Authors
Basak S, Chi-Vu K, Mougios N, Oleksiievets N, Pollack Y, Brandenburg S, Opazo F, Lehnart SE, Enderlein J, Tsukanov R
Journal
BioRxiv
Citation
bioRxiv 2025.10.07.680900.
Abstract
DNA-based Point Accumulation for Imaging in Nanoscale Topography (DNA-PAINT) is a powerful variant of single-molecule localization microscopy (SMLM) that overcomes the limitations of photobleaching, offers flexible fluorophore selection, and enables fine control of imaging parameters through tunable on- and off-binding kinetics. Its most distinctive feature is the capacity for multiplexing, which is achieved through a process known as Exchange-PAINT. This technique involves assigning orthogonal DNA strands to different targets within a sample and then sequentially adding and removing complementary imager strands that are specific to only one target at a time. However, manual Exchange-PAINT workflows are often inefficient, prone to drift and variability, and lack reproducibility.
Here, we introduce a custom compressed-air-driven microfluidics system specifically designed for multiplexed SMLM. Featuring a stackable and modular design that is, in principle, not limited by the number of channels, the system ensures robust, reproducible, and material-efficient buffer exchange with minimal dead volume. It operates in both manual and automated modes and can be readily adapted to a wide range of commercial and custom microscopes, including wide-field, confocal, STED, and MINFLUX platforms.
We demonstrate robust 5-plex Exchange-PAINT imaging in cancerous U2OS cells and, importantly, we establish multiplexed nanoscale imaging in fragile primary cardiomyocytes. These applications highlight the unique power of our platform to extend super-resolution multiplexing into physiologically relevant systems, thereby opening new avenues for biomedical research.
