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There is also a growing appreciation that it is important to assess cells not only in their quiescent state, but also in response to various stimuli. Recent advances in instrumentation such as 4 and 5 color laser systems and the availability of reagents and protocols for assessing internal proteins and their phosphorylation state are serving to make flow cytometry a very important tool for understanding disease processes in human biology. Flow cytometers measure individual cells, and thus are capable of revealing subtleties of biology that other technologies cannot detect. We will go into more detail regarding the important rules in Chapter 4, Controls in flow cytometry.Flow cytometry is a high-information content platform that is increasingly becoming a high-throughput platform as well. The definition of a compensation control is simple: for each fluorophore used in the experiment, a single-stained cell or bead sample must also be prepared. Since compensation controls are critical to the determination of what we call positive or negative for a given marker in an experiment, they are absolutely critical to the success of the experiment. There are a few basic principles to remember when designing compensation controls for an experiment. To find out more about our B, T, NK and myeloid panels go to our no compensation panels webpage. They are great to identify common populations or as a start to build larger more complex panels. We have created common human immunophenotyping panels, using 4 fluorophores, which require no compensation. Alternatively you can combine fluorophores that can only be activated by specific individual laser lines, (providing the lasers are spatially separated), but as you increase the number of fluorophores this becomes practically impossible. You can avoid the need for compensation by using fluorophores that do not have overlapping emission spectra.
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When compensation was not applied, fluorescence spillover can be seen (top panel), which is removed after compensation (bottom panel). Peripheral blood was singly stained with CD4 FITC, CD19 PE, or both CD4 FITC and CD19 PE. Fluorescence compensation corrects for spectral overlap. After compensation we can see that in fact there are no double positive cells, which is to be expected from these mutually exclusive markers.įig.
#Flowjo 10 manual compensation software
The software calculates spillover values and will apply this to the data to obtain correctly compensated data. However when the correct level of compensation is applied using software the true level of staining is revealed. When the sample is stained with both fluorophores, without compensation, a double positive population is observed. Single stained samples reveal the amount of spectral overlap. We can see in Figure 12 how compensation can be applied to a sample stained with antibodies conjugated to FITC and PE. This process becomes even more complicated when photons from multiple dyes are detected in each PMT. Shown in red is the portion of the FITC spectrum that will be detected in the PE detector (585/40) and that must be subtracted from the PE signal using compensation. Also shown is a graphical representation of two commonly used filters, 525/50 and 585/40, to detect these fluorophores. Emission spectra of two fluorophores commonly used in flow cytometry, FITC and PE are shown.
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In those cases the relative contribution of each fluorophore to the signal in a given detector must be determined (Figure 11).įig. In some experiments FITC may be combined with other dyes, for example PE, that emit yellow and orange photons. Gates are shown to identify the FITC positive cells and their spillover. FITC single stained lymphocytes show spillover into PE and PE-Cy5 detectors. In some experiments FITC may be combined with other dyes, for example PE, that emit yellow and orange photons.įig. For example, FITC emits photons that are green, yellow and orange, all of which can be detected on a multidetector instrument with the corresponding detectors (Figure 10). Due to the nature of flow cytometry measurements, a particle’s emission is measured not in a single detector, but in all the detectors being used in the experiment. Because the fluorophores used in flow cytometry emit photons of multiple energies and wavelengths, a mathematical method called compensation was developed to address the measurement of the photons of one fluorophore in multiple detectors. One consideration when performing multicolor fluorescence studies is the possibility of spectral overlap between fluorophores.