In this work the effects of doping and loading TiO2 nanoparticles (NPs) with Ni and Fe, individually or co-operatively, on their photo-catalytic activities in the degradation of organic dyes and water splitting generating hydrogen have been investigated systematically. In addition, the effect of hydrogenation of these metal-doped and metal-loaded nano-materials on water splitting and dye degradation has been studied. These new metal-doped and metal-loaded nano-materials were synthesized by the alcohol-thermal method and the hydrazine reduction method, respectively, and characterized with different analytical techniques including XRD, SEM, XPS, and UV-Vis absorption spectroscopy, in addition to the dye degradation and water splitting measurements. The results of the UV-Vis absorption measurements showed that the hydrogenation of these nano-materials led to a significant enhancement in the absorption in the visible region of the solar spectrum. For the Ni-doped TiO2, the hydrogenation increased the H2 production rate over that of the doped NPs by 4.5 times and, notably, more than those of the pure TiO2 NPs or the hydrogenated TiO2 NPs without doping by as much as 18 times. Most significantly, the hydrogenation of the Ni-loaded TiO2 NPs using the commercial P25 NPs led to a factor of 20 enhancement in H2 production over that of the sample without hydrogenation and as much as 67 times over that of pure TiO2 or hydrogenated TiO2 without Ni-loading. Based on the results of GC/MS measurements, the rates of H2 generation from the photolysis of the Ni-doped TiO2 NPs and the hydrogenated Ni-loaded TiO2 NPs are, respectively, 1.64 mmol/g-hr and 6.18 mmol/g-hr employing about 2 W of a xenon lamp. Contrary to above results, the Fe-doped or loaded TiO2 NPs as well as those co-doped with Ni revealed much weaker photo-catalytic activities in dye degradation and water splitting tests.