Litcius/Paper detail

Heat denaturation enables multicolor X10-STED microscopy

Kim Ann Saal, Ali Shaib, Nikolaos Mougios, Dagmar Crzan, Felipe Opazo, Silvio O. Rizzoli

2023Scientific Reports23 citationsDOIOpen Access PDF

Abstract

Expansion microscopy (ExM) improves imaging quality by physically enlarging the biological specimens. In principle, combining a large expansion factor with optical super-resolution should provide extremely high imaging precision. However, large expansion factors imply that the expanded specimens are dim and are therefore poorly suited for optical super-resolution. To solve this problem, we present a protocol that ensures the expansion of the samples up to 10-fold, in a single expansion step, through high-temperature homogenization (X10ht). The resulting gels exhibit a higher fluorescence intensity than gels homogenized using enzymatic digestion (based on proteinase K). This enables the sample analysis by multicolor stimulated emission depletion (STED) microscopy, for a final resolution of 6-8 nm in neuronal cell cultures or isolated vesicles. X10ht also enables the expansion of 100-200 µm thick brain samples, up to 6-fold. The better epitope preservation also enables the use of nanobodies as labeling probes and the implementation of post-expansion signal amplification. We conclude that X10ht is a promising tool for nanoscale resolution in biological samples.

Topics & Concepts

STED microscopyMicroscopyHomogenization (climate)Resolution (logic)Thermal expansionSuperresolutionMaterials scienceStimulated emissionNanoscopic scaleOptical microscopeBiophysicsChemistryOpticsNanotechnologyBiologyPhysicsComputer scienceScanning electron microscopeLaserArtificial intelligenceImage (mathematics)MetallurgyEcologyBiodiversityAdvanced Fluorescence Microscopy TechniquesAdvanced Electron Microscopy Techniques and ApplicationsMonoclonal and Polyclonal Antibodies Research