Heterotrophic denitrification is an economical means for removing nitrate from groundwater. However, residual organic compounds, disinfection by-products and microorganism contamination in treated water cause potential risks to drinking water supplies. To overcome these problems, system combines with Bio-Carrier Reactor (BCR) for heterotrophic denitrification and Membrane Bioreactor (MBR) for removal of residual organic compounds, precursor of disinfection by-products and microorganisms was studied. The effect on nitrate, nitrite, dissolved organic carbon (DOC), Soluble microbial products (SMPs), total bacteria count, coliforms, turbidity and particle size distribution were investigated by change of carbon to nitrogen ratio and volumetric loading in denitrification process. The performance of microorganisms, like denitrification bacteria activity, microbial community identification and microorganism growth were also studied. Filtration resistance and disinfection by-products were compared for different membranes used in MBR reactor. Finally, combination of BCR and MBR was chosen as a pilot plant for a long-term experiment in field to evaluate the feasibility of application. The research results showed that the nitrate concentration in effluent was lower by controlling higher C/N ratio; however, the residual DOC concentration was higher too. The nitrate concentration in the MBR effluent was increased when the nitrate volumetric loading in the denitrification tank was increased. MBR showed better performance in DOC removal compared to BCR. Also MBR showed better removal of SMP when nitrate volumetric loading was in the range of 0.25 to 0.5 kg NO3--N/m3 d. However, the removal of SMP showed no significant difference between MBR and BCR when nitrate volumetric loading was at 0.75 kg NO3--N/m3 d. Total bacteria count and coliforms in MBR effluent was lower than those in BCR. Also, Coliforms in MBR effluent and total bacteria count after chlorine addition could comply with drinking water quality standard. The removal of turbidity was related with filter media and its pore size. The performance was decreased in the order of MBR-G(UF), MBR-K(MF) and BCR(porous carrier). The total filtration resistance for MBR-K was lower than that for MBR-G. And, the total filtration resistance for MBR was decreased as the MLSS concentration was decreased. The maximum nitrogen gas production after 24 hours increased four times after acclimation of denitrification bacteria. Using primer of nirS gene in extraction of Deoxyribonucleic acid (DNA) from microorganism and Polymerase Chain Reaction (PCR) showed that primer of nirS gene could detect denitrification bacteria in reactor rapidly. Application of fluorescence dyeing technology to aerobic biological system showed that MBR microorganism had similar activity compared to BCR. Denaturing Gradient Gel Electrophoresis (DGGE) analysis found that BCR-N, MBR and BCR-C had different dominant microorganisms. Trihalomethanes concentration in the effluent was below 80 μg/L of drinking water standard after addition of sodium hypochlorite for disinfection. A pilot plant combining BCR and MBR was installed in the field for long-term test. The groundwater used as influent containing 40 mg NO3--N/L nitrate in average. During the long-term test, the treated water was controlled at 18 to 36 CMD, the water productivity was at 99.5% and the denitrification efficiency in anoxic tank was 85%. It shows that the effluent nitrate and nitrite were both removed effectively by controlling carbon to nitrogen ratio at 1.5 (g/g) and volumetric loading of nitrate nitroge below 0.8 kg NO3-N/m3d in the influent. It also showed that amounts of DOC and SMPs in membrane permeate are significantly lower than those in the treated water of denitrification reactor. Therefore, a hybrid biological system was proposed in this study. Bench and pilot experiment results showed it could remove nitrate, nitrite, residual organic compounds, precursors of disinfection by-products and microbial products effectively to improve drinking water safety. Based on the research results, the process could be applied in the treatment of surface water and groundwater for nitrate removal. It was also highly potential for treatment of industrial wastewater with high nitrate concentration.