Bacteria identification and characterization are significant issues in various research fields including microbial monitoring of water or food and clinical diagnosis of bacterial infection. A sensitive and reliable bacteria detection method is needed, especially for serious bacterial infection such as sepsis. Without timely and proper treatments, patients will suffer a high fatality rate. However, the conventional clinical bacteria detection process takes 1-3 days waiting for bacteria incubation in blood culture bottles in an automated culture system. Another 1-2 days are required for antibiotic susceptibility test (AST). Therefore, many researchers aim to develop rapid bacteria detection and AST techniques. Surface-enhanced Raman scattering (SERS), as a highly sensitive and label-free biomolecule detection method, can identify various bacteria species and understand antibiotic susceptibility by analyzing bacteria secreted metabolites. Although the time taken for AST can be reduced to several hours using SERS technique, the most time-consuming blood culturing process is still necessary since the bacteria concentration in patients’ blood is too low. To solve this problem, a bacteria enrichment technique, membrane filtration, is introduced in order to shorten the blood culturing time. In this thesis, a microfluidic system integrating membrane filtration and the SERS-active substrate was developed for performing on-chip bacterial enrichment and in-situ SERS measurements for bacteria detection and AST. With this integrated system, manual operating procedures are minimized and uniform SERS detection is ensured in the closed microfluidic chamber. Meanwhile, a meaningful SERS signal could be detected from a low concentration of bacteria (~103/mL). A rapid, label-free and real-time bacteria detection and AST technique can hence be achieved without intensive human labor and manual errors.