Organs-on-a-chip is attracting for the advanced technology as an alternative to the animal models. To monitoring the environmental changes caused by cellular metabolism effectively, the sensor must be miniaturized. Solid-state ion-selective electrodes (SS-ISEs) provide a way to measure pH and dissolved carbon dioxide system, but are still limited by the potential instability and the memory effect. In this study, we used poly(3,4-ethylenedioxythiophene) (PEDOT) as ion-to-electron transducer (IET) to construct the solid-state pH electrode and solid-state carbonate-selective electrode. We aimed to improve the potential stability and potential repeatability of SS-ISEs by tuning the counter ion of IET and the casting method of ion-selective membrane (ISM). Firstly, the efficiency of signal transfer between ion and electron is related to the redox reaction of PEDOT. For this purpose, high electrochemical stability and high pseudocapacitance of PEDOT is needed. Under the constant potential electrodeposition method, PEDOT with BF4- ion met the requirement. The sensitivity and potential stability of hydrogen-ISE and the carbonate-ISE were 59.16 mV/pH, 7.12 μV/s and 24.37 mV/decade, 14.08 μV/s, respectively. Secondly, increasing in the thickness of ISM of hydrogen ISE could reduce ionic flux and the memory effect, so multiple times drop coating of ISM was optimal. But the carbonate-ISE was opposite, ISE with single drop of ISM could have best sensitivity, potential stability and the potential repeatability, so single time drop coating of ISM was optimal. After tuning the parameters of the manufacturing process, the hydrogen-ISE and carbonate-ISE were placed in a multi-ion solution for repeated measurement (n = 5) with excellent potential repeatability, and the values were 1.06 mV and 1.33 mV, respectively. Finally, the performance of the hydrogen-ISE and carbonate-ISE in the cell culture medium showed that the two electrodes could maintain a high potential stability in the serum-containing solution and could measure the difference in concentration of the cell culture medium for different days.