Sepsis is a common cause of morbidity and mortality, particularly in elderly, immunocompromised, and ill patients. Serious trauma and certain medical procedures, like intravenous transfusion and implantation of devices or organs, may cause bacterial bloodstream infections (BSI) or even lead to severe sepsis. An early treatment with effective antibiotics would greatly reduce the risk of morbidity and mortality. The dosage required for different bacteria will be different, and the method of finding most appropriate dosage depends on the antibiotic susceptibility test. Traditionally, it takes one to two days to perform an antibiotic susceptibility test, requiring a large incubator and tedious manual processes. In this thesis, we integrated dual microchamber with ion-sensitive field-effect transistor (ISFET) to perform real-time and dual bacteria growth monitoring. ISFET is very sensitive to pH value change of environment, which would happen when bacteria consume sugars and releasing organic acids during their growth phase. Here, we loaded two bacteria strains into microchamber and cultured on the sensor surface. Then, the ISFET sensor was connected to a portable instrument for 30-60 mins bacteria growth monitoring under various antibiotic treatment. Based on our results, the bacteria growth rate of the resistant strains is more significant than the susceptible strains, and we achieved rapid, label-free and real-time dual bacteria detection.