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preparation and data analysis and drafted the manuscript. XX conceived and co-wrote the paper. AS, FR, WW, GC, SZ, ZD, and FM participated in the sample characterization. CJ participated in its design and coordination. All authors read and approved the final manuscript.”
“Background Gold nanoparticle (Au NP), being the most stable mono-metallic nanoparticle, promises to be a key Cobimetinib material and building block for newer technologies in the twenty-first century. Gold in its bulk state is regarded as a noble metal and is very unreactive because of its completely filled d-band [1]. However, at nanoscale, it is proving to be an important material for catalysis owing to its shape, size and crystal structure arrangement [2]. Due to this new set of properties, it has found wide-scale Fossariinae application in optics, electronics, catalysis, fabrication and biomedical utilities [3]. Generally speaking, physical methods of producing gold nanoparticles involve heating of gold at reduced pressure
to generate gold vapour, while chemical synthesis requires a reducing agent (generally citrate) followed by addition of a stabilizing agent [4–7]. However, these chemical methods deliver at the cost of expensive reducing and capping agents and toxic solvents along with tedious process control. To overcome these issues, several biogenic synthesis processes have been reported owing to the constant need for cost-effective eco-friendly synthesis of Au NPs. Microbial systems have found an important role in nanoparticle production due to their natural mechanism for detoxification of metallic ions through reduction which can be achieved extracellularly or intracellularly through bioaccumulation, precipitation, biomineralization and biosorption. Ogi et al. [8] showed gold nanoparticle formation in the presence of H2 gas pumped with Shewanella algae cell extract.