biodegradation pathways

Impact of veterinary pharmaceuticals on environment and their mitigation through microbial bioremediation

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Veterinary medicines used in livestock are contaminating our water and soil, creating serious problems like antibiotic-resistant bacteria. Scientists are discovering that natural microorganisms like bacteria and fungi can break down these pharmaceutical pollutants effectively. Advanced technologies combining microbes with electrical systems show promise for cleaning up contaminated wastewater, offering hope for a more sustainable solution to this growing environmental problem.

Application of Fungus Enzymes in Spent Mushroom Composts from Edible Mushroom Cultivation for Phthalate Removal

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This research shows that leftover mushroom growing material (spent compost) can be used to clean phthalates from wastewater. Phthalates are harmful chemicals found in plastics that can damage human health. Scientists tested four types of mushroom composts and found they all worked, with the best results removing 99% of certain phthalates. This provides an affordable, eco-friendly way to treat polluted water.

The microbial strategies for the management of chemical pesticides: A comprehensive review

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Chemical pesticides used to protect crops contaminate soil and water, harming both ecosystems and human health. Scientists have discovered that specific microorganisms—bacteria, fungi, and algae—can naturally break down these harmful pesticides into harmless substances. By using advanced technologies to understand how these microbes work and even genetically enhancing them, researchers are developing sustainable solutions to clean up pesticide-contaminated environments without the toxic side effects of traditional cleanup methods.

The potential of fungi in the bioremediation of pharmaceutically active compounds: a comprehensive review

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Pharmaceutical drugs that we take end up in our water systems because our bodies don’t fully process them. Fungi, especially types of mushrooms, have powerful enzymes that can break down these drug residues and clean contaminated water. Scientists are studying how to use these fungi in treatment systems to remove medications from hospital wastewater and drinking water sources.

The impact of novel bacterial strains and their consortium on diflufenican degradation in the mineral medium and soil

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Scientists isolated four types of bacteria from agricultural soil that can break down diflufenican, a persistent weed-killer chemical that normally takes years to degrade. When these four bacteria work together as a team, they can eliminate over 82% of the herbicide in soil within four weeks. This discovery could provide a practical solution for cleaning up farmland contaminated with this stubborn chemical pollutant.

Environmental Impact of Xenobiotic Aromatic Compounds and Their Biodegradation Potential in Comamonas testosteroni

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This review examines how aromatic compounds found in plastics, pesticides, and antibiotics pollute our environment and how bacteria like Comamonas testosteroni can break them down naturally. The research shows that microplastics are accumulating in oceans and wildlife, causing health problems ranging from physical damage to disruption of metabolism and development. Scientists are exploring ways to use these bacteria and microbiome engineering to create biological cleaning systems that could sustainably treat pollution without adding more chemicals to the environment.

Bacterial Cytochrome P450 Involvement in the Biodegradation of Fluorinated Pyrethroids

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Scientists isolated a soil bacterium called Bacillus sp. MFK14 that can completely break down toxic fluorinated pesticides (specifically β-cyfluthrin and λ-cyhalothrin) within just two days. These pesticides are widely used in agriculture but persist in the environment and accumulate in living tissues, causing health problems. The study shows that special bacterial enzymes called cytochrome P450 play a key role in breaking these pesticides apart into less harmful products like fluoride ions. This discovery offers a promising natural solution for cleaning up pesticide-contaminated soil and water.

Bibliometric analysis of global research on white rot fungi biotechnology for environmental application

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White rot fungi are special mushrooms that can break down difficult-to-decompose pollutants in soil and water, offering a natural and cost-effective way to clean up environmental contamination. This research study analyzed over 3,900 scientific publications about using these fungi for environmental cleanup from 2003 to 2020. The analysis found that research on white rot fungi has grown significantly, with scientists from China and the USA leading the field, and identified three major application areas: treating biomass waste, removing dyes from wastewater, and cleaning polluted environments.

Insights on Anabaena sp. PCC 7120 Responses to HCH Isomers: Tolerance, Degradation, and Dynamics on Potential lin Genes Expression

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This research examined how a type of cyanobacteria called Anabaena can help clean up contaminated areas by breaking down different forms of a harmful pesticide called HCH. The scientists found that Anabaena handles some forms of HCH better than others, completely eliminating certain types while only partially breaking down others. This discovery suggests that Anabaena could potentially be used in environmental cleanup projects to remove HCH pollution from water and soil.

Feasibility of the use of Lentinula edodes mycelium in terbinafine remediation

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Scientists tested whether shiitake mushrooms (Lentinula edodes) could remove terbinafine, a common antifungal medication, from contaminated environments. The mushroom mycelium successfully accumulated and broke down the drug into harmless byproducts, with no trace remaining in the surrounding medium. This eco-friendly approach offers a promising alternative to expensive chemical cleanup methods for pharmaceutical pollution.

Research Keyword: biodegradation pathways