Quantification of nanoparticle uptake by cells using an unbiased sampling method and electron microscopy.

AIMS: By randomly sampling a known fraction of a pellet of cultured cells, we have accurately estimated the mean number of 50 nm gold nanoparticles accumulated within a single cell. Cellular nanoparticle uptake was measured using a combination of stereological sampling techniques and transmission electron microscopy. MATERIALS & METHODS: Nanoparticles were counted individually and their intracellular location was recorded. Quantifying cell and nanoparticle number by analyzing a known fraction of the sample led to precise estimates of intracellular nanoparticle numbers and their spatial locations on an ultrastructural level. We propose a simple and reliable fractionator design and show its applicability and potential using fibroblast cells exposed to 50-nm gold nanoparticles. RESULTS & CONCLUSION: We demonstrate that this approach is suitable for any electron-dense nanomaterial resolvable by electron microscopy and any convex-shaped cells. In addition, the fractionator concept is flexible enough to be used for spatio-temporal or in vivo studies.

Cryo DualBeam Focused Ion Beam-Scanning Electron Microscopy to Evaluate the Interface Between Cells and Nanopatterned Scaffolds.

With the advance of nanotechnology in biomaterials science and tissue engineering, it is essential that new techniques become available to observe processes that take place at the direct interface between tissue and scaffold materials. Here, Cryo DualBeam focused ion beam-scanning electron microscopy (FIB-SEM) was used as a novel approach to observe the interactions between frozen hydrated cells and nanometric structures in high detail. Through a comparison of images acquired with transmission electron microscopy (TEM), conventional FIB-SEM operated at ambient temperature, and Cryo DualBeam FIB-SEM, the advantages and disadvantages of each technique were evaluated. Ultrastructural details of both (extra)cellular components and cell organelles were best observe with TEM. However, processing artifacts such as shrinkage of cells at the substrate interface were introduced in both TEM and conventional FIB-SEM. In addition, the cellular contrast in conventional FIB-SEM was low; consequently, cells were difficult to distinguish from the adjoining substrate. Cryo DualBeam FIB-SEM did preserve (extra)cellular details like the contour, cell membrane, and mineralized matrix. The three described techniques have proven to be complementary for the evaluation of processes that take place at the interface between tissue and substrate.

Reproducible comet assay of amorphous silica nanoparticles detects no genotoxicity.

Genotoxicity of commercial colloidal and laboratory-synthesized silica nanoparticles was tested using the single cell gel electrophoresis or Comet assay. By using a carefully developed protocol and careful characterization of the nanoparticle dispersions, Comet assays were performed on 3T3-L1 fibroblasts with 3, 6, and 24 h incubations and 4 or 40 microg/ml of silica nanoparticles. No significant genotoxicity was observed for the nanoparticles tested under the conditions described, and results were independently validated in two separate laboratories, showing that in vitro toxicity testing can be quantitatively reproducible.