FluoEM, virtual labeling of axons in three-dimensional electron microscopy data 
for long-range connectomics

Drawitsch, Florian; Karimi, Ali; Boergens, Kevin M.; Helmstaedter, Moritz

doi:10.7554/eLife.38976

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FluoEM, virtual labeling of axons in three-dimensional electron microscopy data for long-range connectomics

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Drawitsch, Florian
Connectomics Department, Max Planck Institute for Brain Research, Max Planck Society;
Donders Institute, Faculty of Science, Radbout University;

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Karimi, Ali
Connectomics Department, Max Planck Institute for Brain Research, Max Planck Society;

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Boergens, Kevin M.
Connectomics Department, Max Planck Institute for Brain Research, Max Planck Society;

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Helmstaedter, Moritz
Connectomics Department, Max Planck Institute for Brain Research, Max Planck Society;
Donders Institute, Faculty of Science, Radbout University;

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https://pubmed.ncbi.nlm.nih.gov/30106377/
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Citation

Drawitsch, F., Karimi, A., Boergens, K. M., & Helmstaedter, M. (2018). FluoEM, virtual labeling of axons in three-dimensional electron microscopy data for long-range connectomics. eLife, 14(7): e38976. doi:10.7554/eLife.38976.

Cite as: https://hdl.handle.net/21.11116/0000-0002-7430-5

Abstract

The labeling and identification of long-range axonal inputs from multiple sources within densely reconstructed electron microscopy (EM) datasets from mammalian brains has been notoriously difficult because of the limited color label space of EM. Here, we report FluoEM for the identification of multi-color fluorescently labeled axons in dense EM data without the need for artificial fiducial marks or chemical label conversion. The approach is based on correlated tissue imaging and computational matching of neurite reconstructions, amounting to a virtual color labeling of axons in dense EM circuit data. We show that the identificatin of fluorescent light-microscipally (LM) imaged axons in 3D EM data from mouse cortex is faithfully possible as soon as the EM dataset is about 49-50 micrometer in extent, relying on the unique trajectories of axons in dense mammalian neuropil. The method is exemplified for the identification of long-distance axonal input into layer 1 of the mouse cerebral cortex.