Iron-based NPs have been used on wastewater treatment or environmental remediation applications. The public has raised concerns about the increased risk of exposure and toxicity to iron NPs for human and aquatic life. However, the fate and toxic effects of iron NPs in the aquatic ecosystem remain unclear at present. In this study, we have treated embryos of medaka (Oryzias latipes) fish with carboxymethyl cellulose stabilized nanoscale zero-valent iron (CMC-nZVI, 27.1±3.7 nm), nanoscale iron oxide (nFe3O4, 30.1±2.6 nm) and ferrous ion [Fe(II)aq] at dosages of 25-200 mg/L for a 7-day aqueous exposure. We have investigated the mortality, bioaccumulation potency, developmental toxicity and oxidative stress effects of two iron NPs and [Fe(II)aq] in early life stages of medaka. Results show CMC-nZVI caused the severest mortality and developmental toxic effects in embryos. The bioaccumulation potency in embryos exposed to all 3 iron species treatments (50-150 mg/L) was significantly higher than the control. Embryos treated with CMC-nZVI caused the greatest developmental toxicity including decrease in heart rate, eye size and hatching rate, thus leading to hatching delayed, and nFe3O4 while [Fe(II)aq] caused lesser and least effects. Also, intracellular levels of reactive oxygen species and activities of antioxidants such as superoxide dismutase and catalase were altered in hatchings from embryos treated with CMC-nZVI (>25 mg/L), nFe3O4 (200 mg/L) and [Fe(II)aq] (>50 mg/L). Based on histopathological analyses, all 3 iron species treatement didn’t cause pathological changes but led to a slight degree of iron accumulation in the alimentary canal, pancreas and body tissues. The results implicate a potential ecotoxicological impact of nZVI and related oxidized products on the aquatic environment.