Abstract
Photobleaching is a general hurdle of fluorescence-based techniques especially in high-resolution microscopy that relies on prolonged and complex illumination. Strategies to reduce photobleaching require chemical modifications of the cell medium, which often compromise physiological cellular conditions. Here, we outline an all-optical strategy to minimize photobleaching in reversibly switching fluorescent proteins (RSFPs), a class of probes used in super-resolution and protein-multiplexing imaging techniques. By identifying the photobleaching pathways, we develop imaging schemes to increase the number of on-off photoswitching cycles, either modulating the on-switching light or co-irradiating the RSFPs with light at longer wavelengths with respect to fluorescence excitation. We apply the optimized imaging scheme to achieve imaging multiplexing at high-spatiotemporal resolutions and to record longer time-lapse imaging of sub-cellular structures with both confocal microscopy and parallelized RESOLFT nanoscopy.