posted on 2017-04-17, 00:00authored byZiye Dong, Caroline C. Ahrens, Dan Yu, Zhenya Ding, HyunTaek Lim, Wei Li
Established cell
isolation and purification techniques such as
fluorescence-activated cell sorting (FACS), isolation through magnetic
micro/nanoparticles, and recovery via microfluidic devices have limited
application as disposable technologies appropriate for point-of-care
use in remote areas where lab equipment as well as electrical, magnetic,
and optical sources are restricted. We report a simple yet effective
method for cell isolation and recovery that requires neither specialized
lab equipment nor any form of power source. Specifically, self-floating
hollow glass microspheres were coated with an enzymatically degradable
nanolayered film and conjugated with antibodies to allow both fast
capture and release of subpopulations of cells from a cell mixture.
Targeted cells were captured by the microspheres and allowed to float
to the top of the hosting liquid, thereby isolating targeted cells.
To minimize nonspecific adhesion of untargeted cells and to enhance
the purity of the isolated cell population, an antifouling polymer
brush layer was grafted onto the nanolayered film. Using the EpCAM-expressing
cancer cell line PC-3 in blood as a model system, we have demonstrated
the isolation and recovery of cancer cells without compromising cell
viability or proliferative potential. The whole process takes less
than 1 h. To support the rational extension of this platform technology,
we introduce extensive characterization of the critical design parameters:
film formation and degradation, grafting with a poly(ethylene glycol)
(PEG) sheath, and introducing functional antibodies. Our approach
is expected to overcome practical hurdles and provide viable targeted
cells for downstream analyses in resource-limited settings.