extracellular enzymes

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

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This research shows that two types of fungi—Aspergillus flavus and Cunninghamella elegans—can effectively break down commonly prescribed medications found in wastewater through biofilm formation on foam carriers. The fungi degrade these drugs through enzymatic action rather than absorption, removing 85-99% of the pharmaceuticals within days. This discovery offers a promising, cost-effective biological treatment for cleaning wastewater from hospitals and pharmaceutical factories, potentially protecting aquatic environments from drug pollution.

Ectophoma salviniae sp. nov., Neottiosporina mihintaleensis sp. nov. and four other endophytes associated with aquatic plants from Sri Lanka and their extracellular enzymatic potential

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Researchers in Sri Lanka discovered six species of fungi living inside freshwater aquatic plants, including two entirely new species. These fungi were identified using advanced genetic testing and were found to produce useful enzymes like amylase, cellulase, and laccase. This research reveals that Sri Lankan freshwater ecosystems harbor diverse fungal communities with potential biotechnological applications.

Esterase and Peroxidase Are Involved in the Transformation of Chitosan Films by the Fungus Fusarium oxysporum Schltdl. IBPPM 543

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Scientists discovered that a fungus called Fusarium oxysporum can safely modify chitosan films (a material made from shellfish shells) without breaking them apart. Instead of using destructive enzymes, the fungus produces special enzymes called esterase and peroxidase that reorganize the chitosan’s structure, making it stronger and more resistant. This discovery could lead to new medical materials, drug delivery systems, and water purification products with customized properties.

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

mycolabadmin

Researchers discovered that two types of fungi, Aspergillus flavus and Cunninghamella elegans, can effectively break down common prescription drugs like fluoxetine, ciprofloxacin, and atorvastatin in wastewater. When grown as biofilms on foam carriers, these fungi removed over 90% of the pharmaceuticals in just a few days. This is an important finding because conventional wastewater treatment doesn’t effectively remove these medications, which can harm aquatic ecosystems.

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

mycolabadmin

This study demonstrates that two types of fungi, Aspergillus flavus and Cunninghamella elegans, can effectively remove persistent pharmaceutical pollution from wastewater when grown as biofilms on foam carriers. The fungi achieved removal rates of 92-98% for three common medications (atorvastatin, ciprofloxacin, and fluoxetine) much faster than previously reported methods. Unlike traditional fungal treatments that depend on lignin, these fungi can work in diverse environments, making them practical for wastewater treatment plants and offering a sustainable biological solution to pharmaceutical pollution.

Research Topic: extracellular enzymes

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

Ectophoma salviniae sp. nov., Neottiosporina mihintaleensis sp. nov. and four other endophytes associated with aquatic plants from Sri Lanka and their extracellular enzymatic potential

Esterase and Peroxidase Are Involved in the Transformation of Chitosan Films by the Fungus Fusarium oxysporum Schltdl. IBPPM 543

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms