Photodynamical therapy (PDT), as an emerging treatment modality, which takes advantage of reactive oxygen species (ROS) initiated by light illumination to ablate tumor, has suffered from the limited treatment depth,...
Photodynamic therapy (PDT) takes advantage of reactive oxygen species (ROS) to trigger the apoptosis for cancer therapy. Given that cell apoptosis is a form of programmed cell death involved with multiple suborganelles and cancer cells are more sensitive to ROS than normal cells, early confirmation of the apoptosis induced by ROS would effectively avoid overtreatment. Herein, we highlight an aggregation-induced emission (AIE)-based theranostic agent (TPA3) to in situ dynamically track mitophagy prior to late apoptosis. TPA3 showed high specificity to autophagy vacuoles (AVs), of which appearance is the signature event of mitophagy during early apoptosis and delivered photocytotoxicity to cancer cells and skin cancer tumors in nude mice under irradiation of white light. Furthermore, in situ monitoring of the dynamical mitophagy process involved with mitochondria, AVs, and lysosomes was performed for the first time under confocal microscopy, providing a real-time self-monitoring system for assessing the curative effect prior to late apoptosis. This fluorescence imaging guided PDT witness great advances for applying in the clinical application.
Considering the multiple biological barriers before the entry of photosensitizers (PSs) into cytoplasm, it is of paramount importance to track PSs to elucidate their behaviors and distributions to guide the photodynamic therapy (PDT). Also, the developed PSs suffer from strong oxygen dependency. However, reports on such ideal theranostic platforms are rare. Herein, we developed a theranostic platform (CMTP-2) based on the coumarin-based D-π-A system, which, for the first time, can reveal the holistic intracellular delivery pathway and near-infrared (NIR)-activated mitophagy to guide synergistic type-I PDT and photothermal therapy. The dynamic endo-lysosomal escape of CMTP-2 was monitored, as well as its changeable distributions in endosomes, lysosomes, and mitochondria, demonstrating the preferential accumulation in mitochondria at the end. Upon NIR-I irradiation, CMTP-2 generated toxic radicals and heat, triggering the execution of mitophagy and apoptosis. In vivo experiments on mice indicated that CMTP-2 under 808 nm irradiation realized complete cancer ablation, showing great potential for advancements in synergistic phototherapy.
Exploiting two-dimensional nanomaterials as photo-based theranostic agent has witnessed great promise in highly effective ablation of deep-tissue buried tumors. However, it’s still limited by their poor absorption in the second...
Photodynamic therapy (PDT) with organic photosensitizers generally goes through the oxygen‐dependent process, generating singlet oxygen and/or superoxide anion. However, the generation of reactive oxygen species is often suppressed as a result of hypoxia, one of the common features in tumors, therefore limiting the effectiveness of the tumor treatments. Consequently, it is urgent and significant to develop an oxygen‐independent hydroxyl radical photogenerator and unveil the mechanism. In this work, a hydroxyl radical (·OH) photogenerator originating from the electron transfer process is engineered. Detailed mechanism studies reveal that the optimized photosensitizer, WS2D, which contains a bithiophene unit, could both promote charge carrier generation and accelerate reaction efficiency, resulting in the efficient production of ·OH. In addition, WS2D nanoparticles are constructed to improve the polydispersity and stability in aqueous solution, which exhibit excellent biocompatibility and mitochondrial targeting. Bearing the above advantages, WS2D is employed in phototheranostics, which could release ·OH effectively and damage mitochondria precisely, achieving high PDT efficiency in vitro and in vivo. Overall, this work successfully provides valuable insights into the structural design of a hydroxyl radicals (·OH) photogenerator with great practical perspectives.
Cell
viability is greatly affected by external stimulus eliciting
correlated dynamical physiological processes for cells to choose survival
or death. A few fluorescent probes have been designed to detect whether
the cell is in survival state or apoptotic state, but monitoring the
regulation process of the cell undergoing survival to death remains
a long-standing challenge. Herein, we highlight the in situ monitor
of mitochondria regulating the cell viability by the RNA-specific
fluorescent photosensitizer L. At normal conditions, L anchored mitochondria and interacted with mito-RNA to light
up the mitochondria with red fluorescence. With external light stimulus, L generated reactive oxide species (ROS) and cause damage
to mitochondria, which activated mitochondrial autophagy to prevent
death, during which the red fluorescence of L witnessed
dynamical distribution in accordance with the evolution of vacuole
structures containing damaged mitochondria into autophagosomes. However,
with ROS continuously increasing, the mitochondrial apoptosis was
eventually commenced and L with red fluorescent was gradually
accumulated in the nucleoli, indicating the programmed cell death.
This work demonstrated how the delicate balance between survival and
death are regulated by mitochondria.
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