This study is to develop an effective mechanism for spaying photoresist on planar and non-planar substrates with high topography surface. An electrostatic-assisted spray coating apparatus for spraying photoresist on substrate has been designed and tested. First, this apparatus is used to spay photoresist on 4 type of substrates: the wafer, the planar substrate with high topography surfaces, the non-planar substrates with and without non-planar high topography surfaces. The thickness difference and uniformity of the photoresist on the substrates are measured and evaluated. The other aspect of this study is integrating electrostatic-assisted spray coating, stepped lithographic process, and electroless nickel plating process to fabricate the continuous microstructures onto the metal rollers. The rollers are then used in the UV curing roller imprinting to fabricate microstructures on PET films. The Electrostatic-assisted spray coating apparatus can successfully spay photoresist (EPG-510) on substrates. Using the electrostatic-assisted spray coating, the uniformity of photoresist is below 5% on the wafer and the thickness difference is about 121 nm. Using the electrostatic-assisted spray coating on the roller with same spray time, the uniformity of photoresist can decrease from 9.5% of traditional spray to 7.7% and the thickness difference is about 400 nm. Furthermore, using the electrostatic-assisted spray coating can effectively spray photoresist 3 kind of substrates with high topography surface: nickel plate with V groove microstructure (width 50 μm and depth 25 μm), roller with wave shape microstructure (width 245 μm and depth 24 μm), roller with rectangle microstructure (height 2 μm and period 122 μm). Compared with traditional spray coating, electrostatic-assisted spray coating yields significantly better performance in increasing uniformity and decreasing thickness difference. Electrostatic-assisted coating also avoided the defects due to the gravity-induced flow experienced in dip coating. Finally, using the stepped rotating lithography technique, the photoresist patterns with 20 μm wide line have been successfully fabricated onto the nickel-plated roller coated with electrostatic-assisted spray. Subsequently, the roller is treated with electroless nickel plating process, and the residual photoresist is removed by acetone. After that, a roller with continuous rigid nickel microstructures, with 20 μm width, 10 μm height and 143 μm period, has been fabricated. The roller is used for practical UV curing imprinting to replicate the microstructures onto PET film. Microstructures with the same period but 9.7 μm depth, have been successfully replicated on the substrates.