Anaerobic ammonium oxidation process (Anammox) is a novel technology developed for nitrogen removal, especially for wastewater with high organic nitrogen content. However, limitations of its full-scale application include (1) low bacterial growth rate and long doubling time (approximately 7 to 12 day), and (2) requirement of severe operation conditions for bacterial cultivation. The objectives of this study were to establish an anammox reactor from domestic wastewater sludge and investigate the effects of porous material to bacterial aggregation in the reactor. A lab-scale reactor was used to cultivate Anammox bacteria. The results show that the Anammox reactor can achieve over 99% of nitrogen removal efficiencies with the maximum concentrations of nitrite and ammonium of 700 mg/L and 490 mg/L, respectively. The microbial community analysis of this Anammox system revealed that over 99% of bacteria were phylogenetically close to Cadidatus Kuenenia stuttgartiensis. The addition of the porous material increased the sludge settling velocity; the sludge volume index decreased from 175 to 114. However, it significantly decreased the removal efficiencies of ammonia and nitrite (<50%). The removal efficiencies slowly recovered and remained at a steady state (>95%) after 40 days of porous material addition. The results of real-time quantitative PCR using functional-gene-specific primers indicated that the addition of porous material may have adverse effects on Anammox bacteria while it may favor the growth of denitrification bacteria. The study reveals that the addition of porous material may enhance sludge settling and aggregation, however, it tends to lower nitrogen removal efficiency of Anammox system.