Zinc oxide nanoparticles induces cell death and consequently leading to incomplete neural tube closure through oxidative stress during embryogenesis

Yan, Yu; Huang, Wenyi; Lu, Xiaoting; Chen, Xianxian; Shan, Yingyi; Luo, Xin; Li, Yu; Yang, Xuesong; Li, Chun

doi:10.1007/s10565-024-09894-1

Cited by 2 publications

References 75 publications

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Nanostructured zinc carbonate hydroxide microflakes: assessing the toxicity against erythrocytes and L929 cells in vitro

Prokopiuk,

Onishchenko,

Pazura

et al. 2024

Nanotechnology

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Introduction. Nanostructured materials have been suggested to be used as a source of dietary zinc for livestock animals. In this study, we assessed the cytotoxicity of newly synthesized nanostructured zinc carbonate hydroxide (ZnCH) Zn5(CO3)(OH)6 microflakes. Materials and methods. Cytotoxicity of the microflakes was assessed against murine L929 cell line and rat mature erythrocytes. MTT and neutral red uptake assays, scratch assay, Annexin V-FITC/7-aminoactinomycin D staining, 2',7'-dichlorodihydrofluorescein diacetate (H2DCFDA) staining, Fura 2-AM staining, staining for reactive nitrogen species (RNS), detection of caspases, and lipid order-sensitive NR12S probe staining were employed to evaluate cell viabilityViability, motility, cell death pathways, implication of Ca2+, reactive oxygen species (ROS) and reactive nitrogen species (RNS) signaling, caspases, and alterations of cell membranes following exposure of L929 cells to the microflakes, respectively were assessed. To assess hemocompatibility of the Zn-containing microflakes, osmotic fragility assay and hemolysis assays were performed, as well as multiple eryptosis parameters were evaluated.Results. Our findings indicate a dose-response cytotoxicity of ZnCH microflakes against L929 cells with no toxicity observed for low concentrations (10 mg/L and below). At high concentrations (25 mg/L and above), ZnCH microflakes promoted oxidative stress,nitrosyl stress, Ca2+- and caspase-dependent apoptosis, and altered lipid order of cell membranes in a dose-dependent manner, evidenced by up to 7-fold elevation of RNS-dependent fluorescence, 2.9-fold enhancement of Fura 2-dependent fluorescence, over 20-fold elevation of caspases-dependent fluorescence (caspase-3, caspase-8, and caspase-9), and up to 4.4-fold increase in the ratiometric index of the NR12S probe. Surprisingly, toxicity to enucleated mature erythrocytes was found to be lower compared to L929 cells. ZnCH microflakes induced eryptosis associated with oxidative stress, nitrosyl stress, Ca2+ signaling and recruitment of caspases at 25-50-100 mg/L. Eryptosis assays were found to be more sensitive than evaluation of hemolysis. Conclusions. Zn5(CO3)(OH)6 microflakes show no cytotoxicity at low concentrations indicating their potential as a source of zinc for livestock animals.

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Nanostructured zinc carbonate hydroxide microflakes: assessing the toxicity against erythrocytes and L929 cells in vitro

Prokopiuk,

Onishchenko,

Pazura

et al. 2024

Nanotechnology

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Toxicology of Nanomaterials With a Special Focus on the Nervous System

Yingngam

2024

Advances in Medical Diagnosis, Treatment, and Care

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Nanomaterials possess different properties that make them suitable for application in numerous fields. Nonetheless, their toxicity, especially their neurotoxic propensity, is a considerable area of investigation. In this chapter, nanomaterial neurotoxicity is reviewed in detail, with an emphasis on assessing toxicity, levels of exposure or routes of entry to brain cells, mechanisms by which they cause damage, and specific types of damage. In addition, in this chapter, in vitro, ex vivo, and in vivo models used to measure neurotoxicity are described. This chapter provides a discussion of this matter by considering challenges in terms of nanomaterial characterization, risk assessment, and regulatory aspects. This chapter concludes by underscoring the importance of toxicological models of prediction and safe-by-design solutions. Future research should address the long-term effects of using nanomaterials and the means of preventing their neurotoxicity.

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Zinc oxide nanoparticles induces cell death and consequently leading to incomplete neural tube closure through oxidative stress during embryogenesis

Cited by 2 publications

References 75 publications

Nanostructured zinc carbonate hydroxide microflakes: assessing the toxicity against erythrocytes and L929 cells in vitro

Nanostructured zinc carbonate hydroxide microflakes: assessing the toxicity against erythrocytes and L929 cells in vitro

Toxicology of Nanomaterials With a Special Focus on the Nervous System

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