“Stabilization or Oxidation of Nanoscale Zerovalent Iron at Environmentally Relevant Exposure Changes Bioavailability and Toxicity in Medaka Fish” Chen, P-J; Tan, S-W; Wu, W-L. Environ. Sci. Technol. 2012, ASAP. DOI: 10.1021/es3006783
We’ve posted before on iron-catalyzed reactions (see here for a recent post) as greener alternatives to more traditional platinum group catalyzed reactions. However, even iron has toxicity concerns as described in this paper from National Taiwan University on the toxicity in medaka fish of zerovalent iron (nZVI) nanoparticles (NPs). This is particularly pertinent research in light of the increased usage of iron(0) nanomaterials in remediation.
The study investigates the effects of four different iron dosing ‘solutions’ on the molecular, cellular and organismal health of medaka larvae: (i) carboxymethylcellulose stabilized nZVI (CMC-nZVI), (ii) non-stabilized nZVI (nZVI), (iii) magnetite NPs (nFe3O4), and (iv) soluble Fe(II).
They first characterize the dosing solutions. The sizes of their nanoparticles are 75 nm, 25-75 nm, and 27 nm for CMC-nZVI, nZVI, and nFe3O4 respectively. The zeta potentials were measured to show, not surprisingly, that the CMC-stabilized particles are much more stable to aggregation than the non-stabilized nZVI.
Interestingly, of the four iron dosing solutions, CMC-nZVI has the most significant impact on the level of dissolved oxygen, decreasing it to zero where it remained for 12 hours. Furthermore, this aerobic oxidation of CMC-nZVI leads to a release of 45 mg/L of soluble Fe(II) in 10 min from an initial concentration of 100 mg/L CMC-nZVI as well as an increase in reactive oxygen species (ROS). In contrast, nZVI and nFe3O4 are 20 – 40 % aggregated within 10 min and release less than 20 mg/L of Fe(II) during this time. Only nZVI induces the production of ROS with nFe3O4 and soluble Fe(II) showing no increase in ROS relative to the control. The following figure details these findings for CMC-nZVI; analogous graphs are found in the supplementary information for the other solutions.
As for toxicity, the most toxic solution for medaka larvae (as judged by % mortality over the course of several days exposure to the solutions normalized by the concentration of Fe atoms) is the soluble Fe(II) solution. The second- and third-most are the CMC-nZVI and nZVI solutions, respectively, with nFe3O4 showing little toxicity. It is noteworthy that the ‘stabilized’ particles are more toxic than the ‘non-stabilized’ particles to the larvae.
In contrast, the order of bioaccumulation was nFe3O4 > nZVI > CMC-nZVI ~ Fe(II) (as measured by BCF or bioconcentration factor = iron concentrated in larvae / measured total iron concentration of the dosing solution). This order, interestingly, is the opposite of the toxicity order displayed above.
With these results, the researchers then investigated the molecular effects of the dosing solutions. Though the study is very detailed and worth reading more closely, the most dramatic effect was of CMC-nZVI on the expression of superoxide dismutase (SOD), one of nature’s enzymatic responses to oxidative stress, which increases approximately four-fold in the presence of CMC-nZVI. They also studied the effects of the dosing solutions on the gene expression of the antioxidant enzymes catalase (CAT, which catalyzes the decomposition of hydrogen peroxide) and glutathione S transferase (GST, which catalyzes the transfer of reduced glutathione groups to electrophiles), though the changes in expression were less significant than for SOD. The source of the differing impact on expression of the different enzymes is not clear to me, but I’m not shocked the genetic response is more complicated than a simple increase in gene expression in the presence of oxidative stress.
The researchers next studied the effects of the solutions on the activities of the enzymes. For CMC-nZVI there is little effect on the actual activity of SOD over seven days of exposure. This indicates that while CMC-nZVI has dramatic effects on gene expression it has no effect on the activity of the proteins coded by those genes. Furthermore, the intracellular ROS also is not affected by exposure to either CMC-nZVI or nZVI, suggesting the balance of active antioxidants can handle the oxidative stress from ROS at least over the course of several days.
In summary then, the NP toxicity appears due to a combination of hypoxia, the release of Fe(II), and other “NP-specific toxicity”. If true, the context of the application of these NPs – which are used for remediation in both aquifers and soils – then becomes important. For instance, the release of soluble Fe(II) would probably be of higher concern in an aqueous environment than in sediment. Moreover, the transport of particles between aquifers and sediments, especially in light of the dynamic nature of these solutions, needs to be investigated.
Going forward, I am interested in the identification and description of the NP-specific modes of toxicity and how that differs with stabilization, as the CMC-nZVI solutions are more toxic than the non-stabilized ones to medaka larvae. NP stabilization with surface ligands is a common method to prevent aggregation, but, at least in this case, also increase their toxicity via the release and dissolution of surface accessible iron atoms upon oxidation.