Nitrogen is not only the main factor of causing eutrophication in water body, but also the crucial water quality of carrying out reclaimed wastewater. It has not been restricted stringently on total nitrogen (TN) effluent standards in the past so that most conventional municipal wastewater treatment plants (WWTP) provide little TN removal unless the treatment system is upgraded to an anaerobic/anoxic/oxic (A2O) or an anaerobic denitrification unit is placed after the secondary clarifier. Increasing wastewater reuse to adapt capacity for water resources under climate change imperatively calls for an upgraded capacity of WWTP to remove TN, which would preserve environment and promote treated water more amenable to beneficial uses. This study employed entrapped biomass technology to augment a traditional aerobic activated sludge process with AO/A2O function for removal of TN. The entrapped biomass plates (EBP) were fabricated in the format of carrier plates on which microbial cells were entrapped. Due to mass transport limitations, anoxic and anaerobic conditions were created within the bioplates where denitrification could proceed. The study method was by way of devising experiments from 10 research hypotheses to verify their effects. The authentic domestic wastewater and industrial wastewater were collected to test in a continuous-flow stirred tank reactor. Factors influencing nitrification and denitrification such as the bioplate packing ratio (PR), hydraulic retention time (HRT), alkalinity (ALK; with Na2CO3), electron donor (with CH3OH), and aeration mode were investigated. With a reactor installed entrapped biomass (equivalent to as high as 7500 mg/L of biomass) to treat for an influent domestic wastewater containing 21-30 mg/L of NH3-N, the results showed 98% of ammonia nitrogen being converted to nitrate and 58% of TN removal at HRT of 6 h, and the effluent concentration of NH3-N was under 1 mg/L. EBP has exhibited its’ good performance on TN removal. The nitrogen removal capacity (NRC) was 56 g TN/m3•d and EBP weight loading (EWL) was 8.7 g TN/kg•d. The other further result was 98% of ammonia nitrogen would be converted to nitrate, 64% of TN removal, and 80% of SCOD removal at HRT of 12 h. It revealed organic carbon removal, nitrification and denitrification were concurrent in a single pass. When EBP coupled with the activated sludge process (ASP) for TN removal, nitrification efficiency exceeded 99% and TN removal of 70% was achieved for an influent domestic wastewater containing 21-54 mg/L of NH3-N at HRT of 12 h, and the effluent concentration of NH3-N was N.D.-3 mg/L, the effluent concentration of TN was 7-15 mg/L. The other result was 98% of ammonia nitrogen would be converted to nitrate, and 63% of TN removal at another HRT of 6 h. The NRC was 68 g TN/m3•d and EWL was 17.4 g TN/kg•d. The performance of TN removal was much better. While expanding ASP coupled with EBP for TN removal from industrial wastewater containing low carbon-nitrogen ratio, entrapped biomass technology could still display good applications. The coupled system enabled over 88% of nitrification and promoted denitrification that led to 58% removal of TN at HRT of 12 h with 15000 mg/L of entrapped biomass as well as MLSS 1500-2400 mg/L, and the concentration of NH3-N would descend from 98 mg/L to 27 mg/L. The coupled process readily upgraded an activated sludge aeration basin to an AO or A2O reactor. The study has demonstrated that entrapped biomass technology creates anoxic/anaerobic zones that are capable of carrying out denitrification, requiring no substantial modifications of the vessel as well as operation, and thus providing improved treatment in terms of nitrogen removal in conventional suspended-growth process. In aeration basin, nitrification can be proceeded in the outer part of the EBP. The intra space of the bioplate becomes anaerobic environment where denitrification process occurs due to mass transport limit. DO is the critical factor affecting the performance of nitrification and denitrification. When ASP coupled with EBP, ASP carried out nitrification, organic carbon removal, and depleted DO in the system, where enabled EBP creating more anoxic/anaerobic environments in the intra space that augmented coupled nitrification/denitrification processes to occur. Their synergy empowered conventional aeration basin for TN removal.