During the past several decades, Polyimide (PI) is already a widely used polymer in industries and exhibiting good thermal, chemical, and mechanical properties. These merits render PI a perfect candidate in high-performance engineering applications. To fit for specific purpose, fluoro-containing PI is developed and possesses additional advantages over common PI. Fluoro-containing PI is also soluble in many kinds of organic solvent, rendering a option for simplified operation and better processability. Till recently, new applications of PI coatings have been further investigated, including anti-corrosion and biomedical uses. In this dissertation, high performance fluoro-containing PI films were prepared through different modification process, such as spray-coating of modified nanoparticles and copolyimidization through monomer substitution. The application of modified PI films in anti-corrosion and biomedical uses were deeply explored in this research. In the first section of this dissertation, we prepared superhydrophobic PI hybrid coatings for anticorrosion application by adjusting their surface roughness and surface composition through spray-coating with silylated perfluoroalkylsilane-modified organosilicasol (silylated fluoro-organosilicasol), which increased the surface hydrophobicity. After silylation with 1,1,1,3,3,3-hexamethyldisilazane (HMDS), the silylated fluoro-organosilicasol further transformed the PI surface into a superhydrophobic state. According to the analyses, it suggests that both surface roughness and silylation of the fluoro-organosilicasol making more CF2 groups on the outmost surface rendered the surface hydrophobicity. These PI hybrid coatings also demonstrated good anti-corrosion performance such as lower corrosion current density, nobler corrosion potential and higher polarization resistance. The enhancement in anticorrosion performance was believed to be contributed from the superhydrophobicity and dual barrier protection from the fully-covered fluoro-organosilicasol, insulating the metal from corrosive species in the medium. This superhydrophobic coating technique with good stability guaranteed better corrosion protection and also has great potential for application to other polymeric films. In the second section of this dissertation, a brand-new class of Jeffamine-modified fluoro-containing polyimide (denoted as 6FPI-Jx series, where x is ranging from 10, 20, and 30%) was developed. Although existing pristine fluoro-containing polyimide has been considered as promising biomaterial for its good blood compatibility, it has known to be toxic to normal cells. Here, we modified fluoro-containing PI by incorporation of hydrophilic monomer, Jeffamine, which is a commercial polyether diamine product line from Huntsman. Through systematically characterization, the 6FPI-Jx copolymer exhibited good mechanical and stability as pristine 6FPI. Especially when addition of Jeffamine equal of 10%, 6FPI-J10 displayed considerably improved blood and cell compatibility compared to 6FPI, which was explainable as a combined effect of morphological texture and chemical environment of resulting surface. The new class of 6FPI-Jx also exhibited excellent solubility toward a number of organic solvents. The capability of forming homogeneous 6FPI-J10 coating on stainless steel substrate is demonstrated in this research, showing the 6FPI-J10 a great potential candidate as biocompatible coating for implantable medical devices and also for potential therapeutic applications.