Growth and current production of mixed culture anodic biofilms remain unaffected by sub-microscale surface roughness

Pierra, Mélanie; Golozar, Mehdi; Zhang, Xu; Prévoteau, Antonin; Volder, Michaël De; Reynaerts, Dominiek; Rabaey, Korneel

doi:10.1016/j.bioelechem.2018.04.002

Cited by 14 publications

(12 citation statements)

References 41 publications

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“…However, recent studies have shown that although structurest hat are small compared to the biofilm thickness can influence biofilm attachment and initial growth,t hey do not significantly enhance long-term performance. [19][20][21] Macrostructures with ac omparatively larger size [22] can, however,d rastically increaset he current density,w hichh as been shown by several studies with specific 3D macrostructure designs. [15,17,23] Here, clogging of the 3D structures during the biofilm growth represents a major obstacle that needs to be overcome.…”

Section: Introductionmentioning

confidence: 95%

“…The introduction of small structures (i.e., nanometer or micrometer scale) can drastically increase the electrochemically active surface area of an electrode. However, recent studies have shown that although structures that are small compared to the biofilm thickness can influence biofilm attachment and initial growth, they do not significantly enhance long‐term performance . Macrostructures with a comparatively larger size can, however, drastically increase the current density, which has been shown by several studies with specific 3 D macrostructure designs .…”

Section: Introductionmentioning

confidence: 99%

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The Limits of Three‐Dimensionality: Systematic Assessment of Effective Anode Macrostructure Dimensions for Mixed‐Culture Electroactive Biofilms

2019

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This study analyzes the biofilm growth and long‐term current production of mixed‐culture, electrochemically active biofilms (EABs) on macrostructured electrodes under low‐shear‐force conditions. The channel dimensions were altered systematically in the range 400 μm to 2 mm, and the channel heights were varied between 1 and 4 mm to simulate macrostructures of different scales. Electrodes with finer‐structured surfaces produced higher current densities in the short term owing to their large surface area but were outperformed in the long term because the accumulation of biomass led to limitations of mass transfer into the structures. The best long‐term performance was observed for electrodes with channel dimensions of 1×4 mm, which showed no significant decrease in performance in the long term. Channels with a diameter of 400 μm were overgrown by the biofilm, which led to a transition from 3 D to 2 D behavior, indicating that structures of this scale might not be suitable for long‐term operation under low‐shear‐stress conditions.

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Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

The Limits of Three‐Dimensionality: Systematic Assessment of Effective Anode Macrostructure Dimensions for Mixed‐Culture Electroactive Biofilms

2019

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“…Especially, the core element bioanode is in the focus of research and development. Independent from the electrode material, chemical and physical modifications have been applied successfully to increase electrode performances in BES (He et al, 2011;Guo et al, 2013;Kipf et al, 2013;Artyushkova et al, 2015;Baudler et al, 2015;Champigneux et al, 2018;Pierra et al, 2018;Moß et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Rational Selection of Carbon Fiber Properties for High-Performance Textile Electrodes in Bioelectrochemical Systems

et al. 2019

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Novel applications of bioelectrochemical systems (BES) are emerging constantly, but the majority still lacks economic viability. Especially the use of electrochemical system components without adaptation to BES requirements causes poor exploitation of the potential system performance. The electrode material is one central component that determines BES performance. While commercial carbon fiber (CF) fabrics are commonly used, their customizability as two-or three-dimensional electrode material for BES is rarely investigated. Using pure cultures of S. oneidensis MR-1, we identified CF properties impacting bacterial current generation: (1) The removal of the sizing (protective coating) is of great importance for all the fibers studied, as it acts as an electrical insulator. By desizing, the maximum current density (j max) is increased by up to 40-fold. (2) Alteration of the filament surface chemistry results in an accelerated initial development of current generation, but the maximum current density (j max) is hardly affected. (3) A specific yarn structure, the stretch-broken yarn, supports exceptionally high current densities. The good electrode performance is correlated to the presence of free filament ends (responsible for 41% current increase), which are characteristic for this yarn. (4) Moreover, a combination of these free filament ends with a high degree of graphitization enhances electrode performance of a commercial fabric by 100%. The results demonstrate that the CF selection can greatly influence the achievable electrode performance of CF fabrics, and thereby contributes to rational engineering of CF based electrodes that can be tailored for the many BES applications envisaged.

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“…According to our analysis the cAD1 precursor and its orthologs from other bacteria are encoded by genes adjacent to apbE homologs (Figure 2-Figure 5). A number of mentioned above Firmicutes genera [32], [33] and particularly Listeria [34], Catonella [35] representatives, as well as Bacteroidia (Bacteroides) [36], were considered as electrogenic and shown to populate MFCs [4] under different conditions. We show that cAD1 precursor has two sites specific for ApbE-dependent FMN insertion (TGAT) ( Figure 7), and its homologs have at least one FMN covalent binding insertion motif.…”

Section: Discussionmentioning

confidence: 99%

Is there a Function for a Sex Pheromone Precursor?

Vasieva

Goryanin

2019

Journal of Integrative Bioinformatics

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Functional coupling and comparative genomics analysis have been applied to study functional associations of orthologs of enterococcal cAD1 sex pheromone (P13268) known to be responsible for biofilm formation, conjugative plasmid transfer and spreading of bacterial antibiotics resistance. cAD1 peptide pheromone is released from the membrane lipoprotein with the peptide precursor encoded by a gene cad (tr|C2JQE7). Our analysis of genomic neighbourhood of cad and motifs of the encoded polypeptide and its orthologs suggests a close functional association between cAD1 and ApbE protein (Q82Z24), a FMN insertion and trafficking facilitator. The cad and apbE orthologs were coupled in the genomes and ApbE-specific motifs for FMN covalent attachment were identified in cad-encoded protein sequence and its orthologs. These findings suggest a potential role of FMN-based reductase function of the cAD1 lipoprotein precursor in its processing and release of the active sex pheromone peptide. They may lead to a new approach in prevention of antibiotic resistance spread via targeting sex pheromone processing chaperones or by suppression of the FMN availability and covalent binding. This methods can be also applied to a controlled evolution of bacterial pathogenicity in microbial fuel cells, as the findings suggest the crosstalk between bacterial pathogenicity and bacterial electro-activity.

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Growth and current production of mixed culture anodic biofilms remain unaffected by sub-microscale surface roughness

Cited by 14 publications

References 41 publications

The Limits of Three‐Dimensionality: Systematic Assessment of Effective Anode Macrostructure Dimensions for Mixed‐Culture Electroactive Biofilms

The Limits of Three‐Dimensionality: Systematic Assessment of Effective Anode Macrostructure Dimensions for Mixed‐Culture Electroactive Biofilms

Rational Selection of Carbon Fiber Properties for High-Performance Textile Electrodes in Bioelectrochemical Systems

Is there a Function for a Sex Pheromone Precursor?

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