Specialized Cell-Free DNA Blood Collection Tubes Can Be Repurposed for Extracellular Vesicle Isolation: A Pilot Study.

Liquid biopsies offer a minimally invasive approach to patient disease diagnosis and monitoring. However, these are highly affected by preprocessing variables with many protocols designed for downstream analysis of a single molecular biomarker. Here we investigate whether specialized blood tubes could be repurposed for the analysis of an increasingly valuable biomarker, extracellular vesicles (EVs). Blood was collected from three donors into K3-EDTA, Roche, or Streck cell-free DNA (cfDNA) collection tubes and processed using sequential centrifugation either immediately or after storage for 3 days. MicroEV were collected from platelet-poor plasma by 10,000 centrifugation and NanoEVs isolated using size exclusion chromatography. Particle size and counts were assessed by Nanoparticle Tracking Analysis, protein quantitation by bicinchoninic acid assay (BCA) assay, and dot blotting for blood cell surface proteins. MicroEVs and NanoEVs could be isolated from plasma collected using all three tube types. Major variations were seen with delayed time to processing. Both MicroEV particle number and protein content increased with the processing delay. The NanoEV number did not change with the time-delay but their protein quantity increased. EV-associated proteins predominantly arose from platelets (CD61) and erythrocytes (CD235a). However, leukocyte marker CD45 was only increased in NanoEVs from ethylenediaminetetraacetic acid (EDTA) tubes, suggestive of stabilization of nucleated cells by the specialized blood tubes. Epithelial cell surface marker EpCAM, often used as a marker of cancer, remained the same across conditions in both MicroEV and NanoEV preparations indicating that these EVs were stable with time. Specialized cfDNA collection tubes can be repurposed for MicroEV and NanoEV analysis; however, simple counting or using protein quantity as a surrogate of EV number may be confounded by preanalytical processing. The EVs would be suitable for disease selective EV subtype analysis if the molecular target of interest is not present in blood cells.