We report the investigations of the parameters that are critical in fabricating microstructured polymer optical fibers (MPOFs). MPOFs of different structures are manufactured with a fabrication framework. A slight change in microstructure can provide MPOFs of distinct functionalities. Then, we study the optical characteristics of various MPOFs, including solid-core and ring-shaped fibers. We show that the solid-core fiber can provide single-mode waveguiding in a very large spectral range, at least covering from 600 through 1600 nm in wavelength. We also show that the solid-core fiber with a larger air-filling ratio can provide multi-mode operation. The number of the guided modes can be precisely predicted with the finite-difference method. In the ring-shaped fiber, we identify various ring modes from experiments and simulations. The ring modes can play the roles of cladding modes, like in a conventional step-index fiber. Coupling between the core mode and the ring modes in a ring-shaped fiber can be used for filtering and switching in fiber communications. Finally, we successfully implement supercontinuum generation in a commercial silica-based photonic crystal fiber pumped with a mode-locked Ti:Sapphire laser. The output spectrum extends from 530 to 1450 nm in wavelength. The pulse duration of the green-light component of the fiber output spectrum is compressed from 155.9 to 112 ps by using a prism pair for dispersion compensation.