Due
to the substantial heterogeneity among extracellular
vesicle
(EV) subpopulations, single-EV analysis has the potential to elucidate
the mechanisms behind EV biogenesis and shed light on the myriad functions,
leading to the development of novel diagnostics and therapeutics.
While many studies have been devoted to reveal between-EV variations
in surface proteins and RNAs, DNA cargos (EV-DNA) have received little
attention. Here, we report a hydrogel-based droplet digital multiple
displacement amplification approach for the comprehensive analysis
of EV-DNA at the single-EV level. Single EVs are dispersed in thousands
of hydrogel droplets and lysed for DNA amplification and identification.
The droplet microfluidics strategy empowers the assay with single-molecule
sensitivity and capability for absolute quantification of DNA-containing
EVs. In particular, our findings indicate that 5โ40% EVs are
associated with DNA, depending on the cell of origin. Large EVs exhibit
a higher proportion of DNA-containing EVs and a more substantial presence
of intraluminal DNA, compared to small EVs. These DNA-containing EVs
carry multiple DNA fragments on average. Furthermore, both double-stranded
DNA and single-stranded DNA were able to be detected at the single-EV
level. Utilizing this method, the abundance, distribution, and biophysical
properties of EV-DNA in various EV populations are evaluated. The
DNA level within EVs provides insight into the status of the originating
cells and offers valuable information on the outcomes of anticancer
treatments. The utilization of single-EV analysis for EV-DNA holds
significant promise for early cancer detection and treatment response
monitoring