In the part of the transducer, the conducting polymer plays an important role in converting ions and electrons. However, in practical applications, biomolecules are often limited by ineffectively immobilized on the conducting polymers and cannot be used for a long time in high pH environments. In order to attain the conducting polymers capable of simultaneously immobilizing biomolecules and improving the electrochemical stability. The functionalization of conducting polymer is an important issue. This study will increase the degree of carboxylation of co-electropolymerized materials and confirm the electroactivity of carboxylated conducting polymers in a neutral environment. Therefore, we use two categories of carboxylated materials (high molecular weight and carboxylated carbon nanomaterials). And using simple solution mixing and co-electropolymerization methods to prepare carboxylated conducting polymer composites. From FT-IR results, PANI and PPy were successfully co-electropolymerized with carboxylated materials. In the group of PANI, it was found that the adding more than 25 mg/ml of PAA will change the fiber structure of PANI. And the PPy composites showed a dense cauliflower-like cluster structure. The PANI-A 50 group has the highest redox peak current, PPy-Gr has the best pseudo capacitance stability, and its pseudo capacitance decrease rate is only 13.59%. It can be observed that the hydrophobicity of the film surface is related to the concentration of PAA mixed. When the higher the PAA concentration was added into conducting polymers, the surface of the film will more hydrophilic. The amount of carboxyl group on the surface of carboxylated conducting polymers prepared by co-electropolymerization can reach 1.06 ± 0.08 × 1017/cm2. Aptamer immobilization analysis results showed that the carboxylated conducting polymers surface can be fixed 3.62×1013 molecules/cm2. The results show that the addition of different carboxylated materials to different conducting polymers will achieve in different degrees of carboxylation and electrochemical characteristics. Therefore, different carboxylated conducting polymer materials can be selected to perform different biological and electrochemical processes.