Molds have been used as micro-biofactories for biomanufacturing of metal oxide nanoparticles (MetNps) since they are effortless, immaculate, safe, non-poisonous, vital-biocompatible, and environmentally acceptable. The present study aimed to explore the bioindustry, mold screening protocol, and characterization of zinc oxide nanoparticles (ZnONPs) using a diverse filamentous Green mold (FiGM) isolated from spoiled citrus fruits. Eight filamentous Penicillium Digitatum mold strains had been obtained and subjected to investigate the capability of ZnONPs biosynthesis by fungal extracellular free-cell filtrate. P. digitatum (P-digB3) obtained the peak of ZnONps (379 nm) detected by the UV-visible spectrophotometry and was found as a significantly optimum strain in the highest quantity (mean±SD: 0.0138±0.001 gm/100 ml) and the smallest average NPs size. The ZnONPs were characterized by UV-visible scanning spectrophotometry, Atomic Force Microscopy, X-RD, Scanning Electron Microscopy (SEM), and Transmission Electron Microscopy (TEM). The final average size of ZnONPs was obtained at 65.46 nm with diversified shapes and dimensions. The present study concluded the high capabilities of fungi (FiGMs) as eco-friendly and cheap bio-nano factories to manufacture ZnONPs with great nano-level average size, which may consider new boost sources for use in many nano-sectors and applications.
Keywords: P. digitatum (Pdig-B3); SEM and TEM; Zincum gluconicum; ZnONPs.