Complete removal of ammonia and pho

Complete removal of ammonia and phosphorus from aquaculture wastewater is crucial since they are mostly associated with the eutrophication of water bodies (Gregory et al., 2012; Mook et al., 2012). MA had been reported in many laboratory studies as excellent bioremediators in treating nutrient concentrated wastewater (Di Termini et al., 2011; Arbib et al., 2012). In addition, MA had also been proven to effectively remediation ammonia and phosphorus concentrated wastewater in the uncontrolled field condition (Godos et al., 2009; Arbib et al., 2012). Ammonia and phosphorus absorbed were assimilated in the cell biomass as protein and polyphosphate (Rawat et al., 2011). Phosphorus from the wastewater was oxidized to produce energy in the aerobic condition. The energy generated from this transformation process was used by the MA for its growth and cell metabolism. Phosphorus of concentration of more than 6 mg L 1 could lead to the explosive growth of MA (Ahmad et al., 2013). In the presence of oxygen, the toxic ammonia present in the wastewater would undergo spontaneous bacterial oxidation converting it subsequently into nitrite and nitrate. This explains the global problem of aquaculture effluent which turns ponds and lakes gradually into marshes. Since ammonia and phosphorus are ecologically significant in MA productivity, their proper removal from release to the aquatic water bodies is quintessential to prevent the occurrence of eutrophication.

The role of EM was mainly to enhance the phytoremediation efficiency of MA in absorbing phosphorus. Without the addition of EM, independent MA phytoremediation mode ineffectively removed the nutrient from the wastewater. Most of the bioconversion of contaminant into stable form of ammonia and phosphorus were carried out by EM which was then absorbed by the MA biomass. However, EM shown no significant enhancement in the removal of ammonia of symbiotic MA-EM bioremediation mode.