Sodium p-perfluorous nonenoxybenzene sulfonate (OBS) is a prominent alternative to perfluorooctanesulfonic acid (PFOS). Numerous studies have demonstrated hepatotoxicity and neurotoxicity of OBS and PFOS in mammals. The lungs, as a sensitive organ, are among the potential target organs for OBS and PFOS exposure. However, their toxic effects on the lungs remain unclear. In the present study, three-dimensional (3D) spheroids constructed from A549 cells were exposed to OBS and PFOS for 7 days to evaluate pulmonary toxicity through morphological examination, growth kinetics, transcriptomic profiling, and biochemical assays. Our results showed that OBS significantly reduced the diameter, volume, and growth fraction of the spheroids compared to PFOS. Transcriptomic analysis revealed a notable enrichment of the IL-17 signaling pathway after 7 days of OBS exposure. Significant differences in the transcription of genes within this pathway were observed between OBS and PFOS exposure. OBS reduced the transcription of tnfaip3, nfkbiα, map3k8, enpp2, jun, il6, cxcl1, cxcl2, cxcl3, and cxcl8 in the IL-17 signaling pathway, while PFOS enhanced the transcription of nfkbiα. Additionally, OBS decreased the level of IL-8, whereas PFOS had a minor effect. Cluster analysis confirmed significant differences in the pulmonary toxicity between OBS and PFOS. Our study demonstrated the utility of spheroids as an in vitro cell model complemented with omics technology, for comparing the pulmonary toxicity of OBS and PFOS. It provided a novel approach for evaluating the pulmonary toxicity of new pollutants like OBS.
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Sodium p-perfluorous nonenoxybenzene sulfonate (OBS) is a prominent alternative to perfluorooctanesulfonic acid (PFOS). Numerous studies have demonstrated hepatotoxicity and neurotoxicity of OBS and PFOS in mammals. The lungs, as a sensitive organ, are among the potential target organs for OBS and PFOS exposure.
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Article Synopsis
- Increased attention to per- and polyfluorinated compounds in water highlights Sodium p-Perfluorous Nonenoxybenzenesulfonate (OBS) as a potential alternative to PFOS, but raises environmental concerns due to its presence in oil fields and foams.
- This study explores three advanced reduction processes—UV-Sulfate, UV-Iodide, and UV-Nitrilotriacetic acid—to effectively remove OBS, finding that hydrated electrons are key to its degradation.
- Among the methods, UV-Iodide showed the most promising results with the highest removal rate and defluorination efficiency, although it also produced toxic nitrogen-containing intermediates that could present additional environmental threats.
Innovation of BiOBr/BiOI@BiOI Ternary Heterojunction for Catalytic Degradation of Sodium P-Perfluorous Nonenoxybenzenesulfonate.
Toxics
April 2024
School of Environmental and Chemical Engineering, Shenyang University of Technology, Shenyang 110870, China.
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