In this thesis, a biosensor consists of an Indium-Gallium-Zinc-Oxide (IGZO) thin film transistor (TFT) and a gold sensing electrode is demonstrated for diffusion and mixing properties detection of biomolecules. The protein-ligand kinetic reaction is further investigated. The thesis includes two parts. In the first part, in order to analyze the streptavidin-biotin mixing condition, a Y-type external microfluidic channel is integrated with the TFT biosensor. In addition, the channels are sealed with polydimethylsiloxane to avoid evaporation of the target analyte solutions. The current signals of streptavidin and biotin are measured separately to define the diffusion time. Then, a series of mixing and time delay experiments are conducted. By observing the real-time current change of the TFT biosensor, the mixture condition of the reaction can be analyzed. Finally, bovine serum albumin (BSA) is used for a control experiment to verify the specificity and reliability. In the second part, kinetic reaction of lysozyme and tri-N-Acetylglucosamine (NAG3) are investigated and applied to a TFT biosensor integrated with a linear shape microfluidic channel. First, lysozyme solutions of several concentrations are introduced into the microfluidic channel to construct the relation between lysozyme concentration and drain current variation. Then, three mixing ratios of lysozyme and NAG3 solution are incubated in the micro-centrifuge for different periods of reaction time. Considering the screen effect, the extracted drain current variations are calibrated by the revision factor and the revised current variations are converted into remained lysozyme concentration by the correlation of current variation and lysozyme concentration. Based on the converted information, the fitting curves of remained lysozyme concentration versus reaction time are illustrated. The curves provide the information that can be utilized to calculate the partial orders, association rate constant, and dissociation constant by biochemical formulas. It is noteworthy that the derived dissociation constant is 39.10 μM, which is close to the results reported by previous researches.