Toxicology letters
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Epidemiological studies have established the correlations between PM2.5 and a wide variety of pulmonary diseases. However, their underlying pathogeneses have not been clearly elucidated yet. In the present study, the epithelial-mesenchymal transition (EMT) phenotype with enhanced proliferation and migration activity of human pulmonary epithelial cell line BEAS-2B was observed after exposure to low dose PM2.5 exposure (50 μg/ml) for 30 passages. ⋯ Besides, the enrichment analyses on 7774 mRNA targets of 27 DE-Exo-MiRs predicted by MiRanda software also revealed the potential regulatory role of exosomal miRNAs in pathways in cancer, Wingless/Integrated (Wnt) signaling pathway, focal adhesion related genes and other multiple pathogenic pathways. Moreover, the interactive exosomal miRNA-mRNA pair networks were constructed using Cytoscape software. Our results provided a novel basis for a better understanding of the mechanisms of chronic PM2.5 exposure induced pulmonary disorders including pulmonary fibrosis and cancer, in which exosomal miRNAs (Exo-MiRs) potentially functions by dynamically regulating gene expressions.
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Carfentanil (CRF) is an extremely potent opioid capable of inducing fatal respiratory depression. Naloxone (NX) and naltrexone (NTX) are opioid antagonists for which the efficacy against CRF remains largely unexplored. In this study, the effects of aerosolized CRF on respiratory function were investigated using adult male CD-1 mice. ⋯ Despite improvements in MV, treatment administration did not reverse changes in DC, a measure of respiratory timing. Overall, NX and NTX administration alleviated volumetric aspects of opioid-induced respiratory toxicity, while changes in respiratory timing remained unresolved throughout post-exposure observation. These sustained changes and differences in recovery between two aspects of respiratory dynamics may provide insights for further exploration into the underlying mechanism of action of opioids and opioid antagonists.
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Comparative Study
Concentration × time analyses of sensory irritants revisited: Weight of evidence or the toxic load approach. That is the question.
The toxic effects resulting from inhalation exposure depend on both the concentration (C) of the inhaled substance and the exposure duration (t), including the assumptions that the exposure-limiting toxic effect is linearly linked with the accumulated C × t (inhaled dose), and detoxification or compensatory responses diminishing this dose are negligible. This interrelationship applies for both constant and fluctuating concentrations and is usually expressed by the toxic load equation Cn × t = constant effect (k). The toxic load exponent 'n' is derived from both C- and t-dependent exponents with Cb2×tb3 = k with n = b2/b3. ⋯ In summary, both Cn- and t-dependent dosimetry-related pitfalls may occur in acute bioassays on rodents following inhalation exposure to irritants. These must be identified and dealt with judiciously prior to translation to apparently similar human exposures. By default, extrapolations from one duration to another should start with that Cn × t eliciting the least depression in MV with n = 1.