Flow Cytometry Optimisation

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How can I optimize my experiments?

The essence of flow cytometry is to measure particles one by one when they pass through the light beam. Unfortunately, if the sample is not prepared correctly, the results will also be poor. To ensure success in this experiment, here are a few steps, that you can follow.

How to prepare a sample correctly

To begin with, you should defrost your cells as fast as possible and quickly get rid of the DMSO by resuspending them in BSA containing PBS. Sometimes after defrosting adding the cells to a culture can restore the epitope expression.

 

 

On the other hand, less invasive treatment is preferable for adherent cells. For example, Trypsin can destroy your cells and epitopes, so choosing a gentler method is advisable.

 

 

Furthermore, if you want to discard clumps of cells from lymph nodes or spleen tissue, better filter them than using mechanical disaggregation.

 

 

Finally, the faster you prepare your samples, the better. This doesn’t mean rushing over important steps, but to manage your time efficiently.

Autofluorescence and wavelengths

Autofluorescence is the natural level of fluorescence of the cells. The presence of collagen, elastin, NADPH and riboflavin can contribute to autofluorescence, which can be a major problem in analysing data.

 

 

Usually, cells with more fluorescent compounds are larger, granular cells and this can be detected at short wavelengths for both absorption and emission, around 350 to 550 nm. Mammalian cells tend to get excited by the 488 nm wavelength because they contain specific compounds, that emit in this range.

 

 

Autofluorescence can be a major issue in this case because it lowers the signal-to-noise ratio, resulting in low sensitivity and more false positives. A simple way to measure the level of autofluorescence is by using unstained controls. Using exceptionally bright fluorophores can also lower the impact of this issue.

How to distinguish live from dead cells

Having dead cells in the sample can interfere with the staining and your data quality. Because dead cells have higher autofluorescence, more false positives and reduced dynamic range becomes an issue. To help with this issue, specific dyes have been developed.

What are Nucleic Acid binding dyes?

This type of dye has been developed to fluoresce when they are bound to double-stranded nucleic acids, and they can be excited by 488 or 561 nm lasers. After staining with antibodies, you can directly add them to the samples.

 

 

After a short incubation, you can clearly distinguish the dead cells and remove them, leaving only the unstained live ones.

What are protein binding dyes?

These dyes are another option for removing dead cells from a sample. As the name suggests, they bind to proteins instead of DNA. This type of dye can bind to both live and dead cells, but dead cells can acquire a greater amount of it, because their membrane has been compromised. Same as the DNA dyes, you can use gating on the less stained population to exclude the dead cells.