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Multielement Z-tag imaging by X-ray fluorescence microscopy for next-generation multiplex imaging

Merrick Strotton, Tsuyoshi Hosogane, Marco Di Michiel, Holger Moch, Zsuzsanna Varga, Bernd Bodenmiller

2023Nature Methods21 citationsDOIOpen Access PDF

Abstract

Rapid, highly multiplexed, nondestructive imaging that spans the molecular to the supra-cellular scale would be a powerful tool for tissue analysis. However, the physical constraints of established imaging methods limit the simultaneous improvement of these parameters. Whole-organism to atomic-level imaging is possible with tissue-penetrant, picometer-wavelength X-rays. To enable highly multiplexed X-ray imaging, we developed multielement Z-tag X-ray fluorescence (MEZ-XRF) that can operate at kHz speeds when combined with signal amplification by exchange reaction (SABER)-amplified Z-tag reagents. We demonstrated parallel imaging of 20 Z-tag or SABER Z-tag reagents at subcellular resolution in cell lines and multiple human tissues. We benchmarked MEZ-XRF against imaging mass cytometry and demonstrated the nondestructive multiscale repeat imaging capabilities of MEZ-XRF with rapid tissue overview scans, followed by slower, more sensitive imaging of low-abundance markers such as immune checkpoint proteins. The unique multiscale, nondestructive nature of MEZ-XRF, combined with SABER Z-tags for high sensitivity or enhanced speed, enables highly multiplexed bioimaging across biological scales.

Topics & Concepts

MultiplexMolecular imagingFluorescence-lifetime imaging microscopyMicroscopyHyperspectral imagingMultiplexingFluorescenceMaterials scienceSpectral imagingOpticsPhysicsComputer scienceBiologyBioinformaticsArtificial intelligenceIn vivoTelecommunicationsBiotechnologyAdvanced Fluorescence Microscopy TechniquesAdvanced Electron Microscopy Techniques and ApplicationsMedical Imaging Techniques and Applications
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