Biodegradation of Emerging Pharmaceuticals from Domestic Wastewater by Membrane Bioreactor: The Effect of Solid Retention Time

Although conventional biological treatment plants can remove basic pollutants, they are ineffective at removing recalcitrant pollutants. Membrane bioreactors contain promising technology and have the advantages of better effluent quality and lower sludge production compared to those of conventional...

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Bibliographic Details
Published in:International journal of environmental research and public health 2021-03, Vol.18 (7), p.3395
Main Authors: Alobaidi, Raghad Asad Kadhim, Ulucan-Altuntas, Kubra, Mhemid, Rasha Khalid Sabri, Manav-Demir, Neslihan, Cinar, Ozer
Format: Article
Language:English
Subjects:
Analgesics
Atenolol
Bezafibrate
Biodegradability
Biodegradation
Biodegradation, Environmental
Biological activity
Bioreactors
Carbamazepine
Chemical oxygen demand
Cooperation
Diclofenac
Domestic wastewater
Drugs
Effluents
Membranes
Methods
Microorganisms
Nonsteroidal anti-inflammatory drugs
Paracetamol
Pharmaceutical Preparations
Pharmaceuticals
Pollutant removal
Pollutants
Pore size
Ranitidine
Retention
Retention time
Sewage
Sludge
Waste Disposal, Fluid
Waste Water
Wastewater
Water Pollutants, Chemical - analysis
Water treatment
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Summary:Although conventional biological treatment plants can remove basic pollutants, they are ineffective at removing recalcitrant pollutants. Membrane bioreactors contain promising technology and have the advantages of better effluent quality and lower sludge production compared to those of conventional biological treatment processes. In this study, the removal of pharmaceutical compounds by membrane bioreactors under different solid retention times (SRTs) was investigated. To study the effect of SRT on the removal of emerging pharmaceuticals, the levels of pharmaceuticals were measured over 96 days for the following retention times: 20, 30, and 40-day SRT. It was found that the 40-day SRT had the optimum performance in terms of the pharmaceuticals' elimination. The removal efficiencies of the chemical oxygen demand (COD) for each selected SRT were higher than 96% at steady-state conditions. The highest degradation efficiency was observed for paracetamol. Paracetamol was the most removed compound followed by ranitidine, atenolol, bezafibrate, diclofenac, and carbamazepine. The microbial community at the phylum level was also analyzed to understand the biodegradability of pharmaceuticals. It was noticed that the Proteobacteria phylum increased from 46.8% to 60.0% after 96 days with the pharmaceuticals. The Actinobacteria class, which can metabolize paracetamol, carbamazepine, and atenolol, was also increased from 9.1% to 17.9% after adding pharmaceuticals. The by-products of diclofenac, bezafibrate, and carbamazepine were observed in the effluent samples.
ISSN:1660-4601
1661-7827
1660-4601
DOI:10.3390/ijerph18073395