Phototherapies have many advantages for triple-negative breast cancer (TNBC) treatment. However, their effects are often limited by short blood circulation time, poor tumor selectivity and weak penetration of phototherapeutic agents, and tumor hypoxia. For overcoming these limitations, a versatile biomimetic system is developed based on red blood cells (RBCs). Photothermal agent new indocyanine green (IR820) is conjugated with the cell/tissue-penetrating TAT peptide and further efficiently encapsulated into the intact RBCs by crossing cell membranes to realize the long blood circulation. Meanwhile, cyclic RGD peptide (cRGD) is linked to the surfaces of RBCs through phospholipid insertion to obtain tumor vessel-targeting ability. Photosensitizer temoporfin (mTHPC) is next loaded into the membranes of RBCs by spontaneous transferring. The acquired biomimetic system (cRGD-RBC@mTHPC/TAT-IR820) exhibits potent photodynamic performance upon 652 nm laser irradiation with the facilitation of oxyhemoglobin, which could not only trigger TAT-IR820 release but also destroy tumor vessels. TAT-IR820 penetrates deeply into tumor tissue via the mediation of TAT peptide, exerting greatly promoted photothermal ablation against TNBC upon 808 nm laser irradiation. In situ generated tumor antigens further induce robust immune responses to suppress TNBC recurrence and metastasis. In summary, this study provides a versatile biomimetic system for comprehensive TNBC treatment via stepwise photodynamic and photothermal activations.
Radiotherapy (RT) is one of the main clinical therapeutic strategies against cancer. Currently, multiple radiosensitizers aimed at enhancing X-ray absorption in cancer tissues have been developed, while limitations still exist for their further applications, such as poor cellular uptake, hypoxia-induced radioresistance, and unavoidable damage to adjacent normal body tissues. In order to address these problems, a cell-penetrating TAT peptide (YGRKKRRQRRRC)-modified nanohybrid was constructed by doping high-Z element Au in hollow semiconductor Cu2−xSe nanoparticles for combined RT and photothermal therapy (PTT) against breast cancer. The obtained Cu2−xSe nanoparticles possessed excellent radiosensitizing properties based on their particular band structures, and high photothermal conversion efficiency beneficial for tumor ablation and promoting RT efficacy. Further doping high-Z element Au deposited more high-energy radiation for better radiosensitizing performance. Conjugation of TAT peptides outside the constructed Cu2−xSe/Au nanoparticles facilitated their cellular uptake, thus reducing overdosage-induced side effects. This prepared multifunctional nanohybrid showed powerful suppression effects towards breast cancer, both in vitro and in vivo via integrating enhanced cell penetration and uptake, and combined RT/PTT strategies.
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