Perspectives on Potential Applications of Nanometal Derivatives in Gaseous Bioenergy Pathways: Mechanisms, Life Cycle, and Toxicity

Elsamadony, Mohamed; Elreedy, Ahmed; Mostafa, Alsayed; Fujii, Manabu; Gescher, Johannes; Yekta, Sepehr Shakeri; Schnürer, Anna; Gaillard, Jean François; Pant, Deepak

doi:10.1021/acssuschemeng.1c02260

Cited by 27 publications

(3 citation statements)

References 229 publications

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“…In contrast, the discolouration during non-feeding periods (data did not showed) could be related to oxidation of Fe 2+ from magnetite delivering additional electrons for methanogenesis [ 15 ]. Furthermore, magnetite itself is a conductive mineral and has been shown to compensate for the deficiency of e-pilins, enabling probably direct electron transfer from fermenting organisms to methanogens [ 32 , 35 , 36 ].…”

Section: Discussionmentioning

confidence: 99%

Adaptation of a microbial community to demand-oriented biological methanation

Aghtaei

Benndorf

Reichl

2022

Biotechnol Biofuels

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Background Biological conversion of the surplus of renewable electricity and carbon dioxide (CO2) from biogas plants to biomethane (CH4) could support energy storage and strengthen the power grid. Biological methanation (BM) is linked closely to the activity of biogas-producing Bacteria and methanogenic Archaea. During reactor operations, the microbiome is often subject to various changes, e.g., substrate limitation or pH-shifts, whereby the microorganisms are challenged to adapt to the new conditions. In this study, various process parameters including pH value, CH4 production rate, conversion yields and final gas composition were monitored for a hydrogenotrophic-adapted microbial community cultivated in a laboratory-scale BM reactor. To investigate the robustness of the BM process regarding power oscillations, the biogas microbiome was exposed to five hydrogen (H2)-feeding regimes lasting several days. Results Applying various “on–off” H2-feeding regimes, the CH4 production rate recovered quickly, demonstrating a significant resilience of the microbial community. Analyses of the taxonomic composition of the microbiome revealed a high abundance of the bacterial phyla Firmicutes, Bacteroidota and Thermotogota followed by hydrogenotrophic Archaea of the phylum Methanobacteriota. Homo-acetogenic and heterotrophic fermenting Bacteria formed a complex food web with methanogens. The abundance of the methanogenic Archaea roughly doubled during discontinuous H2-feeding, which was related mainly to an increase in acetoclastic Methanothrix species. Results also suggested that Bacteria feeding on methanogens could reduce overall CH4 production. On the other hand, using inactive biomass as a substrate could support the growth of methanogenic Archaea. During the BM process, the additional production of H2 by fermenting Bacteria seemed to support the maintenance of hydrogenotrophic methanogens at non-H2-feeding phases. Besides the elusive role of Methanothrix during the H2-feeding phases, acetate consumption and pH maintenance at the non-feeding phase can be assigned to this species. Conclusions Taken together, the high adaptive potential of microbial communities contributes to the robustness of BM processes during discontinuous H2-feeding and supports the commercial use of BM processes for energy storage. Discontinuous feeding strategies could be used to enrich methanogenic Archaea during the establishment of a microbial community for BM. Both findings could contribute to design and improve BM processes from lab to pilot scale.

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Section: Discussionmentioning

confidence: 99%

Adaptation of a microbial community to demand-oriented biological methanation

Aghtaei

Benndorf

Reichl

2022

Biotechnol Biofuels

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“…ACS SCE perspectives that contain a compelling account of scientific and sustainability attributes of the reviewed topic will not only satisfy the desired quality features but also have a high probability of paving the way for future scientific and technological advances. We refer prospective authors to a sampling of recent articles, − where they will gain a better understanding of the attributes of published ACS SCE perspectives.…”

Section: Beyond a Good Review: Elements Of An Acs Sce Perspectivementioning

confidence: 99%

Expectations for Perspectives in ACS Sustainable Chemistry & Engineering

Allen¹,

Carrier²,

Chen³

et al. 2021

ACS Sustainable Chem. Eng.

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“…Microbial activity is directly responsible for the biohydrogen generating process and is the most crucial aspect to consider. Supplementing highly conductive nanomaterials (such as graphene, graphene oxide (GO), and reduced graphene oxide (RGO)) to anaerobes has been considered a promising solution for enhancing H 2 -producing bacterial activities in the fermentation process. , Graphene has unique characteristics such as large specific surface area, high mechanical strength, high chemical stability, high biocompatibility, and excellent electrical and thermal conductivity, with a great potential to improve the stability and efficiency of fermentation. , Previous studies have shown that graphene is a strong candidate for improving bacterial proliferation and enhancing biological activity. Despite the aforementioned merits, graphene is still a prohibitively costly material for large-scale applications.…”

Section: Introductionmentioning

confidence: 99%

Stimulating the Fermentation Process of Industrial Food Waste via Nonionic Surfactant/Graphene Nanosheet Combined Supplementation

et al. 2022

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The synergistic impact of Tween 80 (T80) and reduced graphene oxide (RGO) on the codigestion process of food waste and biscuit wastewater via an anaerobic sequential batch reactor was investigated in this study. The T80/RGO-amended reactor exhibited a hydrogen yield of 313.2 ± 89.3 mL/gCODinitial, which is 1.98-fold higher than that of the control. This increase was a consequence of the increase of hydrogenase enzyme activity from 0.24 ± 0.11 to 0.46 ± 0.15 mg MBreduced/min, as well as the stimulation of hydrolytic enzyme activities (i.e., α-amylase, xylanase, CM-cellulase, polygalacturonase, protease, and lipase). Likewise, microbial community analysis revealed that the relative abundances of genera Acinetobacter, Syntrophomonas, and Clostridium (H2-producing species) were enhanced from 3.9, 2.3, and 2.8% to 10.8, 9.1, and 3.6%, respectively, when T80/RGO was supplemented. On the other hand, molecular docking analysis was performed to explore the interaction of the hydrogenase protein with RGO (binding score: −10.1 kcal/mol) and T80 (binding score: −4.1 kcal/mol) as possible targets with active site residues. Eventually, supplementation of the T80/RGO mixture could stimulate the efficiency of the fermentative hydrogen process and, consequently, be used in practical engineering applications.

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Perspectives on Potential Applications of Nanometal Derivatives in Gaseous Bioenergy Pathways: Mechanisms, Life Cycle, and Toxicity

Cited by 27 publications

References 229 publications

Adaptation of a microbial community to demand-oriented biological methanation

Adaptation of a microbial community to demand-oriented biological methanation

Expectations for Perspectives in ACS Sustainable Chemistry & Engineering

Stimulating the Fermentation Process of Industrial Food Waste via Nonionic Surfactant/Graphene Nanosheet Combined Supplementation

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