November 21, 2024
Mahmood Barani

Mahmood Barani

Academic Rank: Assistant professor
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Degree: Ph.D in Nanochemistry
Phone: -
Faculty: Faculty of Nano and Biotechnology

Research

Title Enhanced pollutant degradation via green-synthesized core-shell mesoporous Si@Fe magnetic nanoparticles immobilized with metagenomic laccase
Type Article
Keywords
ImmobilizationMagnetic nanostructureRecalcitrantWastewaterPolyethyleneMetagenomic laccase
Journal INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES
DOI https://doi.org/10.1016/j.ijbiomac.2024.134813
Researchers Shohre Ariaeenezhad (First researcher) , Mahmood Barani (Second researcher) , Maryam Roostaee (Third researcher) , Azadeh Lohrasbi nezhad (Fourth researcher) , Ghasem Mohammadinezhad (Fifth researcher) , Ghasem Hosseini salekdeh (Not in first six researchers)

Abstract

With rapid industrial expansion, environmental pollution from emerging contaminants has increased, posing severe ecosystem threats. Laccases offer an eco-friendly solution for degrading hazardous substances, but their use as free-form biocatalysts face challenges. This study immobilized laccase (PersiLac1) on green-synthesized Si@Fe nanoparticles (MSFM NPs) to remove pollutants like Malachite Green-containing wastewater and degrade plastic films. Characterization techniques (FTIR, VSM, XRD, SEM, EDS, BET) confirmed the properties and structure of MSFM NPs, revealing a surface area of 31.297 m2.g−1 and a pore diameter of 12.267 nm. The immobilized PersiLac1 showed enhanced activity across various temperatures and pH levels, retaining over 82 % activity after 15 cycles at 80°C with minimal leaching. It demonstrated higher stability, half-life, and decimal reduction time than free laccase. Under 1 M NaCl, its activity was 1.8 times higher than the non-immobilized enzyme. The immobilized laccase removed 98.11 % of Malachite Green-containing wastewater and retained 82.92 % activity over twenty cycles of dye removal. Additionally, FTIR and SEM confirmed superior plastic degradation under saline conditions. These findings suggest that immobilizing PersiLac1 on magnetic nanoparticles enhances its function and potential for contaminant removal. Future research should focus on scalable, cost-effective laccase immobilization methods for large-scale environmental applications.