wastewater treatment

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.

The Strategies Microalgae Adopt to Counteract the Toxic Effect of Heavy Metals

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Microalgae can help clean water polluted with toxic heavy metals like cadmium and chromium while also producing useful biomass. The review explains how microalgae absorb and trap heavy metals, and describes ways to make them more effective, including adding certain chemicals, selecting resilient strains, and using genetic modification. Combining heavy metal removal with biomass production could make the process cost-effective for real-world applications.

Copper biosorption by Serratia plymuthica: crucial role of tightly bound extracellular polymeric substances in planktonic and biofilm systems

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Researchers discovered that a bacterium called Serratia plymuthica can effectively remove copper from contaminated water using special protective layers of polymers it produces. These polymer layers, especially the protein components, act like tiny magnets that capture copper ions from solution. The study found that when these bacteria form biofilms on porous surfaces, they become even more effective at removing copper from industrial wastewater, achieving up to 97% removal efficiency even under harsh acidic conditions.

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.

Recent Advances in Functional Polymer Materials for Water Treatment

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Scientists are developing new plastic-like materials that can clean polluted water more effectively and sustainably. These functional polymers can trap heavy metals, remove unwanted dyes, and even help treat wastewater from oil drilling. The research shows these materials work much better than traditional methods, and they can be recycled multiple times, making them environmentally friendly solutions to global water pollution problems.

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.

Biodecolorization and Biodegradation of Methyl Orange by Immobilized Pseudomonas aeruginosa Bacterium into SA/PVA Matrix Integrated with MOF UiO-66 Adsorbent

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Scientists created special beads containing bacteria and a porous material called MOF to remove orange dye (methyl orange) from contaminated water. The bacteria break down the dye molecules while the porous material helps trap the dye, working together more effectively than either method alone. These beads removed over 92% of the dye from water in just 10 days, making them promising for treating textile industry wastewater.

Adaptive responses of Gordonia alkanivorans IEGM 1277 to the action of meloxicam and its efficient biodegradation

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This research demonstrates that a bacterium called Gordonia alkanivorans can break down meloxicam, a commonly used anti-inflammatory drug that pollutes our environment. The bacteria successfully converted the harmful drug into less toxic byproducts over two weeks. The study reveals how the bacteria adapted to handle the drug stress and identified the specific genes and enzymes responsible for the degradation process. These findings could lead to new biological methods for cleaning pharmaceutical pollutants from wastewater.

Isolation and screening of wood-decaying fungi for lignocellulolytic enzyme production and bioremediation processes

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Researchers isolated wood-decaying fungi from forests in Latvia to identify species that produce powerful enzymes capable of breaking down complex plant materials. These enzymes have practical applications in cleaning contaminated water, treating textile industry waste, and converting plant biomass into useful products. The study found that certain environmental fungi, particularly Trametes pubescens, produced enzymes at levels exceeding those of commercially used strains, suggesting they could be valuable tools for environmental cleanup and industrial processes.

Microbes as Teachers: Rethinking Knowledge in the Anthropocene

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Microbes have been the architects of life on Earth for nearly 4 billion years, managing oxygen production, nutrient cycles, and climate stability—yet we rarely recognize their wisdom. This paper argues we should treat microbes as teachers rather than mere subjects of study or exploitation. By reforming education, policy, and how we think about our relationship with microbial life, we can solve modern challenges like climate change and disease while learning to coexist with the microscopic majority that sustains all life.

therapeutic action: wastewater treatment