Spectroscopic and elemental investigation of microbial decomposition of aquatic fulvic acid in biological process of drinking water treatment

Shin, Hang‐Sik; Lim, Kyeong-Ho

doi:10.1007/bf00115742

Cited by 18 publications

(22 citation statements)

References 21 publications

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“…A microbial degradation of aquatic HS has been repeatedly reported [3,24,25]. Despite of this, only little knowledge exists about the microorganisms and possible mechanims involved in the process.…”

Section: Discussionmentioning

confidence: 99%

Degradation and Transformation of Aquatic Humic Substances by Laccase-producing FungiCladosporium cladosporioides andPolyporus versicolor

Claus

Filip²

1998

Acta hydrochim. hydrobiol.

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Section: Discussionmentioning

confidence: 99%

Degradation and Transformation of Aquatic Humic Substances by Laccase-producing FungiCladosporium cladosporioides andPolyporus versicolor

Claus

Filip²

1998

Acta hydrochim. hydrobiol.

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“…A large variety of bacterial consortia capable of degrading HSs were isolated from soil [ 9 , 13 , 14 , 93 , 94 ], coal [ 20 ], or aquatic environments [ 2 , 95 , 96 , 97 , 98 ], including marine and estuarine waters [ 6 , 99 , 100 ]. According to the data presented by Yanagi and coauthors [ 14 ], the population of total bacteria that were capable of degrading soil HAs varied from 0.1 × 10 6 to 2.8 × 10 6 CFU g −1 of soil, forming 0.2–3.5% of the total microbe density.…”

Section: Utilization Degradation and Transformation Of Hss By Bacteriamentioning

confidence: 99%

“…Bacterial and fungal utilization of HSs results in the alteration of HS properties, including a decrease in molecular weight [ 96 , 147 , 148 , 154 , 155 , 174 ], a loss of carbohydrates [ 13 , 175 ], a loss of aliphatics and an increase in aromatics [ 13 , 38 , 73 , 96 , 176 , 177 , 178 , 179 ], increased aromaticity [ 147 ], utilization of the polysaccharides [ 180 , 181 ], a loss of peptides [ 40 , 180 ], alteration of the C/N ratio [ 9 , 13 , 40 , 54 ], and oxidation [ 96 ]. Peroxidase and phenoloxidase enzymes, which are excreted by microorganisms to utilize HSs, can catalyze not only oxidative polymerization of phenolic moieties of HSs but also the oxidative coupling of phenol and aniline pollutants [ 182 ].…”

Section: Utilization Degradation and Transformation Of Hss By Fungi In Soilmentioning

confidence: 99%

Interactions between Humic Substances and Microorganisms and Their Implications for Nature-like Bioremediation Technologies

Куликова

Perminova

2021

Molecules

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The state of the art of the reported data on interactions between microorganisms and HSs is presented herein. The properties of HSs are discussed in terms of microbial utilization, degradation, and transformation. The data on biologically active individual compounds found in HSs are summarized. Bacteria of the phylum Proteobacteria and fungi of the phyla Basidiomycota and Ascomycota were found to be the main HS degraders, while Proteobacteria, Actinobacteria, Bacteroidetes, and Firmicutes were found to be the predominant phyla in humic-reducing microorganisms (HRMs). Some promising aspects of interactions between microorganisms and HSs are discussed as a feasible basis for nature-like biotechnologies, including the production of enzymes capable of catalyzing the oxidative binding of organic pollutants to HSs, while electron shuttling through the utilization of HSs by HRMs as electron shuttles may be used for the enhancement of organic pollutant biodegradation or lowering bioavailability of some metals. Utilization of HSs by HRMs as terminal electron acceptors may suppress electron transfer to CO2, reducing the formation of CH4 in temporarily anoxic systems. The data reported so far are mostly related to the use of HSs as redox compounds. HSs are capable of altering the composition of the microbial community, and there are environmental conditions that determine the efficiency of HSs. To facilitate the development of HS-based technologies, complex studies addressing these factors are in demand.

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“…Biological filtration preferentially removes low molecular weight (LMW) compounds 41,42 that may be present in wildfireimpacted source waters. 14 Accordingly, it may offer treatment resilience in buffering elevated source water DOM after wildfire.…”

Section: Introductionmentioning

confidence: 99%

“…Substantial reductions in UVA254 across the biofilters were not expected because (i) UVA254 reflects both DOC concentration and aromaticity, 68 (ii) WEOM is typically more aromatic when an impact of wildland fire on source water DOM is observed, 14 and (iii) aromatic DOC is less biodegradable than more aliphatic DOC. 41,42,69 Thus, while the biofilters were able to reduce UVA254 somewhat, the extent of removal diminished as more of the influent UVA254 was derived from wildfire ash addition (i.e., higher ash content). Importantly, the biofilter DOC, UVA254, and LC-OCD removal data collectively demonstrate that while the biofilters were not designed to mimic all aspects of full-scale biofiltration (especially not operational aspects such as headloss accumulation), they provided representative and therefore reasonable indication of the biodegradation capabilities of biological filtration processes.…”

Section: Introductionmentioning

confidence: 99%

Biological filtration is resilient to wildfire ash-associated organic carbon threats to drinking water treatment

Blackburn

Emelko

Dickson‐Anderson

et al. 2022

Preprint

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Elevated/altered levels of dissolved organic matter (DOM) in water can be challenging to treat after wildfire. Biologically-mediated treatment removes some DOM; its ability to remove elevated/altered post-fire dissolved organic carbon (DOC) resulting from wildfire ash was therefore investigated. The treatment of low, medium, and high wildfire ash-amended source waters by bench-scale biofilters was evaluated in duplicate. Turbidity and DOC were typically well-removed during periods of stable operation (effluent turbidity ≤ 0.3 NTU in 93% of samples, average DOC removal ~20% in all biofilters during periods of non- impaired DOC removal). Daily DOC removal across all biofilters was generally consistent, suggesting that the wildfire ash and associated water extractable organic matter did not reduce the DOC biodegradation capacity of the biofilters. DOM fractionation indicated that this was because the low molecular weight neutral (which are known to be readily biodegradable) and biopolymer fractions of DOM were reduced; however, humics were largely recalcitrant. Thus, biological filtration may be resilient to wildfire ash-associated DOM threats to drinking water treatment. However, operational resilience may be compromised if the balance between readily removed and recalcitrant fractions of DOM change, as was observed when baseline source water quality fluctuated for brief periods during the investigation.

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Spectroscopic and elemental investigation of microbial decomposition of aquatic fulvic acid in biological process of drinking water treatment

Cited by 18 publications

References 21 publications

Degradation and Transformation of Aquatic Humic Substances by Laccase-producing FungiCladosporium cladosporioides andPolyporus versicolor

Degradation and Transformation of Aquatic Humic Substances by Laccase-producing FungiCladosporium cladosporioides andPolyporus versicolor

Interactions between Humic Substances and Microorganisms and Their Implications for Nature-like Bioremediation Technologies

Biological filtration is resilient to wildfire ash-associated organic carbon threats to drinking water treatment

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