biosorption – Page 2

Using Fungi in Artificial Microbial Consortia to Solve Bioremediation Problems

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This review explores how combinations of fungi and other microorganisms can clean up polluted soil and water more effectively than using individual microbes alone. Fungi are particularly valuable because they produce powerful enzymes that can break down toxic substances like heavy metals, dyes, pesticides, and plastics. By carefully designing microbial teams and sometimes immobilizing them in gels or on materials, scientists can achieve much higher removal rates of pollutants while maintaining environmental safety.

Fungal biodegradation of chlorinated herbicides: an overview with an emphasis on 2,4-D in Argentina

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Fungi can effectively break down and remove harmful herbicides like 2,4-D, which is widely used in Argentine agriculture but poses health and environmental risks. Through their powerful enzymatic machinery, certain fungal species can degrade these toxic chemicals into less harmful substances. This review examines how these fungal degradation processes work and discusses how such fungi might be safely introduced into contaminated environments to clean them up, following Argentina’s regulatory requirements.

New Type Biomembrane: Transport and Biodegradation of Reactive Textile Dye

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Researchers developed an innovative biodegradable membrane containing mushroom fungus (Morchella esculenta) to clean textile dye-contaminated water. The membrane uses natural fungal enzymes called laccase to break down harmful dyes while also absorbing them, achieving 98.6% dye removal in 60 hours. This eco-friendly approach eliminates the need for toxic chemicals used in traditional water treatment and can be reused multiple times, making it promising for industrial textile wastewater treatment.

Environmental Impacts and Strategies for Bioremediation of Dye-Containing Wastewater

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Textile factories release large amounts of dyes into water, creating serious pollution problems. Scientists have discovered that tiny living organisms like bacteria, fungi, and algae can eat and break down these dyes into harmless substances. This biological approach is cheaper, safer, and more environmentally friendly than traditional chemical methods used to clean wastewater, making it a promising solution for industries worldwide.

From consortium design to bioaugmented filters: scalable yeast-based strategies for lead remediation in water systems

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Lead contamination in water is a serious health problem worldwide. This research developed a solution using natural yeast strains from a river that can remove lead from water. Scientists optimized three different yeast types to work together and incorporated them into filters, achieving up to 99.97% lead removal. This sustainable, low-cost approach could make clean water more accessible globally, especially in resource-limited areas.

Mycofiltration of Aqueous Iron (III) and Imidacloprid Solutions, and the Effects of the Filtrates on Selected Biomarkers of the Freshwater Snail Helisoma duryi

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Researchers investigated using oyster mushroom mycelium to filter contaminated water containing iron and pesticides. They found that the mushroom-based filter effectively removed iron (III) from water, reducing it by 94% in column experiments. Tests on freshwater snails exposed to the filtered water showed improved water quality. This approach offers an environmentally friendly alternative to traditional water treatment methods.

Water Quality Assessment and Decolourisation of Contaminated Ex-Mining Lake Water Using Bioreactor Dye-Eating Fungus (BioDeF) System: A Real Case Study

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Researchers tested a natural solution for cleaning polluted water from an old mining lake in Malaysia. They used a special fungus called Ganoderma lucidum in a system called BioDeF that acts like a sponge to remove dirt and discoloration from contaminated water. After just 48 hours, this fungus-based system removed over 90% of the water’s brown color, offering a cheap and eco-friendly alternative to traditional water cleaning methods.

Innovative Approaches and Evolving Strategies in Heavy Metal Bioremediation: Current Limitations and Future Opportunities

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Heavy metals like lead, mercury, and arsenic accumulate in soil and water, harming both ecosystems and human health. Traditional cleanup methods are expensive and harmful to the environment. Scientists are developing biological solutions using microorganisms and special plants that can absorb or break down these toxic metals, combined with genetic engineering and nanotechnology to make the process faster and more effective.

Evaluation of resistance patterns and bioremoval efficiency of hydrocarbons and heavy metals by the mycobiome of petroleum refining wastewater in Jazan with assessment of molecular typing and cytotoxicity of Scedosporium apiospermum JAZ-20

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Scientists isolated fungi from oil refinery wastewater in Saudi Arabia and discovered that a fungus called Scedosporium apiospermum JAZ-20 is exceptionally good at removing harmful metals and oil pollutants from contaminated water. This fungus was also tested on human cancer cells and showed promise as a potential anti-cancer agent while being relatively safe. The research suggests this fungus could be used as an eco-friendly solution to clean up polluted industrial wastewater.

Mycoremediation: Expunging environmental pollutants

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Fungi can be used to clean up environmental pollution from industrial waste, pesticides, and heavy metals. Unlike expensive chemical treatments, fungal mycoremediation is cost-effective and environmentally friendly. Fungi produce natural enzymes that break down harmful pollutants into harmless substances, making it a promising solution for protecting soil and water contamination.

Research Keyword: biosorption