Anammox-based granulation cycle for sustainable granular sludge biotechnology from mechanisms to strategies: A critical review

• Published in: Water research (Oxford) Vol. 228; p. 119353
• Main Authors: Xue, Yi, Ma, Haiyuan, Li, Yu-You
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.01.2023
• Subjects: Anammox granular sludge; EPS; Floatation; Machine learning; Nitrogen removal; Quorum sensing; Nitrogen removal; EPS; Quorum sensing; Floatation; Machine learning; Anammox granular sludge
• ISSN: 0043-1354; 1879-2448
• DOI: 10.1016/j.watres.2022.119353

•Granulation cycles including granulation and regeneration are proposed.•Various granulation mechanisms are summarized to understand anammox granules.•The rebuilding of a regeneration stage is a principle to avoid the granule floatation.•Future researches are focusing on understanding and evaluating the cycle. Anaerobic ammonium oxidation (anammox) granular sludge is a promising biotechnological process for treating low-carbon nitrogenous wastewater, and is featured with low energy consumption and footprint. Previous theoretical and experimental research on anammox granular sludge processes mainly focused on granulation (flocs → granules), but pay little attention to the granulation cycle including granulation and regeneration. This work reviewed the previous studies from the perspective of anammox granules lifecycle and proposed various sustainable formation mechanisms of anammox granules. By reviewing the anaerobic, aerobic, and anammox granulation mechanisms, we summarize the mechanisms of thermodynamic theory, heterogeneous growth, extracellular polymeric substance (EPS)-based adhesion, quorum sensing (QS)-based regulation, biomineralization-based growth, and stratification of microorganisms to understand anammox granulation. In the regeneration process, the formation of precursors for re-granulation is explained by the mechanisms of physical crushing, quorum quenching and dispersion cue sensing. Based on the granulation cycle mechanism, the rebuilding of the normal regeneration process is considered essential to avoid granule floatation and the wash-out of granules. This comprehensive review indicates that future research on anammox granulation cycle should focus on the effects of filamentous bacteria in denitrification-anammox granulation cycle, the role of QS/ quorum quenching (QQ)-based autoinducers, development of diversified mechanisms to understand the cycle and the cycle mechanisms of stored granules. [Display omitted]