Biodegradation – mycolab.ai

Editorial: Biosurfactants – next-generation biomolecules for enhanced biodegradation of organic pollutants, volume II

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Organic pollutants like oil, plastics, and pesticides are dangerous because they persist in the environment and accumulate in living organisms. Biosurfactants are eco-friendly molecules produced by microorganisms that can help break down these stubborn pollutants more effectively than traditional chemical methods. This research shows that biosurfactants can be produced cheaply using agricultural waste and have potential applications in cleaning up oil spills, treating contaminated soil, and even healing wounds.

Toxicity Assessment and Bioremediation of Deep Eutectic Solvents by Haloferax mediterranei: A Step toward Sustainable Circular Chemistry

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This research demonstrates that a salt-loving microorganism called Haloferax mediterranei can safely tolerate and even metabolize certain eco-friendly solvents known as deep eutectic solvents (DESs). These solvents are promoted as green alternatives to toxic chemicals, but their safety wasn’t well understood. The study found that this hardy microorganism can use some components of these solvents as food sources, suggesting it could help clean up waste containing these chemicals in an environmentally friendly way.

Enhancing Environmental and Human Health Management Through the Integration of Advanced Revitalization Technologies Utilizing Artificial Intelligence

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This paper describes how combining artificial intelligence with environmental monitoring can help us better understand how pollution harms our health. The authors propose a seven-step system that collects data on pollution levels in air, water, and soil alongside health information from communities. By using AI to analyze these massive datasets together, scientists and doctors can more quickly identify which pollutants are causing specific health problems and design better treatments for affected people and environments.

Systematic Evaluation of Biodegradation of Azo Dyes by Microorganisms: Efficient Species, Physicochemical Factors, and Enzymatic Systems

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Azo dyes used in textiles and fashion contaminate water supplies and pose health risks including cancer potential. This research review shows that certain microorganisms like specific fungi and bacteria can break down these harmful dyes into less toxic substances through natural enzymatic processes. By optimizing conditions like pH and temperature, and using combinations of different microbes, scientists have achieved degradation rates up to 90%, offering an eco-friendly and cost-effective alternative to traditional chemical treatment methods.

Properties of Sound Absorption Composite Materials Developed Using Flax Fiber, Sphagnum Moss, Vermiculite, and Sapropel

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Researchers created new environmentally friendly sound-absorbing panels using lake sediment (sapropel) as a binder mixed with natural fibers and minerals. These composite materials work well for reducing noise in buildings and have a decorative natural appearance. However, because they contain organic materials, they are susceptible to mold growth and need antimicrobial protection, with materials containing vermiculite performing better than those with moss.

Unlocking the biodegradative potential of native white-rot fungi: a comparative study of fiberbank organic pollutant mycoremediation

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Swedish researchers tested 26 types of white-rot fungi to clean up polluted sediments from old pulp and paper mills called fiberbanks. These contaminated sediments contain harmful chemicals and heavy metals. The study found that three fungal species, especially Diplomitoporus crustulinus, were excellent at breaking down pollutants and could tolerate the toxic environment, making them promising for environmental cleanup efforts.

Maintaining ocean ecosystem health with hydrocarbonoclastic microbes

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Oil spills and petroleum pollution threaten ocean health worldwide. Special bacteria and archaea called hydrocarbonoclastic microorganisms naturally break down oil hydrocarbons in seawater, sediments, and Arctic regions. Scientists are improving cleanup strategies by understanding how these microbes work and combining natural degradation with engineered approaches like adding nutrients and biosurfactants.

High Potential Decolourisation of Textile Dyes from Wastewater by Manganese Peroxidase Production of Newly Immobilised Trametes hirsuta PW17-41 and FTIR Analysis

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This research shows that a fungus called Trametes hirsuta can effectively clean textile industry wastewater by breaking down colorful dyes that pollute the environment. The scientists attached the fungus to nylon sponges and optimized the treatment conditions to achieve over 95% color removal within just two days. The fungus produces special enzymes, particularly manganese peroxidase, that degrade the harmful dyes into safer substances, and the system can be reused repeatedly for continuous wastewater treatment.

Temporal characterization of biocycles of mycelium-bound composites made from bamboo and Pleurotus ostreatus for indoor usage

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Scientists created a sustainable building material by growing oyster mushroom fungus on bamboo fibers. The material was strong enough for packaging and could be composted after use to enrich soil, completing a full cycle in about 7 months. By adding a natural beeswax coating, the material lasted longer while remaining completely biodegradable. This proof-of-concept demonstrates how fungal materials could replace synthetic plastics in a circular economy.

Degradation of High Concentrations of Anthracene Using White-Rot Wood-Inhabiting Fungi and Investigation of Enzyme Activities

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Scientists in Iran discovered that certain wood-decay fungi, particularly Trametes versicolor mushrooms, can effectively break down anthracene, a toxic pollutant from oil and gas industries. These fungi produce special enzymes that degrade the harmful chemical into less toxic substances. In laboratory tests, these indigenous Iranian fungi successfully removed 20-64% of high-concentration anthracene over four weeks, showing promise for cleaning up contaminated sites.

Research Keyword: Biodegradation