Single cell in situ detection and quantification of metal oxide nanoparticles using multimodal correlative microscopy.

Assessing in situ nanoparticles (NPs) internalization at the level of a single cell is a difficult but critical task due to their potential use in nanomedicine. One of the main actual challenges is to control the number of internalized NPs per cell. To in situ detect, track, and above all quantify NPs in a single cell, we propose an approach based on a multimodal correlative microscopy (MCM), via the complementarity of three imaging techniques: fluorescence microscopy (FM), scanning electron microscopy (SEM), and ion beam analysis (IBA). This MCM was performed on single targeted individual primary human foreskin keratinocytes (PHFK) cells cultured and maintained on a specifically designed sample holder, to probe either dye-modified or bare NPs. The data obtained by both FM and IBA on dye-modified NPs were strongly correlated in terms of detection, tracking, and colocalization of fluorescence and metal detection. IBA techniques should therefore open a new field concerning specific studies on bare NPs and their toxicological impact on cells. Complementarity of SEM and IBA analyses provides surface (SEM) and in depth (IBA) information on the cell morphology as well as on the exact localization of the NPs. Finally, IBA not only provides in a single cell the in situ quantification of exogenous elements (NPs) but also that all the other endogenous elements and the subsequent variation of their homeostasis. This unique feature opens further insights in dose-dependent response analyses and adds the perspective of a better understanding of NPs behavior in biological specimens for toxicology or nanomedicine purposes.

A PIXE and ICP-MS analysis of metallic atmospheric contaminants in tree bark tissues, a basis for biomonitoring uses.

The qualitative and quantitative metallic content of tree barks of Argania spinosa (L.) Skeels were studied. Argania spinosa is an endemic species in Morocco. This tree is adapted to semi-arid climates and exposed to specific conditions of relative humidity, temperature, wind, and particle transport. Three sites were sampled in Morocco: the large town of Rabat, the harbor of Agadir, and Aït Baha, a countryside location exposed to continuous desert wind. The methodologies included (1) in situ microanalysis with proton-induced X-ray emission (PIXE) and (2) trace element determinations by mass spectrometry with inductively coupled plasma (ICP-MS) associated with extraction procedures. Both methods allowed detection of elements coming from different bark compartments. The profile of airborne contaminants in the barks was typical of the sampling sites. The level of lead in barks sampled in Rabat reached 100 ng cm(-2), or higher, while it varied between 3 and 35 ng cm(-2) in Aït Baha. The in situ study of the microscopic structure of the bark provided the location of major and minor elements at various depths inside the bark. A differential between free deposit on the bark surface and penetrated content was found for the major and trace elements. The free deposit on the bark surface was suspected to be mostly the result of recent contamination. Part of the contaminants spread out on the surface penetrated the superficial suber. This long-term accumulation affected mostly Pb. In deeper levels, airborne elements at low concentrations and elements resulting from root uptake were concurrently present and resulted in a complex situation, as noted for zinc.

Factors to consider for trace element deposition biomonitoring surveys with lichen transplants.

A trace element deposition biomonitoring experiment with transplants of the fruticose lichen Evernia prunastri was developed, aimed at monitoring the effects of different exposure parameters (exposure orientation and direct rain) and to the elements Ti, V, Cr, Co, Cu, Zn, Rb, Cd, Sb and Pb. Accumulations were observed for most of the elements, confirming the ability of Evernia transplants for atmospheric metal deposition monitoring. The accumulation trends were mainly affected by the exposure orientation and slightly less so by the protection from rain. The zonation of the trace elements inside the thallus was also studied. It was concluded that trace element concentrations were not homogeneous in Evernia, thus imposing some cautions on the sampling approach. A nuclear microprobe analysis of an E. prunastri transplanted thallus in thin cross-sections concluded that the trace elements were mainly concentrated on the cortex of the thallus, except Zn, Ca and K which were also present in the internal layers. The size of the particles deposited or entrapped on the cortex surface averaged 7 microm. A list of key parameters to ensure the comparability of surveys aiming at observing temporal or spatial deposition variation is presented.