Evaluation of uptake, cytotoxicity and inflammatory effects in respiratory cells exposed to pristine and ‐OH and ‐COOH functionalized multi‐wall carbon nanotubes

Toxic effects were reported for pristine‐multi‐wall carbon nanotubes (p‐MWCNTs) while the role of the functionalization on MWCNT‐induced toxicity is not yet well defined. We evaluated on human alveolar (A549) epithelial cells and normal bronchial (BEAS‐2B) cells exposed to p‐MWCNTs, MWCNTs‐OH and MWCNTs‐COOH: uptake by TEM, cell viability by different assays, membrane damage by the LDH assay and cytokine release by ELISA. The aims of the present study were to: (i) confirm MWCNT cytotoxicity mechanisms hypothesized in our previous studies; (ii) identify the most reliable viability assay to screen MWCNT toxicity; and (iii) to test our model to clarify the role of functionalization on MWCNT‐induced toxicity. In A549 cells, p‐MWCNTs and MWCNTs‐OH were localized free in the cytoplasm and inside vacuoles whereas MWCNTs‐COOH were confined inside filled cytoplasmic vesicles. WST‐1 and Trypan blue assays showed in A549 cells a similar slight viability reduction for all MWCNTs whereas in BEAS‐2B cells WST1 showed a high viability reduction at the highest concentrations, particularly for MWCNTs‐COOH. The MTT assay showed a false cytotoxicity as a result of MWCNTs‐interference. Pristine and MWCNTs‐COOH induced membrane damage, particularly in BEAS‐2B cells. MWCNTs‐COOH induced interleukin‐6 (IL‐6) and IL‐8 release in A549 cells whereas p‐MWCNTs induced IL‐8 release in BEAS‐2B cells. MWCNTs intracellular localization in A549 cells confirms the toxicity mechanisms previously hypothesized, with p‐MWCNTs disrupting the membrane and vesicle‐confined MWCNTs‐COOH inducing inflammation. WST‐1 was more reliable than MTT to test MWCNT‐toxicity. BEAS‐2B cells were more susceptible then A549 cells, particularly to MWCNT‐COOH cytotoxicity. Our results confirm the toxicity of p‐MWCNTs and demonstrate, also for the two kinds of tested functionalized MWCNTs toxic effects with a different mechanism of action. Copyright © 2015 John Wiley & Sons, Ltd.