Nile red staining of lysosomal phospholipid inclusions

Brown, W. J.; Sullivan, Tim R.; Greenspan, Phillip

doi:10.1007/bf00270037

Cited by 82 publications

(60 citation statements)

References 15 publications

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“…Microscopy is another method used for studying uptake and distribution of NPs (18,22,37,43). However, microscopy should be employed with care in the assessment of dye leakage, as free hydrophobic dyes will bind to intracellular hydrophobic molecules resulting in both diffuse and spotted staining pattern (12,24,30,33), thereby making the dye hard to separate from the fluorescence of intact NPs. In a previous study, we have shown that PBCA-NPs with NR668 are taken up in PC3 cells by endocytosis, verified by the use of time consuming intracellular spectral microscopy and fluorescence-lifetime imaging microscopy (FLIM) (12).…”

Section: Discussionmentioning

confidence: 99%

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Labeling nanoparticles: Dye leakage and altered cellular uptake

et al. 2016

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In vitro and in vivo behavior of nanoparticles (NPs) is often studied by tracing the NPs with fluorescent dyes. This requires stable incorporation of dyes within the NPs, as dye leakage may give a wrong interpretation of NP biodistribution, cellular uptake and intracellular distribution. Furthermore, NP labeling with trace amounts of dye should not alter NP properties such as interactions with cells or tissues.To allow for versatile NP studies with a variety of fluorescence-based assays, labeling of NPs with different dyes is desirable. Hence, when new dyes are introduced, simple and fast screening methods to assess labeling stability and NP-cell interactions are needed. For this purpose we have used a previously described generic flow cytometry assay; incubation of cells with NPs at 4°C and 37°C. Cell-NP interaction is confirmed by cellular fluorescence after 37°C incubation, and NP dye retention is confirmed when no cellular fluorescence is detected at 4°C.Three different NP-platforms labeled with six different dyes were screened, and a great variability in dye retention was observed. Surprisingly, incorporation of trace amounts of certain dyes was found to reduce, or even inhibit NP uptake. This work highlights the importance of thoroughly evaluating every dye-NP combination before pursuing fluorescent NP applications.3

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Section: Discussionmentioning

confidence: 99%

“…Various procedures have been developed to evaluate NP-labeling stability (18,20,23,(25)(26)(27)(28)(29). However, the majority of these assays do not include cells or serum, which could strongly affect dye release as these serve as acceptor compartments for released dye in vivo (18,24,(29)(30)(31)(32)(33).…”

Section: Introductionmentioning

confidence: 99%

Labeling nanoparticles: Dye leakage and altered cellular uptake

et al. 2016

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“…These images were analyzed by the Factor Analysis of Medical Image Sequences (FAMIS) algorithm, which provides factor curves and images (31,32). The ability to colocalize 7KC (emitting a blue fluorescence under ultraviolet [UV] light) (33) and cellular lipids stained with NR is possible because of the overlap of the emission spectra of 7KC with the excitation spectra of NR (33)(34)(35). In addition, subcellular fractionation associated with gas chromatography and mass spectrometry was used to characterize NR-positive cytoplasmic structures.…”

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confidence: 99%

7‐Ketocholesterol favors lipid accumulation and colocalizes with Nile Red positive cytoplasmic structures formed during 7‐ketocholesterol–induced apoptosis: Analysis by flow cytometry, FRET biphoton spectral imaging microscopy, and subcellular fractionation

et al. 2005

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Background: Oxidized low-density lipoproteins play key roles in atherosclerosis. Their toxicity is at least in part due to 7-ketocholesterol (7KC), which is a potent inducer of apoptosis. In this study on human promonocytic U937 cells, we determined the effects and the interactions of 7KC with cellular lipids during 7KC-induced apoptosis. Methods: Morphologic and functional changes were investigated by microscopic and flow cytometric methods after staining with propidium iodide, 3,3Ј-dihexyloxacarbocyanine iodide, and Hoechst 33342. Cellular lipid content was identified by using filipin to quantify free cholesterol and Nile Red (NR), which emit a yellow or orangered fluorescence in the presence of neutral and polar lipids, respectively. After staining with NR, interactions of 7KC with cellular lipids were identified by fluorescence resonance energy transfer biphoton spectral imaging confocal microscopy and by subcellular fractionation, gas chromatography, and mass spectrometry.

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“…Fluorescence and light microscopy have been instrumental in locating and identifying lipid components of atherosclerotic lesions in animal models and human biopsy tissues (Brown et al 1992;Seifert 1989;Lupu et al 1987;Fowler and Greenspan 1985;Kruth 1984aKruth ,b,1985Kruth and Fry 1984). Immunohistochemical (IH) methods have been used to distinguish populations of smooth muscle cells and macrophages in atherosclerotic lesions (Masuda and Ross 1990;Rosenfeld et al 1987;Tsukada et al 1986), and many authors have used electron microscopy to characterize cell types and investigate intracellular aspects of atherosclerosis (Masuda and Ross 1990;Lupu et al 1987;Rosenfeld et al 1987).…”

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confidence: 99%

A Novel Technique For Mapping the Lipid Composition of Atherosclerotic Fatty Streaks by En Face Fluorescence Microscopy

Klinkner

Bugelski

Waites

et al. 1997

J Histochem Cytochem.

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SUMMARYWe introduce here a new fluorescence microscopy technique for en face analysis of the atherosclerotic fatty streaks (FS). This technique is semiquantitative and has the sensitivity and resolution to map lipids to individual cells in FS less than 100 m in diameter. New Zealand White rabbits were fed an atherogenic diet for up to 26 weeks. Aortas were fixed in formalin and stained en bloc with the fluorescent dyes Nile red and filipin. Fluorescent staining was validated by correlating microfluorimetric and biochemical measurements of the lipid content in FS. To determine the cell types associated with the different staining patterns, FS were also evaluated by transmission electron microscopy (TEM) and immunohistochemistry (IH). Correlation of microfluorimetry, TEM, IH, and biochemical data indicated that regions rich in non-esterified cholesterol stained with filipin and fluoresced blue owing to accumulations of lipid vessicles and/or cholesterol crystals. Regions rich in neutral and polar lipids stained with Nile red and fluoresced yellow or orange, respectively, owing to accumulations of lipids in both macrophages and smooth muscle cells (SMC). Digital overlays of the filipin and Nile red images revealed that larger lesions ( Ͼ 0.5 mm diameter) had a "nested" distribution of lipids, with a blue (filipin) fringe surrounding an orange (Nile red) fringe surrounding a yellow (Nile red) center.

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Nile red staining of lysosomal phospholipid inclusions

Cited by 82 publications

References 15 publications

Labeling nanoparticles: Dye leakage and altered cellular uptake

Labeling nanoparticles: Dye leakage and altered cellular uptake

7‐Ketocholesterol favors lipid accumulation and colocalizes with Nile Red positive cytoplasmic structures formed during 7‐ketocholesterol–induced apoptosis: Analysis by flow cytometry, FRET biphoton spectral imaging microscopy, and subcellular fractionation

A Novel Technique For Mapping the Lipid Composition of Atherosclerotic Fatty Streaks by En Face Fluorescence Microscopy

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