Fluorescence Lifetime Imaging Microscopy (FLIM) visualizes internalization and biological impact of nanoplastics in live intestinal organoids

Abstract The increasing micro- and nanoplastic (MNP) pollution poses significant risks to human and animal health, yet the mechanisms of their accumulation and effects on absorptive tissues such as the gastrointestinal tract remain poorly understood. Addressing these knowledge gaps requires tractable models coupled to dynamic live cell imaging methods, to enable multi-parameter analysis at single cell resolution. Here we report a new method combining adult stem cell-derived small intestinal organoid cultures with multi-parameter live Fluorescence Lifetime Imaging Microscopy (FLIM) to study MNP interactions with gut epithelium. To facilitate this, we optimized live imaging of porcine and mouse small intestinal organoids with an ‘apical-out’ topology. Subsequently, we produced a set of pristine MNPs based on PMMA and PS (<200 nm, doped with deep-red fluorescent dye) exhibiting different surface charges, and evaluated their interaction with organoids displaying controlled epithelial polarity. We found that nanoparticles differently interacted with apical and basal membranes of the organoids and even showed a species-specific pattern of cellular uptake. Using a phasor-FLIM approach, we demonstrate better sensitivity of FLIM over conventional intensity-based microscopy. The ‘fluorescence lifetime barcoding’ enabled distinguishing different types of MNP and their interaction sites within organoids. Finally, we studied short (1 day)- and long (3 days)-term exposure effects of PMMA and PS-based MNPs on mitochondrial function, total energy budget and epithelial inflammation and found that even pristine MNPs could disrupt chemokine production and mitochondrial membrane potential in intestinal epithelial cells. The presented FLIM approach will advance the study of MNP toxicity, their biological impacts on gastrointestinal tissue and help tracing other types of fluorescent nanoparticles in live organoid and 3D ex vivo systems.