Optical force enables the contactless and nondestructive manipulation of tiny fragile objects which is unachievable by any mechanical tweezers. Recent research on integrated optical trapping using the forces induced by evanescent fields has opened up new opportunities for the manipulation in lab-on-a-chip systems. Due to the highly localized field distribution in near field region, particles of sub-micrometer and even nanometer size can be manipulated with precision higher than most conventional tools. However the evanescent field is always weak and therefore the input power must be high to generate force of sufficient strength. Considerable interest has emerged for the use of resonant mode in either optical microcavity or plasmonic structures as ways to enhance optical forces and lower power consumption. Moreover, the resonant characteristic will provide possibility for label-free detection of nanoparticles and molecules with high sensitivity. Such a multiple functional device, which is compatible with parallel manipulation, will be a key component in lab on chip development for bio-chemistry applications. This dissertation focuses right on demonstration of on-chip optical manipulation system with multiple functionalities, including trapping, transportation, detection, and sensing. By design of photonic crystal waveguide, we demonstrate a particle transportation system which is very efficient due to the implementation of slow light effect. For increasing the controllability of near-field optical manipulation, a brand new functionality called controllable transportation is proposed using tapered photonic crystal waveguide. For pursuing compactness of a trapping system we also integrate plasmonic structure on optical waveguide. To develop a compact and efficient trapping system with detection and sensing functionality at the same time, we turn to design one-dimensional photonic crystal cavity. We first propose a nanobeam photonic crystal cavity with waist structure which is accessible for particle of various sizes. This design reaches a trapping force record at nano-Newton level. At the end of this work we further push the record to the level of a few tens of nano-Newton by surface-like resonant mode of nano-fishbone photonic crystal cavity. Meanwhile its abilities in particle detection and surrounding medium sensing are quite remarkable. We anticipate these on-chip particle manipulation approaches we introduce could lead to various applications in nanotechnology and the environmental and life sciences.