SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2945481323> ?p ?o ?g. }

Showing items 1 to 100 of ±133 with 100 items per page.

W2945481323 endingPage "203" @default.
W2945481323 startingPage "195" @default.
W2945481323 abstract "Tricresyl phosphates (TCPs), a typical sort of organophosphate flame retardants, has received extensive concerns due to its potential adverse effects. However, limited information is available on the efficient and safe removal methods of TCPs. In this regard, TCPs were tentatively biodegraded with Brevibacillus brevis. A probable degradation pathway was further proposed with the cellular reactions discussed in detail. Experiments showed that B. brevis at 2 g L−1 could degrade 1 mg L−1 tri-m-cresyl phosphate, tri-p-cresyl phosphate, and tri-o-cresyl phosphate by 82.91%, 93.91%, and 53.92%, respectively, within five days. In the process of biodegradation, B. brevis metabolism caused the release of Na+ and Cl− as well as the absorption of some nutrient ions including K+, PO43−, Mg2+, and SO42−; the presence of oxalic acid, citric acid, acetic acid, and malonic acid was also detected. Similar metabolic pathways were found among different TCPs isomers, but tri-o-cresyl phosphate induced more reactive oxygen species than the other two did. This work develops novel insights into the potential mechanisms of TCPs biodegradation by microorganisms." @default.
W2945481323 created "2019-05-29" @default.
W2945481323 creator A5024502122 @default.
W2945481323 creator A5046870877 @default.
W2945481323 creator A5054313635 @default.
W2945481323 creator A5060002817 @default.
W2945481323 creator A5091878678 @default.
W2945481323 date "2019-10-01" @default.
W2945481323 modified "2023-10-14" @default.
W2945481323 title "Biodegradation of tricresyl phosphate isomers by Brevibacillus brevis: Degradation pathway and metabolic mechanism" @default.
W2945481323 cites W1979952021 @default.
W2945481323 cites W1980201477 @default.
W2945481323 cites W1991663589 @default.
W2945481323 cites W1992809577 @default.
W2945481323 cites W1999581026 @default.
W2945481323 cites W2000476894 @default.
W2945481323 cites W2003362229 @default.
W2945481323 cites W2033617232 @default.
W2945481323 cites W2038699706 @default.
W2945481323 cites W2052827499 @default.
W2945481323 cites W2053262071 @default.
W2945481323 cites W2055152340 @default.
W2945481323 cites W2072365871 @default.
W2945481323 cites W2077230968 @default.
W2945481323 cites W2077719071 @default.
W2945481323 cites W2084621113 @default.
W2945481323 cites W2092035009 @default.
W2945481323 cites W2114669693 @default.
W2945481323 cites W2148459799 @default.
W2945481323 cites W2170498207 @default.
W2945481323 cites W2172371128 @default.
W2945481323 cites W2186767830 @default.
W2945481323 cites W2256290870 @default.
W2945481323 cites W2273082041 @default.
W2945481323 cites W2278444706 @default.
W2945481323 cites W2325430016 @default.
W2945481323 cites W2528965042 @default.
W2945481323 cites W2550827096 @default.
W2945481323 cites W2592705497 @default.
W2945481323 cites W2596939200 @default.
W2945481323 cites W2602416959 @default.
W2945481323 cites W2609642430 @default.
W2945481323 cites W2614429330 @default.
W2945481323 cites W2758825045 @default.
W2945481323 cites W2761957983 @default.
W2945481323 cites W2778408161 @default.
W2945481323 cites W2781616392 @default.
W2945481323 cites W2789901560 @default.
W2945481323 cites W2789903778 @default.
W2945481323 cites W2790961933 @default.
W2945481323 cites W2796836357 @default.
W2945481323 cites W2805417508 @default.
W2945481323 cites W2883110016 @default.
W2945481323 cites W2883141144 @default.
W2945481323 cites W2884841081 @default.
W2945481323 cites W2888570755 @default.
W2945481323 cites W2894933370 @default.
W2945481323 cites W2901529523 @default.
W2945481323 cites W2908673407 @default.
W2945481323 cites W2913222645 @default.
W2945481323 cites W2914231073 @default.
W2945481323 cites W2920601146 @default.
W2945481323 doi "https://doi.org/10.1016/j.chemosphere.2019.05.188" @default.
W2945481323 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/31154180" @default.
W2945481323 hasPublicationYear "2019" @default.
W2945481323 type Work @default.
W2945481323 sameAs 2945481323 @default.
W2945481323 citedByCount "20" @default.
W2945481323 countsByYear W29454813232020 @default.
W2945481323 countsByYear W29454813232021 @default.
W2945481323 countsByYear W29454813232022 @default.
W2945481323 countsByYear W29454813232023 @default.
W2945481323 crossrefType "journal-article" @default.
W2945481323 hasAuthorship W2945481323A5024502122 @default.
W2945481323 hasAuthorship W2945481323A5046870877 @default.
W2945481323 hasAuthorship W2945481323A5054313635 @default.
W2945481323 hasAuthorship W2945481323A5060002817 @default.
W2945481323 hasAuthorship W2945481323A5091878678 @default.
W2945481323 hasConcept C107872376 @default.
W2945481323 hasConcept C13965031 @default.
W2945481323 hasConcept C157021035 @default.
W2945481323 hasConcept C175605896 @default.
W2945481323 hasConcept C178790620 @default.
W2945481323 hasConcept C185592680 @default.
W2945481323 hasConcept C196222841 @default.
W2945481323 hasConcept C2777132085 @default.
W2945481323 hasConcept C2779679103 @default.
W2945481323 hasConcept C41008148 @default.
W2945481323 hasConcept C523546767 @default.
W2945481323 hasConcept C54355233 @default.
W2945481323 hasConcept C55493867 @default.
W2945481323 hasConcept C62231903 @default.
W2945481323 hasConcept C76155785 @default.
W2945481323 hasConcept C86803240 @default.
W2945481323 hasConceptScore W2945481323C107872376 @default.
W2945481323 hasConceptScore W2945481323C13965031 @default.
W2945481323 hasConceptScore W2945481323C157021035 @default.
W2945481323 hasConceptScore W2945481323C175605896 @default.