Pycnoporus cinnabarinus

Fungi as source for new bio-based materials: a patent review

mycolabadmin

Researchers reviewed patents from 2009-2018 on using fungal mycelium to create eco-friendly materials. Instead of petroleum-based plastics, scientists grow fungi on agricultural waste like corn stalks and wood chips, where fungal threads bind the materials together into strong, biodegradable products. These fungal materials are being developed for packaging, car interiors, textiles, and insulation, offering sustainable alternatives to conventional plastics.

Biotransformation of the Fluoroquinolone Antibiotic, Levofloxacin, by the Free and Immobilized Secretome of Coriolopsis gallica

mycolabadmin

Researchers discovered that a type of fungus called Coriolopsis gallica can break down the antibiotic levofloxacin, which persists in the environment and contributes to antibiotic resistance. They tested both free enzymes from the fungus and enzymes trapped in alginate beads to see which worked better. The study found that free enzymes degraded more of the antibiotic when a chemical helper molecule called HBT was added, while immobilized enzymes were more stable and could be reused multiple times.

Large-scale phenotyping of 1,000 fungal strains for the degradation of non-natural, industrial compounds

mycolabadmin

Scientists tested over 1,000 different fungi to see which ones could break down human-made pollutants like industrial dyes, plastics, and paper waste. They found that different types of fungi are good at degrading different pollutants, with wood-decaying fungi being particularly useful. This research suggests that fungi could be engineered to help clean up environmental pollution caused by industry and human activities.

Fungal Ligninolytic Enzymes and Their Application in Biomass Lignin Pretreatment

mycolabadmin

Scientists tested ten different types of fungi to see which ones could best break down lignin, a tough natural material found in plants. Four fungi species showed exceptional ability to produce special enzymes that decompose lignin. These findings could help develop new eco-friendly industrial processes for converting plant waste into useful products, potentially reducing reliance on chemical treatments and fossil fuels.

Waste Rose Flower and Lavender Straw Biomass—An Innovative Lignocellulose Feedstock for Mycelium Bio-Materials Development Using Newly Isolated Ganoderma resinaceum GA1M

mycolabadmin

Researchers developed eco-friendly building materials by growing mushroom mycelium (Ganoderma resinaceum) on waste residues from rose and lavender essential oil production. These waste biomasses, typically discarded or burned, were successfully converted into biocomposites with properties comparable to hempcrete and other sustainable materials. The resulting mycelium-based materials are completely natural, biodegradable, and possess antimicrobial and aromatic properties, offering a promising sustainable alternative to synthetic materials.

White Rot Fungi as Tools for the Bioremediation of Xenobiotics: A Review

mycolabadmin

White rot fungi are nature’s cleanup crew that can break down many toxic chemicals in our environment, from industrial dyes to pesticides. These special fungi produce powerful enzymes that can degrade pollutants that normally resist breakdown, making them promising tools for cleaning contaminated soil and water. Scientists are studying how to better harness these fungi’s abilities to treat industrial wastewater and restore polluted environments.

Towards engineering agaricomycete fungi for terpenoid production

mycolabadmin

Mushroom-forming fungi, particularly species like shiitake and oyster mushrooms, naturally produce valuable compounds called terpenoids used in medicines, food, and cosmetics. Scientists are learning to genetically engineer these fungi to produce even larger amounts of these beneficial compounds, potentially making them as important to biotechnology as baker’s yeast and mold have been historically. This could create new sustainable sources for medicinal compounds and industrial chemicals.

Hierarchical Structure of the Program Used by Filamentous Fungi to Navigate in Confining Microenvironments

mycolabadmin

This research reveals how fungi navigate through tight spaces like soil and wood using sophisticated biological ‘programs’ operating at three levels: individual fungal threads, groups of threads, and entire fungal networks. Each level uses different strategies like sensing openings, remembering directions, and avoiding neighbors to efficiently explore confined spaces. By understanding these natural algorithms, scientists could develop new bio-inspired solutions for navigation and space exploration problems.

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

mycolabadmin

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.

Engineering Strategies for Fungal Cell Disruption in Biotechnological Applications

mycolabadmin

Fungal cells have tough, protective walls that make it difficult to extract valuable products like proteins, oils, and medicines. This review examines different techniques—from physical methods like grinding with beads to chemical and enzyme-based approaches—to break open fungal cells efficiently. By understanding which method works best for different types of fungi and desired products, researchers can develop better, more sustainable ways to use fungi in manufacturing pharmaceuticals, food products, and other valuable compounds.

Fungal Species: Pycnoporus cinnabarinus