In the past ten years, photonic crystal fibers (PCFs) have been widely researched. This special type of fibers, with two-dimensional periodic cladding, provides many impressive properties, such as large mode area, endlessly single mode, etc. Recently, PCFs with periodic modulation in the transmission direction are also developed, increasing the periodicity from 2D to 3D. In literature, 3D structure PCFs have been used as fiber gratings and are more efficient than common fibers because of their larger index difference in constitute material. In this thesis, CO2 laser was employed to periodically modulate the diameter of PCF. There are some advantages to fabricate 3D structure PCF by laser heated pedestal growth (LHPG) system: First, many UV-induced gratings will degrade by time, and the Ge doping in core destroys the original physical properties of the fiber. In contrast, the grating fabricated by CO2 laser is stable even in high temperature. Second, the common laser-heated system always heats the fiber in one or two directions, which may induce larger birefringence effect. The ring heating design of our LHPG system has higher symmetry than any other laser-heated system in literature, which may reduce local collapse of the hole structures in PCF and maintain the transmission characteristics. Two methods, periodical control of shutter or motor stages, were used to fabricate 3D structure PCF with about 224.25 micron pitch. The fabricated structure served as a notch filter and the peak attenuation of 16 dB at 1557.5 nm was achieved. Numerical simulations based on a commercially available beam propagation method (BPM) software and coupled-mode theory were used to model the 3D structure PCF. The simulated result agrees well with our fabricated 3D structure PCF.