Abstract
The development of a non-faradaic electrochemical sensor for screening across multiple bio-fluids that demonstrate the expression of cortisol using a gold microelectrode-based sensor is reported in this paper. Room temperature ionic liquid (RTIL), BMIM[BF4] was used as the buffer to modulate the electrical double layer (EDL) to enhance the electrochemical signal response of the sensor. The sensor design and the surface chemistry was optimized using COMSOL Multiphysics software simulations and FTIR respectively. The sensor was designed so that it uses ultra-low volumes between 3–5 µL of bio-fluid for detection. Cortisol detection was achieved in the physiologically relevant ranges when tested in serum, blood, sweat, and, saliva using non-faradaic Electrochemical Impedance Spectroscopy (EIS) and performance parameters of the sensor were determined. Sensor’s response was tested against the only commercially available salivary cortisol point-of-care kit using regression analysis. Cross-reactive studies using prednisone indicated that the sensor is specific for cortisol. The sensor displayed a correlation value i.e. R2 > 0.95 between the signal response and the concentration of cortisol present in the system. Dynamic range of the sensor was across the physiologically relevant range of cortisol i.e. 50–200 ng/ml for serum/blood, 1–40 ng/ml for saliva, and 10–150 ng/ml for sweat. Limit of detection for serum and sweat was 10 ng/ml and 1 ng/ml for saliva.
Highlights
We have leveraged the electrochemical properties of BMIM [BF4], towards the amplification of electrochemical signal response, in order to develop a robust, sensitive, flexible gold microelectrode-based biosensor for detecting cortisol across different bio-fluids
The signal response for non-invasively obtained bio-fluids and the invasive bio-fluids is comparable even though these bio-fluids have different physical properties which indicates that a single sensor platform can be used to perform robust electrochemical detection across bio-fluids with ultra-low sample volumes
The primary factor for achieving a highly sensitive response can be attributed to the interaction behavior of BMIM[BF4] on the sensor surface
Summary
The sensor was tested for its specificity for cortisol molecule and to understand the effect of cross-reactive agents on the signal response. Even in the presence of this variability, the sensor depicts a linear response for cortisol with the ability to distinguish between different levels of cortisol and other cross-reactive agents. From these cross-reactivity studies, it can be confirmed that the sensor is specific for cortisol molecule and that the presence of interferent molecules does not affect the electrochemical detection ability of the sensor.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
