CellROX™ Deep Red Flow Cytometry Assay Kit - FAQs

View additional product information for CellROX™ Deep Red Flow Cytometry Assay Kit - FAQs (C10491)

6 product FAQs found

I want to assay cells for reactive oxygen species using carboxy-H2DCFDA, but I want to do so with a plate reader instead of microscope. Will it work?

It has been done. The problem is that plate readers are less sensitive than microscopes, with far less signal-to-background difference. It is worth trying, but first optimize concentrations and loading times with control cells, use a plate with little to no autofluorescence, and possibly optimize the gain setting in order to get the best signal possible. But don't expect the same sensitivity, even with optimization.

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I have GFP-transfected cells and need to label for reactive oxygen species. Can I use H2DCFDA?

This is not recommended as the two dyes overlap in the emission wavelength. There are other ROS reagents available in different wavelengths, such as CellROX Deep Red, which emits in the far-red range (665 nm), or dihydroethidium, which is emits in the visible red range (620 nm).

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I need a formaldehyde-fixable reactive oxygen species detection assay. Is H2 DCFDA fixable?

H2DCFDA and similar derivatives are not fixable. The same goes for dihydroethidium and dihydrorhodamine. However, CellROX Deep Red and CellROX Green are retained for a limited time upon fixation with formaldehyde. CellROX Green may be retained upon subsequent Triton X-100 permeabilization. Avoid the use of any acetone or alcohol-based fixatives or fixatives that include alcohol, such as formalin.

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What dyes can I use to detect reactive oxygen species (ROS) in my bacteria?

Many dyes that are used on mammalian cells have also been shown to be useful in bacterial cells. For example, CellROX Deep Red Reagent has been shown to work in B. subtilis (see Reference: http://www-brs.ub.ruhr-uni-bochum.de/netahtml/HSS/Diss/RaatschenNadja/diss.pdf). If you are interested in a particular dye, but are not sure if it will work on your bacteria, literature searches are the best way to check to see if it has been tested. If not, then it may be worth testing yourself.

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What cellular processes can be analyzed with a flow cytometer?

-Calcium flux: Each of the Oregon Green calcium indicators binds intracellular calcium with increasing affinity, providing a sensitivity range to match many applications. Oregon Green probes emit green fluorescence at resting levels of Ca2+ and increase their fluorescence intensity 14-fold with increasing Ca2+ concentration. The cell-permeant formulation (Cat. No. O6807) can be loaded in cell media and is compatible with flow cytometry.
-Rhodamine-based calcium indicators comprise a range of probes for large or small changes in Ca2+ concentration. They exhibit a 50-fold increase in fluorescence upon calcium binding and offer a range of wavelengths that can be used in conjunction with GFP or green-fluorescent dyes for multiplexing. Rhod-2, AM (Cat. No. R1245MP), in particular, localizes to mitochondria and can be used with flow cytometry.
-Membrane potential: A distinctive feature of the early stages of apoptosis is the disruption of the mitochondria, including changes in membrane and redox potential. We offer a range of products specifically designed to assay mitochondrial membrane potential in live cells by flow cytometry, with minimal disruption of cellular function. The MitoProbe family of mitochondrial stains (Cat. Nos. M34150, M34151, and M34152) provide quick, easy, and reliable flow cytometric detection of the loss of mitochondrial membrane potential that occurs during apoptosis. MitoTracker dyes (Cat. Nos. M7510 and M7512) are membrane potential-dependent probes for staining mitochondria in live cells. The staining pattern of MitoTracker dyes is retained throughout subsequent flow cytometry immunocytochemistry, DNA end labeling, in situ hybridization, or counterstaining steps. The Mitochondrial Permeability Transition Pore Assay (Cat. No. M34153) provides a more direct method of measuring mitochondrial permeability transition pore opening than assays relying on mitochondrial membrane potential alone. The mitochondrial permeability transition pore (MPTP) is a non-specific channel formed by components from the inner and outer mitochondrial membranes, and appears to be involved in the release of mitochondrial components during cell death.
-Phagocytosis: In phagocytosis, cells internalize particulate matter such as microorganisms, and this process is important for immune responses and during the clearance of apoptotic cells. Probes for studying phagocytosis include BioParticles indicators—bacteria and yeast labeled with fluorescent dyes.
-Tracking phagocytosis using a quench/wash-based assay can report on simple uptake, or a pH indicator can be used to monitor stages in the pathway. We have no-wash assays labeled with pHrodo Red or Green (Cat. Nos. A10010, P35361, P35364, P35365, P35366, and P35367) and no-wash assays for whole blood (Cat. Nos. A10025, A10026, P35381, and P35382), all suitable for flow cytometry.
-pH changes: Sensitive pH determinations can be made in a physiological range using either fluorescent intensity or ratiometric measurements. pHrodo dyes (Cat. Nos. P35373 and P35372) provide signal intensity modulation from pH 2 to pH 9 and with a choice of fluorescent wavelengths. Tracking internalization of fluorescent dextran is a routine method for analyzing pH changes in cellular compartments. Dextran conjugates of pHrodo dyes (Cat. Nos. P35368 and P10361) provide the most complete solution by allowing discrimination of vesicles from early endosomes to lysosomes, with no quench or wash required.
-Reactive oxygen species: Cells that are environmentally stressed usually contain greatly increased levels of reactive oxygen species (ROS). CellROX reagents are fluorogenic probes developed for the detection and quantitation of ROS in live cells. These cell-permeant reagents are non-fluorescent or very weakly fluorescent in the reduced state; however, when oxidized, they become brightly fluorescent and remain localized within the cell. We offer CellROX Green (Cat. No. C10492), CellROX Orange (Cat. No. C10493), and CellROX Deep Red (Cat. No. C10491) Assay Kits validated for flow cytometry.

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I am trying to label my cells with a reactive oxygen species (ROS) indicator dye, but I am not seeing a significant difference in signal. What could be happening?

First, make sure you have both a negative (untreated) and positive (ROS-induced) sample to compare. A good positive control can be the use of 100 µM menadione for one hour or 50 µM nefazodone for 24 hours. H2O2 can also be used, though it does not work well for CellROX dyes. Some dyes, such as H2DCFDA, require esterase cleavage, so don't incubate in the presence of serum (which contains esterases that can prematurely cleave the dye). If your positive control does not show significant change compared to the negative control, try increasing the concentration and label time for the dye. Our manuals give starting recommendations. Be sure to image your live cells as soon as possible. Only two dyes (CellROX Green and CellROX Deep Red) are retained with formaldehyde fixation. Finally, make sure you are using filters and instrument settings to match the excitation and emission spectra of the dye.

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