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W4372236352 startingPage "3253" @default.
W4372236352 abstract "The conductive microbial nanowires of Geobacter sulfurreducens serve as a model for long-range extracellular electron transfer (EET), which is considered a revolutionary “green” nanomaterial in the fields of bioelectronics, renewable energy, and bioremediation. However, there is no efficient pathway to induce microorganisms to express a large amount of microbial nanowires. Here, several strategies have been used to successfully induce the expression of microbial nanowires. Microbial nanowire expression was closely related to the concentration of electron acceptors. The microbial nanowire was around 17.02 μm in length, more than 3 times compared to its own length. The graphite electrode was used as an alternative electron acceptor by G. sulfurreducens, which obtained a fast start-up time of 44 h in microbial fuel cells (MFCs). Meanwhile, Fe(III) citrate-coated sugarcane carbon and biochar were prepared to test the applicability of these strategies in the actual microbial community. The unsatisfied EET efficiency between c-type cytochrome and extracellular insoluble electron receptors promoted the expression of microbial nanowires. Hence, microbial nanowires were proposed to be an effective survival strategy for G. sulfurreducens to cope with various environmental stresses. Based on this top-down strategy of artificially constructed microbial environmental stress, this study is of great significance for exploring more efficient methods to induce microbial nanowires expression." @default.
W4372236352 created "2023-05-07" @default.
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W4372236352 date "2023-05-05" @default.
W4372236352 modified "2023-10-16" @default.
W4372236352 title "In Situ Enhanced Yields of Microbial Nanowires: The Key Role of Environmental Stress" @default.
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W4372236352 cites W2010310758 @default.
W4372236352 cites W2014713696 @default.
W4372236352 cites W2026699540 @default.
W4372236352 cites W2040325568 @default.
W4372236352 cites W2053654950 @default.
W4372236352 cites W2103736180 @default.
W4372236352 cites W2111569769 @default.
W4372236352 cites W2112216401 @default.
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W4372236352 cites W2122382695 @default.
W4372236352 cites W2136503976 @default.
W4372236352 cites W2139531417 @default.
W4372236352 cites W2141403924 @default.
W4372236352 cites W2143043177 @default.
W4372236352 cites W2150497765 @default.
W4372236352 cites W2152308524 @default.
W4372236352 cites W2160549245 @default.
W4372236352 cites W2238071216 @default.
W4372236352 cites W2333894357 @default.
W4372236352 cites W2464811097 @default.
W4372236352 cites W2494999770 @default.
W4372236352 cites W2518467579 @default.
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W4372236352 cites W2563434948 @default.
W4372236352 cites W2566193558 @default.
W4372236352 cites W2571650024 @default.
W4372236352 cites W2624465165 @default.
W4372236352 cites W2791466455 @default.
W4372236352 cites W2802035147 @default.
W4372236352 cites W2807474578 @default.
W4372236352 cites W2811351352 @default.
W4372236352 cites W2873754355 @default.
W4372236352 cites W2885604963 @default.
W4372236352 cites W2891914072 @default.
W4372236352 cites W2893375367 @default.
W4372236352 cites W2904750190 @default.
W4372236352 cites W2915662218 @default.
W4372236352 cites W2929827553 @default.
W4372236352 cites W2948334032 @default.
W4372236352 cites W2951245862 @default.
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W4372236352 cites W2983888547 @default.
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W4372236352 cites W4240669697 @default.
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W4372236352 doi "https://doi.org/10.1021/acsbiomaterials.3c00313" @default.
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