Abstract
The biomolecular imaging of cell-nanoparticle (NP) interactions using time-of-flight secondary ion mass spectrometry (ToF-SIMS) represents an evolving tool in nanotoxicology. In this study we present the three dimensional (3D) distribution of nanomaterials within biomolecular agglomerates using ToF-SIMS imaging. This novel approach was used to model the resistance of human alveolar A549 cells against gold (Au) ion toxicity through intra- and extracellular biomineralization. At low Au concentrations (≤1 mM HAuCl4) 3D-ToF-SIMS imaging reveals a homogenous intracellular distribution of Au-NPs in combination with polydisperse spherical NPs biomineralized in different layers on the cell surface. However, at higher precursor concentrations (≥2 mM) supplemented with biogenic spherical NPs as seeds, cells start to biosynthesize partially embedded long aspect ratio fiber-like Au nanostructures. Most interestingly, A549 cells seem to be able to sense the enhanced Au concentration. They change the chemical composition of the extracellular NP agglomerates from threonine-O-3-phosphate aureate to an arginine-Au(I)-imine. Furthermore they adopt the extracellular mineralization process from spheres to irregular structures to nanoribbons in a dose-dependent manner with increasing Au concentrations. The results achieved regarding size, shape and chemical specificity were cross checked by SEM-EDX and single particle (sp-)ICP-MS. Our findings demonstrate the potential of ToF-SIMS 3D imaging to better understand cell-NP interactions and their impact in nanotoxicology.
Highlights
The biomolecular imaging of cell-nanoparticle (NP) interactions using time-of-flight secondary ion mass spectrometry (ToF-SIMS) represents an evolving tool in nanotoxicology
We demonstrate the combination of scanning electron microscope-energy dispersive X-ray (SEM-EDX) and ToF-SIMS imaging to assess the chemical composition of the de novo synthesized nanostructures
ToF-SIMS 3D imaging of human alveolar epithelial cells growing in a mild chemical environment
Summary
The biomolecular imaging of cell-nanoparticle (NP) interactions using time-of-flight secondary ion mass spectrometry (ToF-SIMS) represents an evolving tool in nanotoxicology. The submicron lateral resolution in combination with a high depth resolution for organic samples (down to 10 nm3) enables the three dimensional (3D) label-free reconstruction of single cells This makes ToF-SIMS a top emerging and evolving tool for studies relating to the chemical distribution within single cells[4]. We demonstrate the combination of SEM-EDX and ToF-SIMS imaging to assess the chemical composition of the de novo synthesized nanostructures (spheres, irregular shaped particles and nanoribbons). This approach will enable semi-quantitative, marker-free, simultaneous analysis of all cell membrane components while cells undergo biochemical changes at different Au ion precursor concentrations. The combination of ToF-SIMS, X-ray spectroscopy and scanning microscopy reveals the fine structure and the biomolecular distribution that cannot be seen by conventional techniques in such a non-invasive manner
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