Air-Liquid Interface Exposure of Lung Epithelial Cells to Low Doses of Nanoparticles to Assess Pulmonary Adverse Effects.
Silvia DiabatéLucie ArmandSivakumar MurugadossMarco DilgerSusanne Fritsch-DeckerChristoph SchlagerDavid BéalMarie-Edith ArnalMathilde Biola-ClierSelina AmbroseSonja MülhoptHanns-Rudolf PaurIseult LynchEugenia Valsami-JonesMarie CarriereCarsten WeissPublished in: Nanomaterials (Basel, Switzerland) (2020)
Reliable and predictive in vitro assays for hazard assessments of manufactured nanomaterials (MNMs) are still limited. Specifically, exposure systems which more realistically recapitulate the physiological conditions in the lung are needed to predict pulmonary toxicity. To this end, air-liquid interface (ALI) systems have been developed in recent years which might be better suited than conventional submerged exposure assays. However, there is still a need for rigorous side-by-side comparisons of the results obtained with the two different exposure methods considering numerous parameters, such as different MNMs, cell culture models and read outs. In this study, human A549 lung epithelial cells and differentiated THP-1 macrophages were exposed under submerged conditions to two abundant types of MNMs i.e., ceria and titania nanoparticles (NPs). Membrane integrity, metabolic activity as well as pro-inflammatory responses were recorded. For comparison, A549 monocultures were also exposed at the ALI to the same MNMs. In the case of titania NPs, genotoxicity was also investigated. In general, cells were more sensitive at the ALI compared to under classical submerged conditions. Whereas ceria NPs triggered only moderate effects, titania NPs clearly initiated cytotoxicity, pro-inflammatory gene expression and genotoxicity. Interestingly, low doses of NPs deposited at the ALI were sufficient to drive adverse outcomes, as also documented in rodent experiments. Therefore, further development of ALI systems seems promising to refine, reduce or even replace acute pulmonary toxicity studies in animals.
Keyphrases
- oxide nanoparticles
- gene expression
- pulmonary hypertension
- endothelial cells
- high throughput
- dna methylation
- intensive care unit
- induced apoptosis
- high intensity
- signaling pathway
- mass spectrometry
- cell proliferation
- single molecule
- high resolution
- cell death
- extracorporeal membrane oxygenation
- pi k akt
- atomic force microscopy