The
analysis of biomolecules in a 3D cell model is crucial for
the collection of spatial information close to the actual organ. In
this work, a highly sensitive platinized open carbon nanocavity electrode
is fabricated to investigate reactive oxygen species (ROS) in three
regions (proliferating zone, quiescent zone, and necrotic core) of
a 3D CT26 cell model. The presence of a nanocavity permits more frequent
collisions of ROS on the Pt surface, accelerating electron transfer,
and thus pushes the detection limit down to 1 nM. This improved detection
sensitivity guarantees the spatial investigation of the ROS distribution
in a 3D cell sphere, including a high concentration in the outer proliferating
layer even without any external stimulus, a low concentration in the
quiescent layer, and almost no ROS at the center. The observation
of ROS in the cell sphere without the stimulus reveals the presence
of oxygen stress in the 3D cancer cell model, which is obviously different
from the previous observation in living cultured 2D cells. This discovery
provides direct evidence about the discrepancy about the metabolism
in 2D and 3D cells, which could also direct a new study in cell electroanalysis
to achieve more actual molecular information in life study.