We report unprecedented superomniphobic characteristics of nanotube-structured TiO2 surface fabricated by electrochemical etching and hydrothermal synthesis process, with the wettability contact angles for water and oil both being similar to 174 degrees or higher. A tangled forest of similar to 8-nm-diameter, multiwalled nanotubes of TiO2 was produced on the microtextured Ti surface, with the overall nanotube length controlled to 150 nm by adjusting the processing time. Wettability measurements indicate that the nanotube surface is extremely nonwettable to both water and oil. The contact angle of the 8 nm TiO2 nanotube surface after perfluorosilane coating is extremely high (178 degrees) for water droplets indicating superhydrophobic properties. The contact angle for oil, measured using a glycerol droplet, is also very high, about 174 degrees, indicating superoleophobic characteristics. These dual nonwetting properties, superomniphobic characteristics, are in sharp contrast to the as-made TiO2 nanotubes which exhibit superhydrophilic properties with a contact angle of essentially similar to 0 degrees Such an extreme superomniphobic material made by a simple and versatile method can be useful for a variety of technical applications. It is interesting to note that all three properties can be obtained with identical nanotube structures. A nanometer-scaled structure introduced by hydrothermally grown TiO2 nanotubes is an effective air trapping nanostructure in enhancing the amphiphobic (superomniphobic) wettability.