Glutathione-depleting polyprodrug nanoparticle for enhanced photodynamic therapy and cascaded locoregional chemotherapy.

Nanomedicines that combine reactive oxygen species (ROS)-responsive polyprodrug and photodynamic therapy have shown great potential for improving treatment efficacy. However, the consumption of ROS by overexpressed glutathione in tumor cells is a major obstacle for achieving effective ROS amplification and prodrug activation. Herein, we report a polyprodrug-based nanoparticle that can realize ROS amplification and cascaded drug release. The nanoparticle can respond to the high level of hydrogen peroxide in tumor microenvironment, achieving self-destruction and release of quinone methide. The quinone methide depletes intracellular glutathione and thus decreases the antioxidant capacity of cancer cells. Under laser irradiation, a large amount of ROS will be generated to induce cell damage and prodrug activation. Therefore, the glutathione-depleting polyprodrug nanoparticles can efficiently inhibit tumor growth by enhanced photodynamic therapy and cascaded locoregional chemotherapy.

Glutathione-Responsive Polymersome with Continuous Glutathione Depletion for Enhanced Photodynamic Therapy and Hypoxia-Activated Chemotherapy.

The high glutathione (GSH) level of the tumor microenvironment severely affects the efficacy of photodynamic therapy (PDT). The current GSH depletion strategies have difficulty meeting the dual needs of security and efficiency. In this study, we report a photosensitizer Chlorin e6 (Ce6) and hypoxia-activated prodrug tirapazamine (TPZ) coloaded cross-linked multifunctional polymersome (TPZ/Ce6@SSPS) with GSH-triggered continuous GSH depletion for enhanced photodynamic therapy and hypoxia-activated chemotherapy. At tumor sites, the disulfide bonds of TPZ/Ce6@SSPS react with GSH to realize decross-linking for on-demand drug release. Meanwhile, the generated highly reactive quinone methide (QM) can further deplete GSH. This continuous GSH depletion will amplify tumor oxidative stress, enhancing the PDT effect of Ce6. Aggravated tumor hypoxia induced by PDT activates the prodrug TPZ, resulting in an enhanced combination of PDT and hypoxia-activated chemotherapy. Both in vitro and in vivo results demonstrate the efficient GSH depletion and potent antitumor activities by TPZ/Ce6@SSPS. This work provides a strategy for the design of a continuous GSH depletion platform, which holds great promise for enhanced combination tumor therapy.

Chemical Constituents from Mushroom Suillus luteus (Agaricomycetes) and Their Bioactivities.

Wild edible mushrooms are a huge source to discover bioactive natural products. In this work, one new polyprenylphenol derivative, termed 2-geranylgeranyl-1,4-benzenediol 1-O-acetate (1), together with eight known compounds (2-9) were isolated from wild edible mushroom Suillus luteus. The structure of new compound was elucidated by high-resolution electrospray ionization mass spectroscopy and nuclear magnetic resonance data. The structures of known compounds were elucidated by comparison of their nuclear magnetic resonance data with literature data. Compounds 1-7 exhibited significant 2,2-diphenyl-1-picrylhydrazyl free radical scavenging activity with IC50 values ranging from 1.55 ± 0.29 to 19.89 ± 2.28 µM. In addition, compounds 1-7 also showed tyrosinase inhibitory activity with IC50 values ranging from 21.97 ± 3.74 to 66.26 ± 6.85 µM.

Beyond Photo: Xdynamic Therapies in Fighting Cancer.

Reactive oxygen species (ROS)-related therapeutic approaches are developed as a promising modality for cancer treatment because the aberrant increase of intracellular ROS level can cause cell death due to nonspecific oxidation damage to key cellular biomolecules. However, the most widely considered strategy, photodynamic therapy (PDT), suffers from critical limitations such as limited tissue-penetration depth, high oxygen dependence, and phototoxicity. Non-photo-induced ROS generation strategies, which are defined as Xdynamic therapies (X = sono, radio, microwave, chemo, thermo, and electro), show good potential to overcome the drawbacks of PDT. Herein, recent advances in the development of Xdynamic therapies, including the design of systems, the working mechanisms, and examples of cancer therapy application, are introduced. Furthermore, the approaches to enhance treatment efficiency of Xdynamic therapy are highlighted. Finally, the perspectives and challenges of these strategies are also discussed.

Programmed Size-Changeable Nanotheranostic Agents for Enhanced Imaging-Guided Chemo/Photodynamic Combination Therapy and Fast Elimination.

An ideal nanotheranostic agent should be able to achieve efficient tumor accumulation, retention, and fast elimination after its theranostic functions exhausts. However, there is an irreconcilable contradiction on optimum sizes for effective tumor retention and fast elimination. Herein, a programmed size-changeable nanotheranostic agent based on polyprodrug-modified iron oxide nanoparticles (IONPs) and aggregation-induced emission photosensitizer is developed for enhanced magnetic resonance imaging (MRI)-guided chemo/photodynamic combination therapy. The nano-sized theranostic agents with an initial diameter of about 90 nm can accumulate in tumor tissue through passive targeting. In the acidic tumor microenvironment, large aggregates of IONPs are formed, realizing enhanced tumor retention and MR signal enhancement. Under the guidance of MRI, light irradiation is applied to the tumor site for triggering the generation of reactive oxygen species and drug release. Moreover, after chemo/photodynamic combination therapy, the large-sized aggregates are re-dispersed into small-sized IONPs for fast elimination, reducing the risk of toxicity caused by long-term retention. Therefore, this study provides a promising size-changeable strategy for the development of nanotheranostic agents.

Cascade Drug-Release Strategy for Enhanced Anticancer Therapy.

Chemotherapy serves as one of the most effective approaches in numerous tumor treatments but also suffers from the limitations of low bioavailability and adverse side effects due to premature drug leakage. Therefore, it is crucial to realize accurate on-demand drug release for promoting the application of chemotherapeutic agents. To achieve this, stimuli-responsive nanomedicines that can be activated by delicately designed cascade reactions have been developed in recent years. In general, the nanomedicines are triggered by an internal or external stimulus, generating an intermediate stimulus at tumor site, which can intensify the differences between tumor and normal tissues; the drug release process is then further activated by the intermediate stimulus. In this review, the latest progress made in cascade reactions-driven drug-release modes, based on the intermediate stimuli of heat, hypoxia, and reactive oxygen species, is systematically summarized. The perspectives and challenges of cascade strategy for drug delivery are also discussed.

CRISPR-dcas9 Optogenetic Nanosystem for the Blue Light-Mediated Treatment of Neovascular Lesions.

Vascular endothelial growth factor (VEGF) is the key regulator in neovascular lesions. The anti-VEGF injection is a major way to relieve retinal neovascularization and treat these diseases. However, current anti-VEGF therapeutics show significant drawbacks. The reason is the inability to effectively control its therapeutic effect. Therefore, how to controllably inhibit the VEGF target is a key point for preventing angiogenesis. Here, a CRISPR-dCas9 optogenetic nanosystem was designed for the precise regulation of pathologic neovascularization. This system is composed of a light-controlled regulatory component and transcription inhibition component. They work together to controllably and effectively inhibit the target gene's VEGF. The opto-CRISPR nanosystem achieved precise regulation according to individual differences, whereby the expression and interaction of gene was activated by light. The following representative model laser-induced choroid neovascularization and oxygen-induced retinopathy were taken as examples to verify the effect of this nanosystem. The results showed that the opto-CRISPR nanosystem was more efficacious in the light control group (NV area effectively reduced by 41.54%) than in the dark control group without light treatment. This strategy for the CRISPR-optogenetic gene nanosystem led to the development of approaches for treating severe eye diseases. Besides, any target gene of interest can be designed by merely replacing the guide RNA sequences in this system, which provided a method for light-controlled gene transcriptional repression.

A Logic AND-Gated Sonogene Nanosystem for Precisely Regulating the Apoptosis of Tumor Cells.

To date, many methods have been developed for inducing tumor cell death, such as using chemical drugs and radiation. However, all of them have a common problem, a lack of mechanisms for precisely regulating the death of tumor cells. It often leads to nonspecific death and systemic side effects. Therefore, the efficacy and further application of these traditional methods are limited. In this paper, a logic AND-gated sonogene nanosystem was designed for precisely regulating the apoptosis of tumor cells. The running of this system required two essential parts, MscL I92L channel protein and ultrasound. Ultrasound could open the MscL I92L protein channel which when expressed on cells triggers the influx and outflux of small molecules through the channel. When the channel is kept open for a long time, Ca2+ influx becomes excessive which in turn activates the Ca2+ apoptosis pathway of cells. The expression of MscL I92L protein and the applying of ultrasound constituted the logic AND gate which could implement the precise regulation to apoptosis. This strategy would help reduce nonspecific triggers and side effects. In this system, cationic nanoliposomes were prepared as the carrier for effectively delivering MscL I92L plasmids to tumor cells in vivo. We investigated the apoptosis-promoting effect of this system in different tumor cell lines (HeLa, B16, and 4T1). The results demonstrated that the apoptosis rate was highest in the B16 cell line (the early apoptosis rate was 11.9% and the late apoptosis rate was 59.1%) when the cells were subjected to consistent ultrasound (6 MHz, 15 W) for 30 min. This logic AND-gated sonogene nanosystem is expected to provide a new strategy and development direction for tumor therapy.

An efficient delivery of photosensitizers and hypoxic prodrugs for a tumor combination therapy by membrane camouflage nanoparticles.

Photodynamic therapy (PDT) is an oxygen-dependent, non-invasive cancer treatment. The hypoxia in the tumor environment limits the therapeutic effects of PDT. The combined delivery of photosensitizers and hypoxic prodrugs is expected to improve the efficacy of tumor treatment. In this paper, an erythrocyte and tumor cell membrane camouflage nanocarrier co-loaded with a photosensitizer (indocyanine green) and a hypoxic prodrug (tirapazamine) were used to combine PDT with chemotherapy. The system achieved less macrophage clearance through erythrocyte membranes and tumor-targeted tumor cell membranes, thereby inducing cell death and increasing tumor environment hypoxia by NIR irradiation of photosensitizers. Furthermore, the hypoxic environment activated TPZ to kill more tumor cells. In vivo results showed that the tumor inhibition rate of the drug-loaded nanoparticles increased from 34% to 64% after membrane modification. Moreover, the tumor inhibition rate of the photodynamic treatment group alone was only 47%, and the tumor inhibition rate after the combination was 1.3 times that of photodynamic therapy alone. Our platform is expected to contribute to the further application of cancer combination therapy.