Physico-Chemical Alternatives for Synthesis of Metal Nanoparticles Using Fusarium Chlamydosporum

Abstract

Abstract Introduction/Objective Background: Synthesizing metal nanoparticles (NPs) by chemical or physical methods is difficult due to energy and time consumption, equipment costs, and chemical toxicity. Chemosynthesis-derived NPs are unstable, limiting their biological applications. Thus, identifying alternative green sources to address these drawbacks is difficult scientifically. The hardest part of green metal nanoparticle synthesis is finding a nontoxic natural product and an eco-friendly solvent. Objectives: Isolation of fungal endophytes from Eucalyptus sideroxylon leaves to synthesize ZnO and Au nanoparticles. Methods/Case Report Materials and methods: We used healthy Eucalyptus sideroxylon plant samples from the desert research center to separate endophytes. All fungi were grown on malt extract broth on a rotary shaker at 28 °C (120 rpm) for 96 hours after isolation. Biomass components were removed by filtration and washing in distilled water. Nanoparticles came from biomass cell filtrate. 0.1 M, 1 mL of Zn SO4, and HAuCl4 were added to 10 mL of fungal filtrate and agitated for 24 hours in the dark at room temperature to make Zn and Au nanoparticles separately. Characterization of nanoparticles shows a green synthesis of ZnONPs and AuNPs. Results (if a Case Study enter NA) Results: Fungal endophytes' filtrates were mixed with 1mM Zn SO4 and HAuCl4 solutions to test their extracellular biosynthesis of ZnO and Au NPs. The fungal filtrate became colorless and violet after mixing with Zn SO4 and HAuCl4. Only FI-03 is from 13 (FI-01 to FI-013). The most potent fungal strain for Zn O NP and Au NP nanoparticle synthesis was Fusarium Chlamydosporum. Pure, mostly spherical ZnO and Au NPs averaged 19.3 and 22.1 nm. UV-Vis absorption: Excitonic absorption peaks of ZnO NPs were between 300 and 400 nm. ZnO NPs' maximum absorption peak was 305 nm, while Au NPs' peak was 520 nm. One absorption peak indicates metallic gold nanoparticles. Au and ZnO NPs aggregate the most due to their hydrophilicity, HD of 34.88 and 15.77 nm, and PdI of 0.77, 1.00, and 0.952. Gold face-centered cubic fcc structure dominates Au NPs' XRD pattern. EDX shows 64.61 and 35.39 percent Zn and O, respectively, in both nanoparticles. The optical absorption band of gold nanocrystallites peaked at 2.2 keV in energy-dispersive X-rays. Conclusion Endophytic fungus biosynthesizes ZnO and Au NPs, which are bioactive compounds for medicine and food without toxic chemicals and are environmentally friendly.