Abstract
Understanding protein binding to biosensing surfaces is paramount to the design and performance of biosensing devices in fields such as point-of-care testing and bioanalytics. Here, we systematically demonstrated the use of electrical impedance spectroscopy (EIS) and equivalent circuit modeling for real-time tracking of chemisorption of IgG antibody to large-area circular gold electrodes (1.3 mm(2)) functionalized with a self-assembled monolayer (SAM). Using 1 μg/mL IgG and 5 mM of [Fe(CN)(6)](3-/4-), the measured low-frequency impedance proved sensitive to both equilibrium and kinetics of antibody binding, with a slope of ∼74 kΩ/h for the first 2 h and taking approximately 4 h to reach equilibrium in a standard 6 mm-diameter well. Changes in impedance were found to be proportional to the reciprocal of the change in capacitance up to half-to-full IgG monolayer bound to the SAM. Further experiments with a flat microchannel confirmed that the low-frequency impedance and equivalent charge-transfer resistance (R(ct)) depend not only on antibody diffusion but also on the surface-to-volume ratio, which can represent a major challenge previously unreported for the miniaturization of EIS in microfluidic devices. This challenge arises as it requires a higher concentration of [Fe(CN)(6)](3-/4-), of 50 mM or above, which was found to interfere with R(ct) during chemisorption at low IgG concentrations. Chemisorption of IgG to SAM was confirmed with fluorescence microscopy and FTIR. This study marks, to the best of our knowledge, the first experimental demonstration of EIS as a real-time technique for quantitation of Langmuir isotherms during chemisorption of antibodies to SAM, with the potential to improve the design of EIS-based biosensors, especially those integrated into microfluidic devices.