Extracellular vesicle (EV) research increasingly demands for quantitative characterisation at the single vesicle level to address heterogeneity and complexity of EV subpopulations. Emerging, commercialised technologies for single EV analysis based on, for example, imaging flow cytometry or imaging after capture on chips generally require dedicated instrumentation and proprietary software not readily accessible to every lab. This limits their implementation for routine EV characterisation in the rapidly growing EV field. We and others have shown that single vesicles can be detected as light diffraction limited fluorescent spots using standard confocal and widefield fluorescence microscopes. Advancing this simple strategy into a process for routine EV quantitation, we developed ‘EVAnalyzer’, an ImageJ/Fiji (Fiji is just ImageJ) plugin for automated, quantitative single vesicle analysis from imaging data. Using EVAnalyzer, we established a robust protocol for capture, (immuno‐)labelling and fluorescent imaging of EVs. To exemplify the application scope, the process was optimised and systematically tested for (i) quantification of EV subpopulations, (ii) validation of EV labelling reagents, (iii) in situ determination of antibody specificity, sensitivity and species cross‐reactivity for EV markers and (iv) optimisation of genetic EV engineering. Additionally, we show that the process can be applied to synthetic nanoparticles, allowing to determine siRNA encapsulation efficiencies of lipid‐based nanoparticles (LNPs) and protein loading of SiO 2 nanoparticles. EVAnalyzer further provides a pipeline for automated quantification of cell uptake at the single cell–single vesicle level, thereby enabling high content EV cell uptake assays and plate‐based screens. Notably, the entire procedure from sample preparation to the final data output is entirely based on standard reagents, materials, laboratory equipment and open access software. In summary, we show that EVAnalyzer enables rigorous characterisation of EVs with generally accessible tools. Since we further provide the plugin as open‐source code, we expect EVAnalyzer to not only be a resource of immediate impact, but an open innovation platform for the EV and nanoparticle research communities.
BACKGROUND/AIMS: Trypan blue is routinely used in cell culture experiments to distinguish between dead cells, which are labelled by trypan blue, and viable cells, which are apparently free of any staining. The assumption that trypan blue labelling is restricted to dead cells derives from the observation that rupture of the plasma membrane correlates with intense trypan blue staining. However, decades ago, trypan blue has been used to trace fluid uptake by viable macrophage-like cells in animals. These studies contributed to the concept of the reticuloendothelial system in vertebrates. Trypan blue itself does not show a fluorescence signal, but trypan blue-labelled proteins do. Therefore, intracellular localization of trypan blue-labelled proteins could give a clue to the entrance pathway of the dye in viable cells. METHODS: We used fluorescence microscopy to visualize trypan blue positive structures and to evaluate whether the bactericide, silver, enhances cellular trypan blue uptake in the brain macrophage-like cell line, BV-2. The pattern of chromatin condensation, visualized by DAPI staining, was used to identify the cell death pathway. RESULTS: We observed that silver nitrate at elevated concentrations (≥ 10 µM) induced in most cells a necrotic cell death pathway. Necrotic cells, identified by pycnotic nuclei, showed an intense and homogenous trypan blue staining. Apoptotic cells, characterized by crescent-like nuclear chromatin condensations, were not labelled by trypan blue. At lower silver nitrate concentrations, most cells were viable, but they showed trypan blue labelling. Viable cells showed a cell-type specific distribution of heterochromatin and revealed a perinuclear accumulation of bright trypan blue-labelled vesicles and, occasionally, a faint homogenous trypan blue labelling of the cytoplasm and nucleus. Amiloride, which prevents macropinocytosis by blocking the Na+ / H+ exchange, suppressed perinuclear accumulation of dye-labelled vesicles. Swelling of cells in a hypotonic solution induced an intense intracellular accumulation of trypan blue. Cells exposed to a hypotonic solution in the presence of 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB), which blocks volume-regulated ion channels, prevented labelling of the cytoplasm and nucleus but did not affect labelling of perinuclear vesicles. CONCLUSION: In viable cells trypan blue-labelled vesicles indicate trypan blue uptake by macropinocytosis and trypan blue-labelled cytosol could indicate a further entry pathway for the dye, like activated volume-regulated channels. Accordingly, fluorescence microscopic analysis of trypan blue-labelled cells allows not only a discrimination between necrotic and apoptotic cell death pathway but also a discrimination between the mode of trypan blue uptake in viable cells - via pinocytosis or via activated volume-regulated ion channels - in the same preparation at the single cell level.
Extracellular vesicles (EVs) are highly interesting for the design of next-generation therapeutics. However, their preparation methods face challenges in standardization, yield, and reproducibility. Here, we describe a highly efficient and reproducible EV preparation method for monodisperse nano plasma membrane vesicles (nPMVs), which yields 10 to 100 times more particles per cell and hour than conventional EV preparation methods. nPMVs are produced by homogenizing giant plasma membrane vesicles following cell membrane blebbing and apoptotic body secretion induced by chemical stressors. nPMVs showed no significant differences compared to native EVs from the same cell line in cryo-TEM analysis, in vitro cellular interactions, and in vivo biodistribution studies in zebrafish larvae. Proteomics and lipidomics, on the other hand, suggested substantial differences consistent with the divergent origin of these two EV types and indicated that nPMVs primarily derive from apoptotic extracellular vesicles. nPMVs may provide an attractive source for developing EV-based pharmaceutical therapeutics.
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