Home Molecular Biology Heterogeneous Autofluorescence
Steps
  1. 1 Identify heterogeneous autofluorescence signatures 00:01
  2. 2 Discover distinct autofluorescent populations 01:36
  3. 3 Distinguish spectral signatures by gating 04:06
  4. 4 Export brightest events from each population 07:43
  5. 5 Designate autofluorescence tags in software 09:19
  6. 6 Add tags to experiment and set controls 11:34
  7. 7 Run unmixing wizard and verify results 14:03
Molecular Biology Current Protocols

Heterogeneous Autofluorescence

Protocol
Difficulty
intermediate

Steps

1
Identify heterogeneous autofluorescence signatures

Review the unstained sample using a spectral plot to identify that multiple cell types in the tissue sample produce different autofluorescence signatures rather than a single clean signature.

▶ 00:01
2
Discover distinct autofluorescent populations

Open a raw n-by-n permutation worksheet to compare all fluorescent channels. Create a spectral plot of UV and YG1 channels to identify regions of heterogeneity and locate distinct cell populations with different spectral characteristics.

▶ 01:36
3
Distinguish spectral signatures by gating

Gate around the identified populations based on their positions in the UV/YG1 plot to isolate different spectral signatures. Create spectral plots for each gated population alongside scatter plots to confirm they represent distinct cell types with different autofluorescence profiles.

▶ 04:06
4
Export brightest events from each population

For each distinguished spectral signature, identify the peak channel and gate on the brightest events. Export at least 300-500 events from each population as FCS files for use in unmixing, including the dim autofluorescent negative population.

▶ 07:43
5
Designate autofluorescence tags in software

Create a new autofluorescent tags group in the spectral flow software library. Add entries for each distinguished autofluorescent population with their respective detector and peak emission wavelength information.

▶ 09:19
6
Add tags to experiment and set controls

Add the newly created autofluorescent tags to the experiment as reference controls. Import the exported FCS files for each population and assign the dim autofluorescent population as the negative control for spillover calculation.

▶ 11:34
7
Run unmixing wizard and verify results

Run the unmixing wizard through all controls, setting gates for the cell populations. Check the similarity matrix to confirm that autofluorescent signatures have similarity indices below the 0.98 threshold, indicating they are distinct spectral signatures.

▶ 14:03

🚨 Failure Case Library (2) + Submit your own case

severe
Red Blood Cell and Heme-Related Autofluorescence
Strong autofluorescence across multiple channels in blood-rich tissues such as spleen, liver, brain, bone marrow, and vascularized tumors. Heme and porphyrins dominate signal especially when tissue is not thoroughly perfused.
💡 4 · ✓ 5
severe
Age-Related Lipofuscin Accumulation
Exceptionally broad excitation and emission spectra affecting multiple channels in aged tissues such as brain, heart, skeletal muscle, and retina. Age-dependent lysosomal pigment cannot be confined to single channel.
💡 4 · ✓ 5
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