posted on 2019-11-18, 17:03authored bySergio Ayala-Mar, Victor H. Perez-Gonzalez, Marco A. Mata-Gómez, Roberto C. Gallo-Villanueva, José González-Valdez
Exosomes are a specific subpopulation of extracellular
vesicles
that have gained interest because of their many potential biomedical
applications. However, exosome isolation and characterization are
the first steps toward designing novel applications. This work presents
a direct current–insulator-based dielectrophoretic (DC-iDEP)
approach to simultaneously capture and separate exosomes by size.
To do so, a microdevice consisting of a channel with two electrically
insulating post sections was designed. Each section was tailored to
generate different nonuniform spatial distributions of the electric
field and, therefore, different dielectrophoretic forces acting on
exosomes suspended in solution. Side channels were placed adjacent
to each section to allow sample recovery. By applying an electric
potential difference of 2000 V across the length of the main channel,
dielectrophoretic size-based separation of exosomes was observed in
the device. Analysis of particle size in each recovered fraction served
to assess exosome separation efficiency. These findings show that
iDEP can represent a first step toward designing a high-throughput,
fast, and robust microdevice capable of capturing and discriminating
different subpopulations of exosomes based on their size.