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20 resultsShowing papers similar to Electric stimulation mitigated the mixed microplastic inhibition to anaerobic digestion during wastewater treatment
ClearElectrochemically Coupled Anaerobic Membrane Bioreactor Facilitates Remediation of Microplastic-Containing Wastewater
Researchers tested an electrochemically coupled anaerobic membrane bioreactor for treating microplastic-containing wastewater and found that electrical stimulation effectively counteracted the inhibitory effects of microplastics on microbial metabolism. The system improved methane production, microbial viability, and enzyme activity compared to conventional anaerobic treatment in the presence of microplastics. The study suggests that combining electrochemical and biological approaches could improve both wastewater treatment efficiency and energy recovery when microplastics are present.
Bioelectrochemical anaerobic digestion mitigates microplastic pollution and promotes methane recovery of wastewater treatment in biofilm system
Researchers found that bioelectrochemical systems can simultaneously break down microplastics in wastewater and recover methane gas for energy. The systems enhanced the degradation of polyethylene and polyvinyl chloride particles while maintaining healthy biofilm communities on the electrodes. The study suggests that combining electrochemistry with biological treatment could offer a practical approach to both microplastic removal and renewable energy recovery from wastewater.
Bioelectrochemistry promotes microbial activity and accelerates wastewater methanogenesis in anaerobic digestion under combined exposure to antibiotics and microplastics
Researchers tested a bioelectrochemical system for treating wastewater contaminated with both antibiotics and microplastics, achieving 14% better treatment efficiency and methane recovery than standard methods. The electrical stimulation helped beneficial microbes thrive despite the pollutants, though it also increased some antibiotic resistance genes. This study is relevant because it addresses a real-world challenge of treating water containing multiple contaminants, including microplastics, before it reaches the environment.
Effect of single and hybrid microplastic exposures on anaerobic sludge in microbial electrochemical technology (MET)
Researchers studied how single and mixed types of microplastics affect wastewater treatment performance in microbial electrochemical systems. They found that microplastics significantly impaired methane production, reduced pollutant removal efficiency, and increased oxidative stress in microbial communities, with PVC causing the strongest inhibition. Mixed microplastic exposure under electrical stimulation caused even greater disruption to key microbial populations involved in wastewater treatment.
Insights into the impact of polyethylene microplastics on methane recovery from wastewater via bioelectrochemical anaerobic digestion
Researchers found that polyethylene microplastics inhibited methane recovery in bioelectrochemical anaerobic digestion systems by disrupting microbial communities and electrochemical performance, though low concentrations had less severe effects.
Evaluating Microplastic Effects on Performance and Electrochemistry of Microbial Fuel Cells for Wastewater Treatment
Researchers evaluated how microplastics affect the performance of microbial fuel cells used for wastewater treatment. They found that low concentrations of microplastics actually improved chemical oxygen demand reduction and power production compared to wastewater without microplastics. However, at higher concentrations the beneficial effects diminished, suggesting that microplastic levels in wastewater could influence the efficiency of bioelectrochemical treatment systems.
Revealing the Mechanisms of Polyethylene Microplastics Affecting Anaerobic Digestion of Waste Activated Sludge
Researchers studied how polyethylene microplastics affect the anaerobic digestion of sewage sludge, a common wastewater treatment process. They found that higher concentrations of microplastics significantly reduced methane production by disrupting microbial communities and enzyme activities essential for digestion. The study reveals that microplastic contamination in wastewater systems can undermine the efficiency of sludge treatment and biogas generation.
Thermal hydrolysis alleviates polyethylene microplastic-induced stress in anaerobic digestion of waste activated sludge
Scientists found that pretreating waste sludge with heat before anaerobic digestion reduced the negative effects that polyethylene microplastics have on the process. The thermal treatment improved methane production and helped maintain healthy microbial communities even in the presence of microplastics. The study suggests that thermal hydrolysis could be a practical strategy for wastewater treatment plants dealing with microplastic-contaminated sludge.
Effects of multi-microplastic mixtures on the performance of constructed wetland microbial fuel cells for wastewater treatment
Researchers tested how mixtures of four common microplastic types affect the performance of constructed wetland microbial fuel cells used for wastewater treatment. They found that while microplastics had minimal impact on organic matter removal, nitrogen removal efficiency dropped by about 20% due to suppression of key denitrifying bacteria. Interestingly, microplastics enhanced electricity generation by enriching electroactive bacteria like Geobacter in the fuel cell systems.
Investigation of the influence of polystyrene microplastics in wastewater on anode biofilm viability and electron transfer in microbial fuel cells performance
Researchers found that polystyrene microplastics in wastewater reduce the electricity-generating ability of microbial fuel cells — devices that use bacteria to turn waste into power — by disrupting the bacterial biofilms that transfer electrons to electrodes. Carbon-based electrodes were more resistant to microplastic interference than metal ones, suggesting material choice matters when designing systems treating microplastic-contaminated water.
Overcoming micro/nanoplastics-induced inhibition in anaerobic digestion: Advances in remediation techniques
This review examines how micro- and nanoplastics inhibit anaerobic digestion performance — reducing biogas yield and organic removal — and surveys remediation strategies including physical, chemical, and biological approaches to overcome their disruptive effects in waste treatment systems.
Responses of syntrophic microbial communities and their interactions with polystyrene nanoplastics in a microbial electrolysis cell
Researchers investigated how polystyrene nanoplastics affect microbial communities in a microbial electrolysis cell, a technology used for energy recovery during wastewater treatment. They found that nanoplastics disrupted the biofilm structure and altered the composition of the microbial communities responsible for breaking down waste. The study suggests that nanoplastic contamination in wastewater could reduce the efficiency of these promising electrochemical treatment systems.
Saving Energy in Biological Wastewater Treatment by Using Extremely Low-Frequency Electric Field—Pilot-Scale Study
Not relevant to microplastics research; this paper describes a pilot study using low-frequency electric fields to improve biological wastewater treatment efficiency, with no connection to microplastic pollution.
Resilience and functional redundancy of methanogenic digestion microbiome safeguard recovery of methanogenesis activity under the stress induced by microplastics
Researchers studied how microplastics and nanoplastics affect the microbiome responsible for methane production during anaerobic digestion of wastewater sludge. The study found that while plastic particles initially disrupted methanogenesis, the microbial community showed resilience and functional redundancy that allowed methane production to recover over time.
Impact of micro-nanoplastics on biochemical phases of anaerobic digestion in sewage sludge treatment: mechanistic insights and future prospects
Micro- and nanoplastics were found to disrupt the biochemical phases of anaerobic digestion, affecting the efficiency of the biological process used to treat organic waste. Understanding these impacts is important because anaerobic digestion is a common wastewater and sludge treatment method that may both receive and process microplastic-contaminated materials.
Effect of microplastic on anaerobic digestion of wasted activated sludge
This study investigated how varying doses of microplastics affect methane production during anaerobic digestion of waste activated sludge, testing concentrations from 0 to 100,000 particles per gram. Higher microplastic doses progressively inhibited methane production, suggesting that high microplastic loads in wastewater treatment sludge can impair biogas recovery.
Using dual chamber microbial fuel cells for coupled microplastic biodegradation and bioelectricity production: assessing the effect of substrate
Researchers investigated using dual-chamber microbial fuel cells to simultaneously biodegrade PET microplastics and generate bioelectricity. The study found that microbial consortia in the fuel cell setup could break down microplastics while producing usable electrical energy, offering a potentially sustainable approach to microplastic remediation in wastewater treatment.
Dissecting the effects of co-exposure to microplastics and sulfamethoxazole on anaerobic digestion
Researchers examined how microplastics combined with the antibiotic sulfamethoxazole affect the anaerobic digestion process used in wastewater treatment. They found that the combination reduced methane production and altered microbial communities, while also promoting widespread antibiotic resistance among the microorganisms. The study highlights concerns about how co-occurring microplastics and antibiotics in sewage could undermine wastewater treatment efficiency.
Systematic study of microplastics on methane production in anaerobic digestion: Performance and microbial response
Microplastics are increasingly found in wastewater treatment systems, and this study systematically examined how different types, concentrations, and sizes of microplastics affect the anaerobic digestion process used to break down sewage sludge and generate biogas. Polyethylene microplastics were found to inhibit methane production, with finer particles and higher concentrations causing greater disruption to the microbial communities driving digestion. The findings matter because microplastics in sewage sludge can impair the treatment process and also end up spread on agricultural land when sludge is used as fertilizer.
Deciphering the inhibition mechanisms of microplastics on the full-stage sludge anaerobic digestion via enrichment to anaerobic microbes and toxicity of released compounds
This study found that microplastics in sewage sludge significantly interfere with the waste treatment process by reducing the activity of key microorganisms needed to break down waste. More than half of the negative effect came from toxic chemicals released when microplastic particles rub against sludge, and the disrupted treatment also increased the risk of spreading antibiotic-resistant bacteria.