Machine learning-based clustering of nanosized fluorescent extracellular vesicles

Kuypers, Sören; Smisdom, Nick; Pintelon, Isabel; Timmermans, Jean-Pierre; Ameloot, Marcel; Michiels, Luc; Hendrix, Jelle; Hosseinkhani, Baharak

doi:10.1101/2020.11.27.374728

Author:

Kuypers, Sören

Smisdom, Nick ; Pintelon, Isabel ; Timmermans, Jean-Pierre ; Ameloot, Marcel ; Michiels, Luc ; Hendrix, Jelle ; Hosseinkhani, Baharak

Abstract:

ABSTRACT

Extracellular vesicles (EV) are biological nanoparticles that play an important role in cell-to-cell communication. The phenotypic profile of EV populations is a promising reporter of disease, with direct clinical diagnostic relevance. Yet, robust methods for quantifying the biomarker content of EV have been critically lacking, and require a single-particle approach due to their inherent heterogeneous nature. Here, we used multicolor single-molecule burst analysis microscopy to detect multiple biomarkers present on single EV. We classified the recorded signals and applied the machine learning-based t-distributed stochastic neighbor embedding algorithm to cluster the resulting multidimensional data. As a proof of principle, we applied the method to assess both the purity and the inflammatory status of EV, and compared cell culture and plasma-derived EV isolated via different purification methods. We then applied this methodology to identify intercellular adhesion molecule-1 (ICAM-1) specific EV subgroups released by inflamed endothelial cells, and to prove that apolipoprotein-a1 is an excellent marker to identify the typical lipoprotein contamination in plasma. Our methodology can be widely applied on standard confocal microscopes, thereby allowing both standardized quality assessment of patient plasma EV preparations, and diagnostic profiling of multiple EV biomarkers in health and disease.