Robert M. Zucker

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. In this study, different concentrations of TiO2 nanoparticles were suspended in cell culture medium. The suspension was then sonicated and characterized by dynamic light scattering and microscopy. Cultured human‐derived retinal pigment epithelial cells (ARPE‐19) were incubated with TiO2 nanoparticles at 0, 0.1, 0.3, 1, 3, 10, and 30 μg/ml for 24 hours. Cellular reactions to nanoparticles were evaluated using flow cytometry and dark field microscopy. A FACSCalibur™ flow cytometer was used to measure changes in light scatter after nanoparticle incubation. Both the side scatter and forward scatter changed substantially in response to the TiO2. From 0.1 to 30 μg/ml TiO2, the side scatter increased sequentially while the forward scatter decreased, presumably due to substantial light reflection by the TiO2 particles. Based on the parameters of morphology and the calcein‐AM/propidium iodide viability assay, TiO2 concentrations below 30 μg/ml TiO2 caused minimal cytotoxicity. Microscopic analysis was done on the same cells using an E‐800 Nikon microscope containing a xenon light source and special dark field objectives. At the lowest concentrations of TiO2 (0.1–0.3 μg/ml), the flow cytometer could detect as few as 5–10 nanoparticles per cell due to intense light scattering by TiO2. Rings of concentrated nanoparticles were observed around the nuclei in the vicinity of the endoplasmic reticulum at higher concentrations. These data suggest that the uptake of nanoparticles within cells can be monitored with flow cytometry and confirmed by dark field microscopy. This approach may help fulfill a critical need for the scientific community to assess the relationship between nanoparticle dose and cellular toxicity Such experiments could potentially be performed more quickly and easily using the flow cytometer to measure both nanoparticle uptake and cellular health. Published 2010 Wiley‐Liss, Inc.

The pros and cons of apoptosis assays for use in the study of cells, tissues, and organs.

Programmed cell death or apoptosis occurs in many tissues during normal development and in the normal homeostasis of adult tissues. Apoptosis also plays a significant role in abnormal development and disease. Increased interest in apoptosis and cell death in general has resulted in the development of new techniques and the revival of old ones. Each assay has its advantages and disadvantages that can render it appropriate and useful for one application, but inappropriate or difficult to use in another. Understanding the strengths and limitations of the assays would allow investigators to select the best methods for their needs.

Effect of treatment media on the agglomeration of titanium dioxide nanoparticles: impact on genotoxicity, cellular interaction, and cell cycle.

The widespread use of titanium dioxide (TiO2) nanoparticles in consumer products increases the probability of exposure to humans and the environment. Although TiO2 nanoparticles have been shown to induce DNA damage (comet assay) and chromosome damage (micronucleus assay, MN) in vitro, no study has systematically assessed the influence of medium composition on the physicochemical characteristics and genotoxicity of TiO2 nanoparticles. We assessed TiO2 nanoparticle agglomeration, cellular interaction, induction of genotoxicity, and influence on cell cycle in human lung epithelial cells using three different nanoparticle-treatment media: keratinocyte growth medium (KGM) plus 0.1% bovine serum albumin (KB); a synthetic broncheoalveolar lavage fluid containing PBS, 0.6% bovine serum albumin and 0.001% surfactant (DM); or KGM with 10% fetal bovine serum (KF). The comet assay showed that TiO2 nanoparticles induced similar amounts of DNA damage in all three media, independent of the amount of agglomeration, cellular interaction, or cell-cycle changes measured by flow cytometry. In contrast, TiO2 nanoparticles induced MN only in KF, which is the medium that facilitated the lowest amount of agglomeration, the greatest amount of nanoparticle cellular interaction, and the highest population of cells accumulating in S phase. These results with TiO2 nanoparticles in KF demonstrate an association between medium composition, particle uptake, and nanoparticle interaction with cells, leading to chromosomal damage as measured by the MN assay.

In Vitro Phototoxicity and Hazard Identification of Nano-scale Titanium Dioxide

Titanium dioxide nanoparticles (nano-TiO(2)) catalyze reactions under UV radiation and are hypothesized to cause phototoxicity. A human-derived line of retinal pigment epithelial cells (ARPE-19) was treated with six samples of nano-TiO(2) and exposed to UVA radiation. The TiO(2) nanoparticles were independently characterized to have mean primary particle sizes and crystal structures of 22nm anatase/rutile, 25nm anatase, 31nm anatase/rutile, 59nm anatase/rutile, 142nm anatase, and 214nm rutile. Particles were suspended in cell culture media, sonicated, and assessed for stability and aggregation by dynamic light scattering. Cells were treated with 0, 0.3, 1, 3, 10, 30, or 100μg/ml nano-TiO(2) in media for 24hrs and then exposed to UVA (2hrs, 7.53J/cm(2)) or kept in the dark. Viability was assessed 24hrs after the end of UVA exposure by microscopy with a live/dead assay (calcein-AM/propidium iodide). Exposure to higher concentrations of nano-TiO(2) with UVA lowered cell viability. The 25nm anatase and 31nm anatase/rutile were the most phototoxic (LC(50) with UVA<5μg/ml), while the 142nm anatase and 214nm rutile were the least phototoxic. An acellular assay ranked TiO(2) nanoparticles for their UVA photocatalytic reactivities. The particles were found to be capable of generating thiobarbituric acid reactive substances (TBARS) under UVA. Flow cytometry showed that nano-TiO(2) combined with UVA decreased cell viability and increased the generation of reactive oxygen species (ROS, measured by Mitosox). LC(50) values under UVA were correlated with TBARS reactivity, particle size, and surface area.

CONFOCAL LASER SCANNING MICROSCOPY OF APOPTOSIS IN ORGANOGENESIS-STAGE MOUSE EMBRYOS

Confocal laser scanning microscopy combined with a vital stain has been used to study apoptosis in organogenesis-stage mouse embryos. In order to achieve optical sectioning through embryos, it was necessary to use low power objectives and to prepare the sample appropriately. Mouse embryos were harvested on gestation day 8 or 9 and stained with the vital lysosomal dye, LysoTracker Red. Following incubation in the stain, embryos were fixed in 2% paraformaldehyde overnight, dehydrated in a graded methanol series, and cleared in benzyl alcohol/benzyl benzoate. The resulting embryo is almost transparent and retains specific LysoTracker Red staining. The entire embryo can be optically sectioned and reconstructed in three dimensions to reveal areas of dye staining. To test this approach, the chemotherapeutic drug hydroxyurea was added to day 8 embryos in vitro to induce apoptosis. Our results demonstrated specific regions undergoing programmed cell death in normal development and increased apoptosis in embryos exposed to hydroxyurea. The observed patterns of LysoTracker Red staining correlate well with previous studies of cell death using other lysosomotropic dyes such as Nile blue sulfate, acridine orange, or neutral red. LysoTracker Red has the advantages of being aldehyde-fixable and highly fluorescent (bleaching was not observed even after multiple scans). This procedure allows for the optical imaging of whole day 9 (approximately 22 somites) embryos that were greater than 500 microns thick in the Z-axis.

Hindbrain and Cranial Nerve Dysmorphogenesis Result from Acute Maternal Ethanol Administration

Acute exposure of mouse embryos to ethanol during stages of hindbrain segmentation results in excessive cell death in specific cell populations. This study details the ethanol-induced cell loss and defines the subsequent effects of this early insult on rhombomere and cranial nerve development. Ethanol at a teratogenic dosage (2.9 g/kg) or a comparable volume of vehicle was administered in each of two intraperitoneal injections to pregnant C57BL/6J mice on gestational day (GD) 8, 8 h, and GD 8, 12 h (defined hereafter as GD 8.5). Ethanol-exposed GD 9 embryos, visualized in three dimensions using laser scanning confocal microscopy of LysoTracker Red fluorescence or Nile blue sulphate vital staining, displayed excessive apoptosis in the rostral hindbrain, specifically within rhombomeres 1–3, as well as in cranial neural crest cells and ectodermal placodes. Comparably treated embryos examined on GD 10.5–11 illustrated a disproportionate reduction in the length of the rostral hindbrain. Examination of plastic histological sections of GD 9 embryos and via scanning electron microscopy on GD 10 revealed deficiencies in the hindbrain, with a phenotype including abnormal rhombomere segmentation and an extremely small fourth ventricular roofplate. Whole-mount antineurofilament immunohistochemistry on GD 10.5 and GD 11 illustrated a variety of cranial nerve abnormalities ranging from fused or absent ganglia to ectopic or disorganized fibers. In addition, a delay in the development of the glossopharyngeal (IX) nerve/ganglia complex was observed. These hindbrain and cranial nerve abnormalities are discussed in the context of the genesis of human alcohol-related birth defects and neurodevelopmental disorder.

Calibration and validation of confocal spectral imaging systems.

Confocal spectral imaging (CSI) microscopic systems currently on the market delineate multiple fluorescent proteins, labels, or dyes within biological specimens by performing spectral characterizations. However, some CSI systems have been found to present inconsistent spectral profiles of reference spectra within a particular system and between related and unrelated instruments. This variability confirms that there is a need for a standardized, objective calibration and validation protocol.

Detection of silver nanoparticles in cells by flow cytometry using light scatter and far-red fluorescence.

The cellular uptake of different sized silver nanoparticles (AgNP) (10, 50, and 75 nm) coated with polyvinylpyrrolidone (PVP) or citrate on a human derived retinal pigment epithelial cell line (ARPE‐19) was detected by flow cytometry following 24‐h incubation of the cells with AgNP. A dose dependent increase of side scatter and far red fluorescence was observed with both PVP and citrate‐coated 50 nm or 75 nm silver particles. Using five different flow cytometers, a far red fluorescence signal in the 700–800 nm range increased as much as 100 times background as a ratio comparing the intensity measurements of treated sample and controls. The citrate‐coated silver nanoparticles (AgNP) revealed slightly more side scatter and far red fluorescence than did the PVP coated silver nanoparticles. This increased far red fluorescence signal was observed with 50 and 75 nm particles, but not with 10 nm particles. Morphological evaluation by dark field microscopy showed silver particles (50 and 75 nm) clumped and concentrated around the nucleus. One possible hypothesis to explain the emission of far red fluorescence from cells incubated with silver nanoparticles is that the silver nanoparticles inside cells agglomerate into small nano clusters that form surface plasmon resonance which interacts with laser light to emit a strong far red fluorescence signal. The results demonstrate that two different parameters (side scatter and far red fluorescence) on standard flow cytometers can be used to detect and observe metallic nanoparticles inside cells. The strength of the far red fluorescence suggests that it may be particularly useful for applications that require high sensitivity.

Quality assessment of confocal microscopy slide based systems: Performance†

All fluorescence slide‐based cytometry detections systems basically include the following components: (1) an excitation light source, (2) intermediate optics, and (3) a detection device consisting of a CCD camera or a PMT. The optical principles employed is slide‐based systems are similar to those of confocal microscopes (CLSM).

Whole insect and mammalian embryo imaging with confocal microscopy: Morphology and apoptosis

After fluorochromes are incorporated into cells, tissues, and organisms, confocal microscopy can be used to observe three‐dimensional structures. LysoTracker Red (LT) is a paraformaldehyde fixable probe that concentrates into acidic compartments of cells and indicates regions of high lysosomal activity and phagocytosis, which both correlate to apoptosis activity. LT has been shown to be an indicator of apoptotic cell death which is correlated to other standard apoptotic assays.