Despite regulation of the reactive oxygen species (ROS) level is an intelligent strategy for cancer therapy, the therapeutic effects of ROS-mediated therapy (including photodynamic therapy (PDT) and chemodynamic therapy (CDT)) are limited by oxygen reliance, inherent flaws of traditional photosensitizers, and strict reaction conditions of effective Fenton reaction. Herein, we reported biocompatible copper ferrite nanospheres (CFNs) with enhanced ROS production under irradiation with a 650 nm laser through direct electron transfer and photoenhanced Fenton reaction and high photothermal conversion efficiency upon exposure to an 808 nm laser, exhibiting a considerable improved synergistic treatment effect. Importantly, by exploiting the properties of O generation and glutathione (GSH) depletion of CFNs, CFNs relieve the hypoxia and antioxidant capability of the tumor, achieving photoenhanced CDT and improved PDT. The high relaxivity of 468.06 mM s enables CFNs to act as an outstanding contrast agent for MRI in vitro and in vivo. These findings certify the potential of such "all in one" nanotheranostic agent integrated PDT, photoenhanced CDT, photothermal therapy (PTT), and MRI imaging capabilities along with modulating the tumor microenvironment function in theranostics of cancer.
The generation of singlet oxygen ( 1 O 2 )d uring photodynamic therapyi sl imited by the precise cooperation of light, photosensitizer,a nd oxygen, and the therapeutic efficiency is restricted by the elevated glutathione (GSH) levels in cancer cells.H erein, we report that an ultrathin twodimensional metal-organic framework of Cu-TCPP nanosheets (TCPP = tetrakis(4-carboxyphenyl)porphyrin) can selectively generate 1 O 2 in at umor microenvironment. This process is based on the peroxidation of the TCPP ligand by acidic H 2 O 2 followed by reduction to peroxylr adicals under the action of the peroxidase-like nanosheets and Cu 2+ ,and their spontaneous recombination reaction by the Russell mechanism. In addition, the nanosheets can also deplete GSH. Consequently,the Cu-TCPP nanosheets can selectively destroy tumor cells with high efficiency,constituting an attractive way to overcome current limitations of photodynamic therapy.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.
Integration of multiple therapeutic/diagnostic modalities into a single system holds great promise to improve theranostic efficiency for tumors, but still remains a technical challenge. Herein, we report a new multimodal theranostic nanoconstruct based on Fe-doped polydiaminopyridine nanofusiforms, built easily and on a large scale, which can dual-regulate intracellular oxygen and glutathione levels, transport iron ions, and simultaneously be used for thermal imaging and magnetic resonance imaging. Co-loading of dihydroartemisinin and methylene blue generates a superior multifunctional theranostic agent with enhanced photochemotherapy efficiency and biodegradability, leading to almost complete destruction of tumors with near-infrared light irradiation. This represents an attractive route to develop multimodal anticancer theranostics.
Fe‐based Fenton agents can generate highly reactive and toxic hydroxyl radicals (·OH) in the tumor microenvironment (TME) for chemodynamic therapy (CDT) with high specificity. However, the strict condition (lower pH environment: 3–4) of the highly efficient Fenton reaction limits its practical application in the clinic. Development of new CDT agents more suitable for TME is significant and challenging. A highly efficient Cu(I)‐based CDT agent, copper(I) phosphide nanocrystals (CP NCs), which is more adaptable to the pH value of TME than Fe‐based agents, thereby producing more ·OH to trigger the apoptosis of cancer cells, is prepared. Moreover, the excess glutathione (GSH) in TME can reduce the Cu(II) produced by a Fenton‐like reaction to Cu(I), further increasing the generation rate of ·OH and relieving tumor antioxidant ability. Furthermore, owing to their strong absorption in the NIR II region, CP NCs exhibit an excellent photothermal conversion effect, which can further improve the Fenton reaction. What is more, CP NCs can act as in situ self‐generation magnetic resonance imaging (MRI) agents owing to the generation of paramagnetic Cu(II) in response to excess H2O2 in the TME. These properties may open up the exploration of copper‐based materials in clinical application of self‐generation imaging‐guided synergetic treatment.
Intrinsically integrating precise diagnosis, effective therapy, and self-anti-inflammatory action into a single nanoparticle is attractive for tumor treatment and future clinical application, but still remains a great challenge. In this study, bovine serum albumin-iridium oxide nanoparticles (BSA-IrO NPs) with extraordinary photothermal conversion efficiency, good photocatalytic activity, and a high X-ray absorption coefficient were prepared through one-step biomineralization. The nanoparticles allow tumor phototherapy and simultaneous photoacoustic/thermal imaging and computed tomography. More importantly, BSA-IrO NPs can also act as a catalase to protect normal cells against H O -induced reactive oxygen pressure and inflammation while significantly enhancing photoacoustic imaging through microbubble-based inertial cavitation. These remarkable features may open up the exploration iridium-based nanomaterials in theranostics.
Although
more attention has been attracted to the therapy based
on reactive oxygen species (ROS) for tumor therapy in recent years,
such as photodynamic therapy and chemodynamic therapy, the limited
ROS production rate leads to their poor treatment effect owing to
the relatively low content of O2 and H2O2 in tumor microenvironments, confined light penetration depth,
strict Fenton reaction conditions (pH 3–4), and so on. Therefore,
it is urgent to explore the new agents with highly efficient ROS generation
capacity. Herein, we first prepared phospholipid coated Na2S2O8 nanoparticles (PNSO NPs) as new ROS generation
agents for in situ generating Na+ and S2O8
2– through gradual degradation, which can
then be changed to toxic •SO4
– (a novel reported ROS) and •OH regardless of the
amount of H2O2 and pH value in the tumor microenvironment
(TME). As the generation of a large amount of Na+, PNSO
NPs can bypass the ion transport rules of cells through endocytosis
to deliver large amounts of Na+ into the cells, resulting
in a surge of osmolarity and rapid cell rupture and lysis. Osmotic
pressure induced by PNSO NPs will further lead to an unusual manner
of cell death: caspase-1-related pyroptosis. Moreover, all of above
effects will cause high immunogenic cell death, regulate the immunosuppressed
TME, and then activate systemic antitumor immune responses to combat
tumor metastasis and recurrence. We believe PNSO NPs will be new and
potential ROS generation agents, and this work will broaden the thinking
of the exploring of new antitumor nanodrugs.
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