mycoremediation – Page 3

Hydrothermal liquefaction aqueous phase mycoremediation to increase inorganic nitrogen availability

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When biomass is converted to biofuel through a heating process called hydrothermal liquefaction, it produces a waste liquid containing nutrients but also toxins. Scientists used a type of fungus called Trametes versicolor to clean up this waste and convert the nitrogen into forms that plants can use. After three days of treatment with the fungus, nitrogen levels that plants can use increased dramatically. Adding helpful bacteria further improved the results, making this waste potentially usable as a fertilizer for growing vegetables hydroponically.

Characterization of the Enzymatic and Biosorption Processes Involved in the Decolorization of Remazol Brilliant Blue R Dye by Pleurotus ostreatus Pellets

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Oyster mushrooms can effectively remove synthetic dyes from wastewater through a combination of absorption and enzymatic breakdown. Researchers tested Pleurotus ostreatus pellets with a textile dye commonly used as a standard pollutant. The mushroom achieved over 98% dye removal, suggesting it could be used in wastewater treatment systems to clean industrial textile effluent. The fungus both absorbs the dye and produces enzymes that break it down.

Degradation of Extra-Heavy Crude Oil by Fungi Isolated from Hydrothermal Vents Fields in the Gulf of California

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Scientists discovered that certain fungi living in deep-sea hydrothermal vents can break down extra-heavy crude oil, a thick and difficult-to-treat form of petroleum. Among eight fungal species tested, Aspergillus sydowii was the most effective, degrading 40% of the crude oil in laboratory conditions. This research suggests these hardy deep-sea fungi could be used as a natural solution to clean up oil spills in extreme marine environments where traditional cleaning methods don’t work well.

Pharmaceutical Pollution in Aquatic Environments: A Concise Review of Environmental Impacts and Bioremediation Systems

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Medications we take for health are ending up in our water supplies in significant amounts because standard water treatment plants cannot remove them effectively. These pharmaceutical residues are harming wildlife and aquatic ecosystems, causing problems like population declines in birds, developmental issues in fish, and the spread of antibiotic resistance. Scientists are developing new bioremediation technologies, particularly using fungi and mycoremediation, to better remove these drugs from wastewater before they reach our water bodies.

Native Fungi as a Nature-Based Solution to Mitigate Toxic Metal(loid) Accumulation in Rice

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Rice farmers dealing with contaminated soils now have a natural solution: specially selected fungi can be added to the soil to help reduce toxic metal accumulation in rice plants. In a greenhouse study, native fungi reduced arsenic uptake by up to 75% when combined with specific water management practices. This approach offers an environmentally friendly alternative to traditional remediation methods while promoting sustainable agriculture in metal-contaminated areas.

The removal of black ink via Emericella quadrilineata as a green alternative technique to recycling ink waste papers

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Researchers discovered that a fungus called Aspergillus quadrilineatus can effectively remove black ink from waste paper, offering an eco-friendly alternative to harmful chemical deinking methods. Under optimal conditions, the fungus removed 97% of ink in just 6 days by absorbing it onto its surface and breaking it down with special enzymes. This biological approach could help reduce environmental pollution from paper recycling while making the process more cost-effective and sustainable.

Mycoremediation of Petroleum-Contaminated Soil Using Native Ganoderma and Trametes Strains from the Ecuadorian Amazon

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Researchers from Ecuador tested native fungi from the Amazon rainforest for their ability to clean up oil-contaminated soil. Five fungal species were found to remove over 96% of petroleum hydrocarbons in just 60 days through their natural enzymatic systems. These results show that fungi from biodiverse regions could offer an affordable and sustainable alternative to traditional soil cleanup methods, particularly important for communities affected by oil extraction pollution.

Adaptability assessment of Aspergillus niger and Aspergillus terreus isolated from long-term municipal/industrial effluent-irrigated soils to cadmium stress

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Scientists studied two types of fungi that can survive in soil contaminated with cadmium, a toxic heavy metal from industrial waste. These fungi can accumulate and remove cadmium from their environment while producing protective chemicals that help them survive the metal’s toxic effects. The research shows these fungi could potentially be used as a biological solution to clean up contaminated soils, offering a more sustainable alternative to traditional chemical cleanup methods.

Phytostabilization of Heavy Metals and Fungal Community Response in Manganese Slag under the Mediation of Soil Amendments and Plants

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This research shows that adding spent mushroom compost and a mineral amendment called attapulgite to contaminated mining waste, combined with planting a hardy tree species, significantly reduces heavy metal pollution. The tree and amendments work together by improving soil quality and promoting beneficial fungi that help stabilize harmful metals in the soil, preventing them from leaching into groundwater and surrounding ecosystems.

Hydrothermal liquefaction aqueous phase mycoremediation to increase inorganic nitrogen availability

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This research shows that a common mushroom fungus called Trametes versicolor can clean up wastewater produced during the conversion of food waste into biofuel. The fungus transforms hard-to-use nitrogen compounds in the waste into forms that plants can absorb. After three days of treatment, the nitrogen that plants can use increased dramatically. When bacteria known for converting ammonia to nitrate were added to the fungal treatment, the results improved even more, suggesting this waste could eventually be recycled as a fertilizer for growing plants in water-based farming systems.

Research Topic: mycoremediation