The
deficiency of reactive oxygen species (ROS) is the main reason for
the current poor efficiency of tumor photodynamic therapy (PDT). To
solve this problem, a simple light-triggered core–satellite
nanoplatform (UPSD@Au) has been developed by loading Au nanoparticles
on the surface of mesoporous silica-coated upconversion nanoparticles.
Small molecules DC50 (C17H14BrF2N3OS) and photosensitizer (silicon phthalocyanine dihydroxide,
SPCD) were loaded into the silica shell to improve ROS production.
Meanwhile, PDT can be triggered through facile near-infrared laser
irradiation given the occurrence of a moderate photothermal transfer
process between upconversion nanoparticles and Au. The reasonable
increment in temperature induced by Au resulted in the timely release
of DC50. The inhibition of copper transfer by DC50 results in reduced
ROS scavenging and thus improves light-triggered ROS accumulation.
Notably, the expression levels of the human copper-trafficking proteins
Atox1 and CCS in cancerous cells exceed those in normal cells, and
thus enhanced ROS accumulation effect was achieved in cancerous cells.
In vitro and in vivo results demonstrate that the synergism between
DC50 and SPCD coloaded in the UPSD@Au nanoplatform increases the efficiency
of PDT. The UPSD@Au platform represents an efficient codelivery method
for hydrophobic small molecules and improves sensitization to specific
cancer therapy.