Detection of Silver and TiO Nanoparticles in Cells by Flow Cytometry.

Evaluation of the potential hazard of man-made nanomaterials has been hampered by a limited ability to observe and measure nanoparticles in cells. A FACSCalibur™ flow cytometer and a Stratedigm S-1000 flow cytometer were used to measure changes in light scatter from cells after incubation with either silver nanoparticles (AgNP) or TiO nanoparticles. Within the range of between 0.

Combination of Dark-Field and Confocal Microscopy for the Optical Detection of Silver and Titanium Nanoparticles in Mammalian Cells.

We describe here two optical microscopy techniques-dark-field confocal light scanning microscopy (DF-CLSM) and dark-field wide-field confocal microscopy (DF-WFCM), that can be used to study interaction between nanoparticles and cells in 3D space. Dark field microscopy can detect very small structures below the diffraction limit of conventional light microscopes, while a confocal setup provides vertical sectioning capabilities to render specimens in 3D. The use of DF-WFCM instead of DF-CLSM allows faster sample processing but yields lower resolution.

Detection of TiO2 nanoparticles in cells by flow cytometry.

Evaluation of the potential hazard of man-made nanomaterials has been hampered by a limited ability to observe and measure nanoparticles in cells. A FACSCalibur™ flow cytometer was used to measure changes in light scatter from cells after incubation with TiO(2) nanoparticle. Both the side scatter and forward scatter changed substantially in response to the TiO(2).

Microscopy imaging methods for the detection of silver and titanium nanoparticles within cells.

Scientific evaluation of potential environmental hazards resulting from man-made nanomaterials has been hampered by the inability to optimally detect cell-associated nanoparticles. We have successfully imaged TiO(2) nanoparticles in ARPE-19 cells using different light microscope modalities commonly available to investigators including fluorescence, dark field, phase, interference, and confocal. In this report, we describe different optical and lighting conditions necessary for optimal nanoparticle imaging in ARPE-19 cells.