Deep-frying is a simple, rapid and popular cooking method in our daily foods. There are several chemical reactions occurring during repetitive and continuous deep-frying process, which gives rise to the formation of considerable number of harmful compounds that significantly deteriorate the quality of deep-frying oil. To determine the point at which the deep-frying oil should be discarded rapidly is thus a challenging task, and no satisfactory method for real-time field analysis is available to date. Our work was to study the electrochemical impedance spectroscopic (EIS) behavior of deep-frying oil during heating, as well as assess the feasibility of developing an EIS platform for the quality of deep-frying oil. EIS measurement was scanned from 10-2 Hz to 103 Hz at 30 °C with an unbiased 100 mV sinusoidal signal through a pair of screen-printed carbon electrodes. The result showed that the sample didn’t need any pretreatment and the charge transfer resistance (RCT) in Nyquist plot decreased with increasing the frying cycles. The resulted EIS spectrum was fit to the Randles equivalent circuit for further data interpretation. RCT was gradually decreased from 57.85±1.45 GΩ (fresh frying oil) to 8.43±1.12 GΩ (oil sample after 20 hours frying simulation test), and total polar compounds (TPC) content also increased from 5.5 % to 23.5 %. Since RCT showed obvious negative correlation with the content of TPC, it would be a potential index for the quality of deep-frying oil. Electrochemical impedance spectroscopic has been proved that it has potential to develop a rapid sensing platform for deep-frying oil quality through a pair of screen printed carbon paste electrodes.