two computationally intensive operations, the multiplication and integration required by the FRA algorithm, are performed by an in-channel dual-slope multiplying ADC in the mixed-signal domain resulting in minimal area and power consumption. Multiplication of the input current by a digital coefficient is implemented by modulating the counter-controlled duration of the charging phase of the ADC. Integration is implemented by accumulating output digital bits in the ADC counter over multiple input samples. The 1.05 × 1.6 mm prototype fabricated in a 0.13 μm standard CMOS technology has been validated in prostate cancer DNA detection. Each channel occupies an area of only 0.06 mm2 and consumes 42 μW of power from a 1.2 V supply.
Keywords :
CMOS integrated circuits; DNA; bioMEMS; bioelectric phenomena; biological organs; biomedical electronics; biomolecular electronics; biosensors; cancer; electrochemical impedance spectroscopy; electrochemical sensors; frequency response; medical signal processing; molecular biophysics; multiplying circuits; 16-channel CMOS impedance spectroscopy DNA analyzer; 16-channel mixed-signal CMOS DNA analyzer; FRA algorithm; biosensor; computationally intensive operations; counter-controlled duration; digital coefficient; frequency response analysis; imaginary impedance component extraction; in-channel dual-slope multiplying ADC; input current; mixed-signal domain; output digital bits; power 42 muW; power consumption; prostate cancer DNA detection; real impedance component extraction; size 0.13 mum; standard CMOS technology; voltage 1.2 V; Biosensors; DNA; Electrodes; Impedance; Radiation detectors; Spectroscopy; System-on-a-chip; Biosensor; DNA; electrochemical sensor; frequency response analysis; impedance spectroscopy; multiplying ADC; Algorithms; Biomedical Engineering; Biosensing Techniques; DNA; DNA, Neoplasm; Dielectric Spectroscopy; Equipment Design; Humans; Male; Prostatic Neoplasms; Semiconductors; Signal Processing, Computer-Assisted;
Journal_Title :
Biomedical Circuits and Systems, IEEE Transactions on
DOI :
10.1109/TBCAS.2012.2226334
