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Soil polluted system shapes endophytic fungi communities associated with Arundo donax: a field experiment

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Mining activities pollute soils with heavy metals and red mud waste, damaging ecosystems and making plant growth difficult. This study examined fungi living inside the roots of Arundo donax, a hardy plant that survives in polluted soils, grown in three soil types: clean, heavy metal-contaminated, and red mud-contaminated. The researchers found that fungal communities changed based on the type of pollution, with a fungus called Pleosporales sp. thriving in red mud and showing promise for helping clean up contaminated soils. This research suggests that understanding these beneficial fungi could improve strategies for using plants to remediate polluted environments.

Filamentous Fungi Are Potential Bioremediation Agents of Semi-Synthetic Textile Waste

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Researchers tested whether fungi could break down and remove dyes from textile waste as an environmentally friendly alternative to landfilling or burning. A white rot fungus called Hypholoma fasciculare successfully removed over 80% of dye from test textiles within 8 months. This study represents the first successful demonstration of fungi breaking down dyes directly from solid textiles, opening new possibilities for sustainable textile waste management.

Production, optimization and characterization of esterase isolated from a new endophytic Trichoderma afroharzianum strain AUMC 16,433 and its applications in dye decolorization

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Scientists discovered a new type of fungus that produces an enzyme capable of breaking down synthetic dyes used in the textile industry. Using statistical optimization techniques, they enhanced the enzyme’s production and purified it to study its properties. The enzyme successfully removed various industrial dyes from solutions, with the highest effectiveness on malachite green dye. This discovery offers a promising natural solution to reduce environmental pollution caused by textile dye wastewater.

Optimizing bioremediation techniques for soil decontamination in a linguistic intuitionistic fuzzy framework

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This research develops mathematical tools to help experts choose the best method for cleaning contaminated soil using living organisms. The study presents new fuzzy logic operators that can handle both numerical and linguistic information, making decisions more understandable to humans. When applied to a contaminated industrial site, the method identified bioaugmentation (adding beneficial microorganisms) as the most effective cleanup approach among four options tested.

Fully integrated hybrid multimode-multiwavelength photonic processor with picosecond latency

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Researchers created a tiny optical computer chip that processes data much faster than electronic computers. The chip uses different colors and patterns of light to handle multiple signals at once, mimicking how fiber optic cables can send information through different pathways simultaneously. It successfully unscrambled mixed-up signals in real-time and removed jamming interference from communication signals, all with a processing time of just 30 picoseconds—trillions of times faster than blinking.

Exploring the potential of a bioassembler for protein crystallization in space

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Scientists successfully grew high-quality protein crystals in space using an innovative magnetic bioassembler device. By taking advantage of the weightless environment aboard the International Space Station, they were able to grow protein crystals with excellent structural quality that matched or exceeded Earth-based methods. This breakthrough demonstrates that space-based protein crystallization could help scientists better understand protein structures and potentially accelerate drug development.

Diversity of macrofungi in southeast Xizang 1. The wood-decay fungi

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Researchers surveyed wood-decay fungi in the forests of southeast Xizang and identified 558 different species, including one newly described species. This more than doubled the number of such fungi previously known from the region. Most species preferred either hardwood or softwood trees, and the fungi were classified as causing either white rot or brown rot. This study helps us understand the important decomposers that break down dead wood in China’s most biodiverse forest region.

Thermal Degradation and Fire Properties of Fungal Mycelium and Mycelium-Biomass Composite Materials

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This research explores how mushroom mycelium (fungal threads) can be grown with wheat grains to create fire-resistant composite materials. The study found that these mycelium-based composites are significantly safer than plastic polymers, catching fire less easily and releasing less heat when burned. The mycelium acts like a natural fire shield by forming a protective char layer. These findings suggest mycelium composites could be a sustainable and environmentally friendly alternative to synthetic plastics for packaging and insulation applications.

A review on architecture with fungal biomaterials: the desired and the feasible

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This review examines how mushroom mycelium can be used as a sustainable building material to reduce the construction industry’s carbon footprint. Six notable architectural projects from 2014-2021 demonstrate different approaches to using mycelium-based blocks and panels for constructing pavilions and temporary structures. The research shows that while mycelium composites offer environmental benefits and exciting design possibilities, they typically need reinforcement with traditional materials and careful production control to be effective in larger structures.

Optimization and antifungal efficacy against brown rot fungi of combined Salvia rosmarinus and Cedrus atlantica essential oils encapsulated in Gum Arabic

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Researchers have developed a natural product that protects wood from fungal decay by combining oils from rosemary and cedar trees and encapsulating them in Gum Arabic using specialized techniques. This nanoencapsulation process creates tiny protective particles that are much more stable and effective than the oils alone. When tested against wood-damaging fungi, this product showed remarkable antifungal power comparable to commercial fungicides. This innovation offers a safe, environmentally-friendly alternative to synthetic wood preservatives for building and construction applications.

Anti-Therapeutic Action: Not applicable