Handheld Electrochemical Sensing Platform: Analysis for Pathogen Detection

Using a Modular Electrochemical Impedance Spectroscopy (EIP) Device – Benchtop Instrumentation and Mobile Detection

Opportunity

Available for Licensing

IP Status

US Utility Patent Pending

Inventors

Thomas Chen
Lang Yang

At A Glance

Researchers in the Department of Electrical & Computer Engineering at Colorado State University have developed a digital signal generation and acquisition device overcomes the limitations of analog EIS instrumentation. The device uses digital techniques to store multi-frequency input stimuli of different frequency ranges and uses the state-of- the-art digital-to-analog conversion to generate the required analog stimuli. The resulting circuit can be integrated on a single chip, making it less susceptible to noise, reducing size and cost of future EIS products.  The device is well suited for a variety of mobile or in-the-field applications, such as pathogen detection, as well as in conventional benchtop systems.

Licensing Director

Mandana Ashouri
Mandana.Ashouri@colostate.edu
970-491-7100

Reference No.: 17-045

Background

Interest in low cost and highly mobile detectors with digital output is extremely high, due partially to the anticipation of an Internet-of-Things. Electrochemical methods of detection are inherently suitable for low cost and miniaturization and offer an attractive alternative to traditional methods for pathogen detection (e.g., polymerase chain reaction – PCR) and other uses as they do not require expensive equipment or specialized reagents. Electrochemical impedance spectroscopy (EIS) is an electrochemical technique with particular potential.

 

Technology Overview

Standard EIS employs equipment that performs a linear sweep of an analog signal through the desired frequency range. Not only is the equipment physically bulkier than the standard digital equipment of today, but the frequency range accessible to the analog equipment is limited on the low end of the frequency spectrum by the poor signal-to-noise intrinsic to this region of the spectrum. Additionally, the need to perform a linear frequency sweep slows the rate of signal acquisition. The slow rate limits the use of EIS in certain experiments and prohibits the use of certain techniques to improve signal-to-noise.

Part of the innovation lies in the sophisticated composite signal employed, which combines 32 sinusoidal signals of varying frequencies between 2 Hz and 2 kHz and incorporates an offset in order to lower the crest factor for the signal. The signal is stored digitally but delivered as a single analog composite signal. Other composite signals may be readily used.

Another aspect of the innovation lies in the onboard signal-to-noise reduction that dramatically reduces the flicker noise that is inherent to the low end of standard EIS frequency ranges. Incorporated directly into the circuit design, the result is a measurement with low end sensitivities superior to bulkier analog equipment.

Benefits
  • Digital EIS device that is superior to conventional analog EIS instrumentation
  • Composite waveform is stored digitally and delivered as an analog signal
  • Onboard signal acquisition with signal-to-noise reduction for improved sensitivity
  • Excellent results from a miniaturized, low power and low cost device
  • Well-suited for mobile and field applications
Applications

The method described in the invention can be used as a baseline technology for future EIS-based POC diagnostic devices. The method makes it possible to shrink the size of POC devices and reduce the cost.

Last updated on October 7, 2019.