Nanoscale zerovalent iron (nZVI) has been increasingly used for in situ groundwater and soil remediation because of its high redox activity and specific characteristics of nanoparticles (NPs). Recent applications are often involved in the use of surface-modified nZVI with the stabilizer that can enhance mobility of nZVI while travelling through the underground aquifer. However, the ultimate fate of iron NPs under- or above-ground aquifer and associated risks of exposure and toxicity to environmental life remain poorly understood at present. The objective of the study is to understand modes of toxic action of different iron NPs by comparing their lethal and sublethal effect(s) in medaka (Oryzias latipes). We have treated medaka larvae with thoroughly characterized solutions containing nZVI (uncoated), carboxymethyl cellulose sodium (CMC)-coated nZVI, nanoscale iron oxides (nFe3O4) and ferrous (Fe2+) ion at 0.5 - 100 mg/L for 7 days aqueous exposure. TEM images indicated that uncoated nZVI and nFe3O4 tended to aggregate, but CMC-nZVI did not. Dissolve oxygen suddenly dropped to 0 mg/L for >180 min and total reactive oxygen species (ROS) were elevated after the addition of CMC-nZVI and nZVI (100 mg/L). Fe2+ and Fe3+ were major species in CMC-nZVI, but at low concentration in the nZVI solution during 24 hr’s monitoring. In the meantime, the acute toxicity were in the order of Fe2+ ＞ CMC-nZVI ＞ nZVI ＞ nFe3O4 at high exposure concentrations (50 and 100 mg/L). At low exposure concentrations (0.5 and 5 mg/L), nFe3O4 and Fe2+ significantly increased CAT, GR activities and intracellular ROS levels, but decreased SOD activity. CMC-nZVI and nZVI only altered CAT activity. Based on histopathological analyses, treated groups (> 25 mg/L of CMC-nZVI, nZVI, nFe3O4 and Fe2+) led to various degrees of accumulation of iron particles in the fish gill and intestine tissues. Intestine wall and intestinal villi were damaged at some treated groups (> 25 mg/L of CMC-nZVI and nZVI). In this study, we observed that the use of stabilizer on nZVI and its reaction products (nFe3O4 and Fe2+) may increase hazardous risk of nZVI to the aquatic ecosystem.