Abstract
Despite iron-based nanoparticles gaining huge attraction in various field of sciences and technology, their application rises ecological concerns due to lack of studies on their interaction with microbial cells populations and communities, such as biofilms. In this study, Chlorella vulgaris cells were employed as a model of aquatic microalgae to investigate the impacts of l-lysine-coated iron oxide nanoparticles (lys@IONPs) on microalgal growth and biofilm formation. In this regard, C. vulgaris cells were exposed to different concentrations of lys@IONPs and the growth of cells was evaluated by OD600 and biofilm formation was analyzed using crystal violet staining throughout 12 days. It was revealed that low concentration of nanoparticles (< 400 µg/mL) can promote cell growth and biofilm formation. However, higher concentrations have an adverse effect on microalgal communities. It is interesting that microalgal growth and biofilm are concentration- and exposure time-dependent to lys@IONPs. Over long period (~ 12 days) exposure to high concentrations of nanoparticles, cells can adapt with the condition, so growth was raised and biofilm started to develop. Results of the present study could be considered in ecological issues and also bioprocesses using microalgal cells.
Highlights
Iron-based nanoparticles are one of the most applied nanostructures in various fields of sciences and technologies
Impacts of synthesized nanoparticles on the growth of C. vulgaris cells were evaluated by measurements of optical density at 600 nm (OD600) using an Eppendorf Biophotometer® plus (Hamburg, Germany)
Chlorella vulgaris was selected as a model of microalgal cells to investigate the effects of lys@IONPs on microalgal biofilm formation
Summary
Iron-based nanoparticles are one of the most applied nanostructures in various fields of sciences and technologies. Due to their unique physicochemical properties these particles have gained applications in various fields science and engineering [1,2,3,4,5,6]. According to introduction of iron nanoparticles to the life sciences, many studies have been done to discover the interaction of living cells with these nanostructures [8, 9]. Concerning these investigations, it was revealed that iron nanoparticles have a concentration-dependent effect on the cells. By increase in the concentration of nanoparticles, toxic effects are increasingly prevailing and reduction in the cell growth and viability would be observed [9, 10]
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