Breaking the diffraction barrier in fluorescence microscopy at low light intensities by using reversibly photoswitchable proteins

Abstract: Fluorescence microscopy is indispensable in many areas of science, but until recently, diffraction has limited the resolution of its lens-based variant. The diffraction barrier has been broken by a saturated depletion of the marker's fluorescent state by stimulated emission, but this approach requires picosecond laser pulses of GW͞cm 2 intensity. Here, we demonstrate the surpassing of the diffraction barrier in fluorescence microscopy with illumination intensities that are eight orders of magnitude smaller. Th… Show more

“…Also, the extension to other applications such as multicolour detection is feasible by generating other novel photoswitchable markers with different emission wavelengths that can be switched on through a CW-2PA process. Our results underscore once more the power of switchable photochromic molecules [10,34] for realizing far-field optical microscopy with spatial resolution far below the Abbe barrier, and promise new exciting insights into many scientific fields including live-cell imaging.…”

Fluorescence Nanoscopy with Optical Sectioning by Two‐Photon Induced Molecular Switching using Continuous‐Wave Lasers

“…Also, the extension to other applications such as multicolour detection is feasible by generating other novel photoswitchable markers with different emission wavelengths that can be switched on through a CW-2PA process. Our results underscore once more the power of switchable photochromic molecules [10,34] for realizing far-field optical microscopy with spatial resolution far below the Abbe barrier, and promise new exciting insights into many scientific fields including live-cell imaging.…”

Fluorescence Nanoscopy with Optical Sectioning by Two‐Photon Induced Molecular Switching using Continuous‐Wave Lasers

“…These concerns are compounded by the field’s heavy reliance on puncta as primary evidence for in vivo phase separation. Super-resolution techniques, including our findings, reveal that presumed “condensates” exhibit more defined architectures or stable interactions than predicted by liquid-phase separation (LLPS) models [3, 14]. Critically, diffraction-limited microscopy cannot distinguish between true liquid condensates, stable protein-DNA complexes, or imaging artifacts -all of which may appear as similar punctate structures.…”

Super-resolution microscopy reveals distinct epigenetic states regulated by estrogen receptor activity

“…3C and 3F). The average fluorescence ratio of the HSPCs after photoconversion was 12.1 times higher than the ratio prior to photoconversion (R b = 0.5360.21, R a = 6.4264.24, p = 8.36610 24 ). Similarly, the average fluorescence ratio of the T cells after photoconversion was 17.6 times higher than the ratio prior to conversion (R b = 0.3660.12, R a = 6.3562.54, p = 1.15610 233 ), suggesting that good distinction between photoconverted and non-photoconverted cells can be achieved.…”

Correction: Tracking Single Cells in Live Animals Using a Photoconvertible Near-Infrared Cell Membrane Label