When light beam propagates in the waveguide, the optical phase is influenced by the boundary index and thickness variations. Applying the phase modulation method in the configuration, the optical phase can be retrieved from the interference fringes. This technique combining the waveguide and the interferometry is so called “waveguide interfermetry”. It offers more information to resolve bio-sample parameters because both TE and TM polarizations are available. Therefore, it is very suitable to being applied to bio-molecules interactions measurement. In this thesis, a newly developed dual-polarization waveguide interferometry system is developed. The Mach-Zehnder Interferometry based optical configuration includes the newly developed waveguide chip, the sample and the reference light beams equipped with different polarizations, the phase modulation mechanism by combining quarter wave plate and analyzer, CCD, IMAQ card, and LabVIEW program to acquire the signal. Moreover, integrating the analog temperature control system in this optical biochip system further reduces the influence of the environmental disturbance. The motivation of this dissertation is to solve some problems faced by SPR and ellipsometry detection techniques in bio-tech analysis. Due to generic optical configuration limitations, SPR technique can only adopt TM polarization detection and thus may have less information to retrieve parameters needed to explore the complex bio-reactions. In ellipsometry detection, the incident light path through the bio-sample layer changes due to the bio-sample index variations, which makes it hard to determine the exact incident angle needed for inverse calculations. In order to improve shortcomings of these techniques, the dual-polarization waveguide interferometry system is developed and built during the course of this research. The incident light beam in this method can sense the bio-sample by using both TE and TM polarizations and is propagated in the waveguide without suffering variable indices when light beam penetrates across bio-sample and chip layers. Furthermore, the resolution of waveguide interferomerty is increased due to the multi-reflections exist the waveguide. The dual-polarized waveguide interferometry system has bee proved the ability to detect the bio-molecules interactions. Some ELISA interaction and regeneration experiments were completed. The Anti-IgG and IgG reaction was successfully measured. These experimental results can be converted into the complex bio-reaction information sought after by biomedical researchers. To further improve the resolution and to expand the application regime of this system, several work items were proposed, which include minimizing the optical system size, simplifying the signal detection part, reducing the waveguide chip cost, and integrating the flow injection system. With these suggested potential improvements implemented, the dual-polarization waveguide interferometry system is expected to become even more accurate and more versatile.