posted on 2024-05-17, 09:29authored byMin Long, Chen-Wei Zheng, Manuel A. Roldan, Chen Zhou, Bruce E. Rittmann
PFAS
(poly- and per-fluorinated alkyl substances) represent
a large
family of recalcitrant organic compounds that are widely used and
pose serious threats to human and ecosystem health. Here, palladium
(Pd0)-catalyzed defluorination and microbiological mineralization
were combined in a denitrifying H2-based membrane biofilm
reactor to remove co-occurring perfluorooctanoic acid (PFOA) and nitrate.
The combined process, i.e., Pd-biofilm, enabled continuous removal
of ∼4 mmol/L nitrate and ∼1 mg/L PFOA, with 81% defluorination
of PFOA. Metagenome analysis identified bacteria likely responsible
for biodegradation of partially defluorinated PFOA: Dechloromonas sp. CZR5, Kaistella
koreensis, Ochrobacterum anthropic, and Azospira sp. I13. High-performance
liquid chromatography-quadrupole time-of-flight mass spectrometry
and metagenome analyses revealed that the presence of nitrate promoted
microbiological oxidation of partially defluorinated PFOA. Taken together,
the results point to PFOA-oxidation pathways that began with PFOA
adsorption to Pd0, which enabled catalytic generation of
partially or fully defluorinated fatty acids and stepwise oxidation
and defluorination by the bacteria. This study documents how combining
catalysis and microbiological transformation enables the simultaneous
removal of PFOA and nitrate.