Photodynamic therapy (PDT) is often applied in a clinical
setting
to treat bladder cancer. However, current photosensitizers report
drawbacks such as low efficacy, low selectivity, and numerous side
effects, which have limited the clinical values of PDT for bladder
cancer. Previously, we developed the first bladder cancer-specific
aptamer that can selectively bind to and be internalized by bladder
tumor cells versus normal uroepithelium cells. Here, we use an aptamer-based
drug delivery system to deliver photosensitizer chlorine e6 (Ce6)
into bladder tumor cells. In addition to Ce6, we also incorporate
catalase into the drug complex to increase local oxygen levels in
the tumor tissue. Compared with free Ce6, an aptamer-guided DNA nanotrain
(NT) loaded with Ce6 and catalase (NT–Catalase–Ce6)
can specifically recognize bladder cancer cells, produce oxygen locally,
induce ROS in tumor cells, and cause mitochondrial apoptosis. In an
orthotopic mouse model of bladder cancer, the intravesical instillation
of NT–Catalase–Ce6 exhibits faster drug internalization
and a longer drug retention time in tumor tissue compared with that
in normal urothelium. Moreover, our modified PDT significantly inhibits
tumor growth with fewer side effects such as cystitis than free Ce6.
This aptamer-based photosensitizer delivery system can therefore improve
the selectivity and efficacy and reduce the side effects of PDT treatment
in mouse models of bladder cancer, bearing a great translational value
for bladder cancer intravesical therapy.