Giardia, a protozoan parasite which resides in human intestine, can cause Giardiasis, a common parasitic disease associated with severe diarrhea. It possesses a simple life cycle including the motile trophozoite stage and infectious cyst stage. Once a human consumes unsanitary drinking water or food with Giardia cysts, the low pH in stomach drives excystation to release the trophozoites. When they perceive stimuli from the high bile and alkalinized pH environment, they will initiate encystation by turning on the Cyst Wall Protein gene to form cysts. Our purpose is to understand the spatiotemporal encystation process and the encystation rate of Giardia in a physiological environment (murine intestine) via observing the ratio metric change of encysting and non-encystation cells in the Dual-color Bioluminescence Imaging (BLI) System. BLI is essential to monitor noninvasive biological processes in living organisms via detecting photon emissions that requires the enzyme luciferase to catalyze a substrate, usually luciferin, with oxygen, ATP, and magnesium. To test if dual-color BLI can report the ratio metric change of encysting and non-encysting cells in vitro, we have generated the in vitro encystation assay. The promoter of Glutamate Dehydrogenase, a constantly expressed gene at all stages of Giardia, is combined with a luciferase gene to represent non-encysting cells when transcribed in normal media. The promoter of cyst specific gene, Cyst Wall Protein 1, is combined with another luciferase gene to represent encysting cells when expressed only in encystation media. By successfully observing the ratio metric change of luciferase expressions in vitro, we can then proceed to future mouse experiments. Once the technique has been confirmed feasible in the mouse model, it can be applied to monitor the life cycle of all cyst forming parasites and understand when and where they are at infectious stage, thereby improving the accuracy for alternative drug screening.