posted on 2023-04-05, 17:34authored bySeunghee Han, Yullim Lee, Jihan Kim, Soo-Yeon Cho
Label-free single-cell analytics have been developed
for understanding
the collective immune response mechanism of immune cells. However,
it remains difficult to analyze the physicochemical properties of
a single cell in high spatiotemporal resolution for an immune cell
having dynamic morphological changes and significant molecular heterogeneities.
It is deemed due to the absence of a sensitive molecular sensing construct
and single-cell imaging analytic program. In this study, we developed
a deep learning integrated nanosensor chemical cytometry (DI-NCC)
platform, which combines a fluorescent nanosensor array in microfluidics
and a deep learning model for cell feature analysis. The DI-NCC platform
possesses the capability to collect rich, multivariate data sets for
each individual immune cell (e.g., macrophage) within the population.
We obtained LPS+ (n = 25) and LPS– (n = 61) near-infrared images and analyzed 250 cells/mm2 in 1 μm spatial resolution and 0 to 1.0 confidence
level even with overlapped or adhered cell configurations. This enables
automatic quantification of the activation and nonactivation levels
of a single macrophage upon instantaneous immune stimulations. Furthermore,
we support the activation level quantified by deep learning with heterogeneities
analysis of both biophysical (cell size) and biochemical (nitric oxide
efflux) properties. The DI-NCC platform can be promising for activation
profiling of dynamic heterogeneity variations of cell populations.