@misc{10481/87319,
year = {2019},
url = {https://hdl.handle.net/10481/87319},
abstract = {Methyl tert-butyl ether (MTBE) degradation technologies based on two-phase partitioning systems such as extractive membrane biofilm reactors (EMBFR) permit separation of biological and contaminant compartments, thus allowing optimization of the biological section. In this study, we set-up an EMBFR with three MTBE-degrading and cooperating strains (termed social biofilm: Agrobacterium sp. MS2, Paenibacillus etheri SH7T and Rhodococcus ruber EE6). The removal efficiency of the social-biofilm EMBFR was 80%, and functional stability was observed in the reactor, i.e. more efficient than previous studies (single-strain inoculated EMBFR, <50% removal efficiency and unstable function). Metabolite tert-butyl alcohol was not observed, and the EC50 values were higher than those observed in single-strain EMBFRs. Comparative analysis of the MTBE enzymatic pathway and the social-biofilm was performed, where the mechanism of cooperation observed within the social-biofilm is likely due to enzymatic redundancy. Functional outcomes were equal to previous batch tests, hence 100% scalability was obtained. Overall, higher functional and stability outcomes are obtained with the use of the social-biofilm in an MTBE-EMBFR.},
publisher = {Elsevier},
keywords = {BSocial},
keywords = {HTGrowth},
title = {Social microbial inocula confer functional stability in a methyl tert-butyl ether extractive membrane biofilm bioreactor},
doi = {10.1016/j.envpol.2018.10.100},
author = {Purswani, Jessica and Guisado Requena, Isabel María and Coello-Cabezas, Julio and González López, Jesús Juan and Pozo Llorente, Clementina},
}