Characterizing the transient ultratrace light-independent
intracellular
singlet oxygen (1O2), which plays a vital role
in multiple biological processes in living organisms, brings about
tremendous help for understanding the nature of 1O2-mediated or related bioevents. Nevertheless, an approach
to detect the light-independent intracellular 1O2 is hard to find. Herein, we developed a chemiluminescent nanosensor
by compacting a great number of TPE-N(Ph)-DBT-PH molecules in one
nanostructure via autoaggregation. Taking advantage of the aggregation-induced
emission property, this TPE-N(Ph)-DBT-PH nanosensor is highly fluorescent
and promises a bright red-light CL and the convenience of mapping in vivo sensor distribution. Experiments demonstrate the
nanosensor’s unprecedented selectivity toward 1O2 against other reactive oxygen species. The 3.7 nmol L–1 limit of detection renders this nanosensor with the
best-known sensitivity of 1O2 chemical sensors.
Meanwhile, fluorescence confocal microscope imaging results suggest
that our nanosensor simultaneously targets mitochondria and lysosomes
in RAW 264.7 cells via the energy-dependent endocytosis pathway, thereby
implying an attractive potential for the detection of intracellular 1O2. Such a potential is demonstrated by detecting 1O2 in RAW 264.7 cells during a lipopolysaccharide
and phorbol myristate acetate stimulated respiration burst. This study
represents the first approach to detect light-independent intracellular 1O2 during cell bioregulation. Thus, our nanosensor
provides an effective tool for investigating the 1O2-related bioprocesses and pathological processes.
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