Performance Improvement and Biofouling Mitigation in Osmotic Microbial Fuel Cells via In Situ Formation of Silver Nanoparticles on Forward Osmosis Membrane

Lu, Yuqin; Jia, Jia; Miao, Hengfeng; Ruan, Wenquan; Wang, Xinhua

doi:10.3390/membranes10060122

Cited by 23 publications

(14 citation statements)

References 52 publications

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“…Thus, the quantity and distribution of bacteria, EPS, and other metabolites can be determined (Zhu et al, 2016), (Xu et al, 2012). In their investigation, Xu et al (2020) proved that the use of the CLSM technique allowed a comparison of protein and polysaccharide contents between membranes. Furthermore, the thickness of the biofouling layer could also be measured by CLSM [40].…”

Section: Biofilm Architecture Investigationmentioning

confidence: 99%

Prevention and removal of membrane and separator biofouling in bioelectrochemical systems: a comprehensive review

et al. 2022

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Section: Biofilm Architecture Investigationmentioning

confidence: 99%

Prevention and removal of membrane and separator biofouling in bioelectrochemical systems: a comprehensive review

et al. 2022

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“…Furthermore, the stress produced by the water cluster and applied on the water in the cluster is relatively small. However, for the negative electrode of the membrane, the higher the water absorption, the larger the inflation of the hydrophilic domains [14].…”

Section: Introductionmentioning

confidence: 99%

Study on the Effect of Water Flux in Osmotic Microbial Fuel Cells on Membrane Water Content and Resistance

Zhao

Song

Duan

2022

Water

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Osmotic microbial fuel cells (OsMFCs) can integrate forward osmosis into microbial fuel cells (MFCs), which are able to perform organic elimination, bioenergy production, and high-class water abstraction from wastewater. However, it is not well understood how the unique feature of OsMFCs, i.e., water flux, helps improve current generation. Based on experimental studies and the Springer model theory, a new method for representing water transmission in OsMFC membranes is put forward that considers water transmission by electro-osmosis resulting from proton flux through the membrane and by osmosis resulting from osmotic pressure grades of water. In this research, osmotic water transmission is associated with the permeable differential pressure resulting from the ionic differential concentration in the membrane, and electro-osmotic water transmission is found to be proportional to the current density employed but irrelevant to the composition gradients. The net water transmission in OsMFC depends on the operation time and increases accordingly with higher current density and composition gradients. Furthermore, the membrane’s proton conductibility and water-transmission capabilities are significantly affected by the moisture content, which decreases from the negative electrode to the positive electrode in the OsMFC system. Increasing water flux with higher osmotic pressure and current density is therefore able to diminish the resistance of the membrane.

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“…These functional coatings allow for the modification of the pore size and geometry (cone-shaped pores) and also improve the biocompatibility and pre-selection of diffusive transport properties [ 13 ]. Finally, it is desirable to cover the surface with specific materials to reduce the biofouling effect of nanoporous membranes, with various techniques such as plasma jet, laser topological covering with hydrophilic/charged/polyethylene glycol networks, and the hydrophobic carbon coating currently available [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

Nanoporous Membranes for the Filtration of Proteins from Biological Fluids: Biocompatibility Tests on Cell Cultures and Suggested Applications for the Treatment of Alzheimer’s Disease

Schreiner

Tamba

Mihai

et al. 2022

JCM

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Background: Alzheimer’s disease has a significant epidemiological and socioeconomic impact, and, unfortunately, the extensive research focused on potential curative therapies has not yet proven to be successful. However, in recent years, important steps have been made in the development and functionalization of nanoporous alumina membranes, which might be of great interest for medical use, including the treatment of neurodegenerative diseases. In this context, the aim of this article is to present the synthesis and biocompatibility testing of a special filtrating nano-membrane, which is planned to be used in an experimental device for Alzheimer’s disease treatment. Methods: Firstly, the alumina nanoporous membrane was synthesized via the two-step anodizing process in oxalic acid-based electrolytes and functionalized via the atomic layer deposition technique. Subsequently, quality control tests (spectrophotometry and potential measurements), toxicity, and biocompatibility tests (cell viability assays) were conducted. Results: The proposed alumina nanoporous membrane proved to be efficient for amyloid-beta filtration according to the permeability studies conducted for 72 h. The proposed membrane has proven to be fully compatible with the tested cell cultures. Conclusions: The proposed alumina nanoporous membrane model is safe and could be incorporated into implantable devices for further in vivo experiments and might be an efficient therapeutic approach for Alzheimer’s disease.

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Performance Improvement and Biofouling Mitigation in Osmotic Microbial Fuel Cells via In Situ Formation of Silver Nanoparticles on Forward Osmosis Membrane

Cited by 23 publications

References 52 publications

Prevention and removal of membrane and separator biofouling in bioelectrochemical systems: a comprehensive review

Prevention and removal of membrane and separator biofouling in bioelectrochemical systems: a comprehensive review

Study on the Effect of Water Flux in Osmotic Microbial Fuel Cells on Membrane Water Content and Resistance

Nanoporous Membranes for the Filtration of Proteins from Biological Fluids: Biocompatibility Tests on Cell Cultures and Suggested Applications for the Treatment of Alzheimer’s Disease

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