As the development of the biomedical semiconductor technology, the double-gated structure applied on pH sensing of ISFET has been researched in several studies. However, all the researches of double-gated ISFET above were based on single crystalline silicon channel rather than poly-Si channel film. For the first time, we proposed the novel double-gated poly-crystalline silicon thin film transistors (DG poly-Si TFT) structure as a ion-sensitive filed effect transistor (pH-ISFET) for pH sensing, and adopted silicon-dioxide (SiO2) as the sensing membrane. In this thesis, we investigated on the pH sensitivity of the liquid-gate and bottom-gate by utilizing a DG poly-Si TFT with various sensing membrane thickness as a pH-ISFET. Here we have successfully demonstrated the feasibility of applying the DG poly-Si TFT as a pH-ISFET. Besides, the relationship between the pH sensitivity of the liquid-gate and bottom-gate operation mode were also observed and illustrated in this study. From the experiment results, the pH sensitivity of the DG-ISFET is obviously improved after a H2 sinter process. Also, it can be found that the immersion of ISFET devices with the RO water is not expected to improve the pH sensitivity of ISFET but may provide a more stable measurement of pH sensitivity precluding the influence of the non-ideal phenomena such as drift. Most importantly, the pH-induced bottom-gate voltage shift per pH depending on the asymmetric between the top oxide and back oxide thickness of double-gated ISFET is observed and presented. The pH sensitivity of bottom-gate operation mode will degenerate with the increased sensing membrane thickness, while the pH sensitivity of the liquid-gate operation mode is independent of the sensing membrane thickness and limited by the Nernst limit. Furthermore, a measuring method was raised to confirm the relation between the pH response of the bottom-gate and liquid-gate operation mode. Hence we believed that the experiment results in this thesis are credible and valuable.