In this study, two kinds of organic electronic materials have been studied for the application in organic thin film transistors (OTFT). The first kind is the thin-film materials for gate insulator. 1-(a) To develop the insulating films made of Ta2O5-doped polyimide utilizing sol-gel processes. 1-(b) To study the insulating thin films of polyimide (PI) and poly vinyl phenol (PVP), aimed at their match with the OTFT processing. The second kind is the conducting films for transparent electrodes of OTFT, which is made of conducting polymer, poly-(3,4-ethylenedioxythiophene /polystyrene sulphonate) (PEDOT: PSS), mixing with nano-sized silver wires. The above mentioned thin-film materials are integrated with a solution processed organic semiconductor 5,11-bis(triethylsilylethynyl) anthradithiophene (TES-ADT) to fabricate OTFT devices. Their physical and electronic properties are characterized and investigated. The study of 1-(a) showed that the composite insulating films have thermal properties degrading and dielectric constant increasing with the content of Ta2O5 in the polyimide. The OTFT incorporating the films showed that the carrier mobility increased with the dielectric constant of the films. Furthermore, the degree of imidization of the composite films is affected by the amount of Ta2O5 added, and consequently, influences the leakage current densities of the films. In the study of 1-(b), the surface energies of PI and PVP films are found critical to the qualities of TES-ADT films formed on them as well as the electronic stability of the fabricated OTFT. Furthermore, it was verified that the thithography applied on organic semiconductor layer could reduce parasitic leakage current and increase current on/off ratio. The OTFT based on spin-cast TES-ADT films grown on the low-surface-energy PI dielectric exhibited enhanced electrical performance with a carrier mobility as high as 0.43 cm2/Vs and a current on/off ratio of 106. At last, the study of the silver wires/PEDOT: PSS composite film shows that the transparent conductive electrodes have a low sheet resistance less than 140 Ω/sq and a transmittance as high as 70 % in the visible region. For the composite film with 0.1 wt% of AgNWs, the work function is 5.0 eV and the corresponding contact resistance is as low as 2.7 × 104 Ω•cm. The resulting OTFT device utilizing TES-ADT as active layer showed a high electrical performance with carrier mobility 0.21 cm2/Vs.