Lysosome-targeted silicon quantum dots theranostics for simultaneous fluorescent imaging and photodynamic therapy

As an emerging treatment method, photodynamic therapy (PDT) has attracted considerable interest due to the characteristics of non-invasiveness, repeatable treatment, high spatiotemporal resolution and few side effects. However, the life span (<40 ns) and diffusion distance (<20 nm) of reactive oxygen species such as singlet oxygen (O-1(2)) in tumor cells are extremely short, which has seriously limited therapeutic efficacy of PDT. The enrichment site of photosensitizers in cancer cells is usually the first site of PDT action, which will not only affect the biological signaling pathway of cancer cell death, but also is closely related to the final therapeutic effect. Therefore, the design and preparation of photosensitizers targeting specific subcellular organelles can directly break the biological function of the organelle and trigger the corresponding cell death signaling pathway, which can significantly improve the efficacy of PDT. Herein, a lysosome-targeted silicon quantum dots (L-Si QDs) was first made by diethylene glycol-mediated synthetic route as a multicolor fluorescent imaging reagents and a new photosensitizer. The as-prepared L-Si QDs exhibit bright fluorescence with excellent pH stability and time stability, excitation-dependent emission, and good biocompatibility. Furthermore, the results of cell experiments showed that L-Si QDs was accumulated in lysosomes after being taken up by cancer cells, and can efficiently produce O-1(2) upon 635 nm laser irradiation, which can damage lysosomes, up-regulate cleavage caspase-3, increase Bax release, down-regulate Bcl-2 and induce cell apoptosis finally. This study significantly broadens the biomedical applications of silicon quantum dots and provides excellent nanomaterials candidates for tumor phototherapy.

Automated summary

Photodynamic therapy (PDT) is an emerging treatment method that has attracted interest due to its non-invasiveness, repeatable treatment, high spatiotemporal resolution, and few side effects. However, the short lifespan and diffusion distance of reactive oxygen species in tumor cells seriously limit the therapeutic efficacy of PDT. Therefore, the design and preparation of photosensitizers targeting specific subcellular organelles can significantly improve the efficacy of PDT.