Membrane bioreactor (MBR) processes, in which membrane filtration is combined with biological degradation for biomass separation, have attracted great attention recently because of their advantages over conventional activated sludge processes, including a smaller footprint, less sludge production and superior effluent quality. However, their wide applications have been hindered by their excessive operation cost due to membrane fouling. Membrane fouling reduces water production and membrane lifespan, thereby, increasing operation and maintenance costs. Many studies have been devoted to exam the mechanisms of fouling and fouling mitigation in MBRs. Despite such intensive efforts, no conclusion on the cause of MBR fouling has been agreed upon, which may be due to the complication of mixed liquor and influent, module design and operation conditions implemented in various studies. Membrane fouling is the interaction between sludge and membrane, which results in adsorption or deposition of components in sludge on membrane surface. As a result, characteristics of sludge and membrane and hydrodynamic conditions are vital factors affecting membrane fouling in MBRs. In this study, the impact of sludge characteristics on membrane fouling in a submerged MBR was investigated. Bulking sludge due to excessive growth of filamentous bacteria was changed to normal sludge by use of an aerobic selector. Excellent effluent quality was achieved in the MBR regardless of the quality of the sludge of the bioreactor. However, serious fouling was observed when bulking sludge occurred and filamentous bacteria were found dominant in the reactor despite the larger particle size distribution of the sludge. Filamentous bacteria were found to produce more SMP including soluble polysaccharides and soluble proteins in the mixed liquor, which contributed to severe fouling in bulking sludge, in particular, the release of high concentration of soluble polysaccharides. Bound extracellular bound substances (EPS) which was found similar in the normal sludge and bulking sludge was not the cause for membrane fouling in this case. Sludge retention time (SRT) has been found to alter sludge characteristics and therefore, have significant impact on membrane fouling. Shorter SRT (10 days) resulted in higher fouling propensity most likely due to higher SMP in the mixed liquor. Despite the similar amount of SMP in mixed liquor, fouling rate at SRT 30 days was higher than SRT 60 days. This may be due to the higher content of bound EPS in sludge flocs at SRT 30 days, resulting in higher specific cake resistance. SMP was found to have larger molecular weight at shorter SRT. Dynamic membranes which can reject small components such as solutes in mixed liquor were formed on the membrane in the beginning of the filtration. The dynamic membrane would not cause apparent membrane fouling but improved membrane rejection instead. Hydrophilic fraction which was accumulated in the mixed liquor was the dominant species in SMP. Hydrophilic carbohydrates were most likely the major foulants at SRT 10 days . To reduce membrane fouling, titanium dioxide (TiO2) composite membranes were prepared. A chemical copreciptization-peptization method was used to produce TiO2 nanoparticles in neutral sol. The composite membranes were prepared by dip-coating the membrane in the neutral TiO2 sol and also in acidic TiO2 suspension. Filtration tests showed that membrane fouling was reduced in both cases possibly due to the increase in hydrophilicity of the membrane. Results showed that optimal amount of coating is important in fouling mitigation. Too much TiO2 on membrane surface deteriorated membrane filtration due to the blocking of membrane pores. The ultrasonic washing test showed that most TiO2 particles were firmly coated on the surface of the TiO2 composite membrane.