In this thesis, effects of operating parameters of hydrothermal approach with stirring on the synthesis and physical properties of titanium dioxide particles were studied. The synthesized TiO2 particles were then subjected to plastic anodes based on ITO-PEN substrates by doctor blade and hot compression methods for application in dye sensitized solar cells. UV-vis analysis indicated the synthesized TiO2 particles exhibited threshold wavelength around 380-390 nm, corresponding to bang gap energy of 3.18-3.26 eV. XRD analysis showed that anatase form was the predominant crystal structure of the prepared TiO2, and no rutile form appeared. However, the as-synthesized samples at 210℃ yielded trace brookite structure, and it disappeared as the temperature increased to 230℃. The hydrothermal samples synthesized at 270℃ and 300 rpm for 4h displayed the least IR absorption and PL intensity, which may be attributed to a high crystallization. Under hot compression at 80 ℃ and 100 MPa, TiO2 films from pure P-25 illustrated more flat surface with low porosity, on the contrary, those comprising P-25 and synthesized TiO2 (7:3) explored more rough surface with large porosity, which was beneficial for dye solutions and electrolytes to permeate therein. The photo-to-electricity conversion efficiency effectively enhanced from 2.91% to 3.69% as 30% P-25 was replaced by hydrothermal TiO2 synthesized at 270℃ and 300 rpm for 4h.