Manuel Alarcón-ViveroNathaly Ruiz-Tagle MoenaFidelina GonzalezJopia, PazPazJopiaEstrella AspéHomero Urrutia BrionesKatherine Sossa Fernandez2025-12-072025-12-072022-01-1710.1007/s10529-021-03213-y2-s2.0-85123071418https://cris-uv-2.scimago.es/handle/123456789/7595WOS:000743014600003The digestion efficiency of liquid industrial wastes increases when using bioreactors colonized by microbial biofilms. High concentrations of proteins derived from the fish processing industry lead to the production of ammonia, which inhibits methane production. Two bioreactors were constructed to compare methanogenic activity: one enriched with mMPA (methylaminotrofic methane production archaea) consortia (control bioreactor), and the second with NH3tolerant consortia (treatment bioreactor). Ammonia tolerant activity was assessed by applying an ammonia shock (755 mg NH3/L). Methane production, consumption of total organic carbon (TOC) and the taxonomic composition of bacteria and archaea was evaluated using 16S rDNA in the acclimatization, ammonia shock, and recovery phases.The ammonia shock significantly affected both methane production and the consumption of TOC in the control reactor (p< 0.05) and taxonomical composition of the microbial consortia (OTU). These values remained constant in the treatment reactor. The analysis of biofilm composition showed a predominance of Methanosarcinaceae (Methanomethylovoranssp., and probably two different species ofMethanosarcinasp.) in bioreactors. These results demonstrate that using acclimated biofilms enriched with ammonia tolerant methanogens control the inhibitory effect of ammonia on methanogenesis.enacceso restringidoObstetrics and Gynecologyartículo