Naturally available hypericin undergoes electron transfer for type I photodynamic and photothermal synergistic therapy

A manganese-oxide nano-rambutan as the intrinsic modifier for hypericin delivery and triple-negative breast cancer treatment

The anti-tumor efficacy of naturally derived photosensitizer-hypericin (Hy) is dampened by hypoxia and over-expressed glutathione in the tumor microenvironment (TME). For rewiring the TME, we encapsulated Hy to an intrinsic modifier-manganese oxide-formed nanorambutan (MnOx-Hy NR). In triple-negative breast cancer cells, MnOx-Hy NR not only consumed glutathione through Mn2+ and hypericin release but also facilitated O2 production to relieve hypoxia, through which the reactive oxygen species (ROS) generation was strengthened by endoplasmic reticulum targeting hypericin. In the meantime, glutathione consumption-induced glutathione peroxidase 4 (GPX4) inactivation and the elevation of lipid hydroperoxide (LPO) level further triggered ferroptosis. Then, the combination of PDT and ferroptosis contributed to a synergic immunogenic cell death (ICD) effect in 4 T1 cells, facilitating the adaptive anti-tumor immune response activation. Thereby, MnOx-Hy NR exhibited excellent anti-tumor effects both in primary and distant tumors through the abscopal effect, as well as significant lung metastasis inhibition in the 4 T1 mouse metastatic tumor model.

Construction and synergistic anti-tumor study of a tumor microenvironment-based multifunctional nano-drug delivery system

To solve the problems existing in the clinical application of hypericin (Hyp) and tirapazamine (TPZ), a nano-drug delivery system with synergistic anti-tumor functions was constructed using mesoporous silica nanoparticles (MSN) and sodium alginate (SA). The system exhibited excellent stability, physiological compatibility and targeted drug release performance in tumor tissues. In the in vitro and in vivo experiments, Hyp released from MSN killed tumor cells through photodynamic therapy (PDT). The degree of hypoxia in the tumor tissue site was exacerbated, enabling TPZ to fully exert its anti-tumor activity. Our studies suggested that the synergistic effects between the components of the nano-drug delivery system significantly improve the anti-tumor properties of Hyp and TPZ.

Hypericin: A natural anthraquinone as promising therapeutic agent

BACKGROUND

Hypericin is a prominent secondary metabolite mainly existing in genus Hypericum. It has become a research focus for a quiet long time owing to its extensively pharmacological activities especially the anti-cancer, anti-bacterial, anti-viral and neuroprotective effects. This review concentrated on summarizing and analyzing the existing studies of hypericin in a comprehensive perspective.

METHODS

The literature with desired information about hypericin published after 2010 was gained from electronic databases including PubMed, SciFinder, Science Direct, Web of Science, China National Knowledge Infrastructure databases and Wan Fang DATA.

RESULTS

According to extensive preclinical and clinical studies conducted on the hypericin, an organized and comprehensive summary of the natural and artificial sources, strategies for improving the bioactivities, pharmacological activities, drug combination of hypericin was presented to explore the future therapeutic potential of this active compound.

CONCLUSIONS

Overall, this review offered a theoretical guidance for the follow-up research of hypericin. However, the pharmacological mechanisms, pharmacokinetics and structure activity relationship of hypericin should be further studied in future research.

A highly efficient polydopamine encapsulated clinical ICG theranostic nanoplatform for enhanced photothermal therapy of cervical cancer

Photothermal therapy (PTT) is a safe and efficient anti-tumor treatment. A photothermal agent (PTA) with good biocompatibility and strong photothermal properties is of great importance for PTT. In this study, near-infrared (NIR) excitable clinical indocyanine green (ICG) was utilized as a PTA and further encapsulated by another PTA polydopamine (PDA) to form highly stable and efficient ICG@PDA nanoparticles (NPs). Then the ICG@PDA NPs were modified with methoxy polyethylene glycol amine (mPEG2000-NH2) to form biocompatible ICG@PDA@PEG NPs. ICG@PDA@PEG NPs showed good water solubility and a spherical shape with an average size of 140 nm. Furthermore, the photothermal properties of ICG@PDA@PEG NPs were studied and excellent photothermal performance with a photothermal conversion efficiency of 43.7% under 808 nm laser irradiation was achieved. Then, the PTT properties of ICG@PDA@PEG NPs were confirmed on HeLa cells with an efficiency of 86.1%. Meanwhile, the in vivo biocompatibility and toxicity of ICG@PDA@PEG NPs were evaluated. No apparent in vivo toxicity was observed in 24 hours and 7 days. Next, in vivo PTT analysis was conducted for cervical tumor-bearing nude mice under 808 nm laser excitation. It showed a good anti-tumor effect in vivo. Thus, ICG@PDA@PEG NPs exhibited great potential for safe and efficient photothermal therapy in anti-tumor therapy.

Recent Progress of Metal-Organic Framework-Based Photodynamic Therapy for Cancer Treatment

Photodynamic therapy (PDT), combining photosensitizers (PSs) and excitation light at a specific wavelength to produce toxic reactive oxygen species, has been a novel and promising approach to cancer treatment with non-invasiveness, spatial specificity, and minimal systemic toxicity, compared with conventional cancer treatment. Recently, numerous basic research and clinical research have demonstrated the potential of PDT in the treatment of a variety of malignant tumors, such as esophageal cancer, bladder cancer, and so on. Metal-organic framework (MOF) has been developed as a new type of nanomaterial with the advantages of high porosity, large specific surface area, adjustable pore size, and easy functionalization, which could serve as carriers to load PSs or increase the accumulation of PSs in target cells during PDT. Moreover, active MOFs have the potential to construct multifunctional systems, which are conducive to refining the tumor microenvironment (TME) and implementing combination therapy to improve PDT efficacy. Hence, a comprehensive and in-depth depiction of the whole scene of the recent development of MOFs-based PDT in cancer treatment is desirable. This review summarized the recent research strategies of MOFs-based PDT in antitumor therapy from the perspective of MOFs functions, including active MOFs, inactive MOFs, and their further combination therapies in clinical antitumor treatment. In addition, the bottlenecks and obstacles in the application of MOFs in PDT are also described.

Visible light-driven i-motif-based DNAzymes

DNA foldings provide variant possibilities to develop DNAzymes with remarkable catalytic performance. In spite of fruitful reports on G-quadruplex DNAzymes, four-stranded cytosine-rich i-motifs have not been explored as the potential skeletons of DNAzymes. In this work, we developed a visible light-driven DNAzyme based on human telomeric i-motifs using a natural photosensitizer of hypericin (Hyp) as the cofactor and dissolved oxygen as the oxidant source. The i-motif folding in acidic solution caused the distal thymine overhangs at the 3' and 5' ends to approach each other to provide a favorable binding site for Hyp via an interaction of fully complementary hydrogen bonding. However, the i-motifs without the distal overhangs or with the inappropriate overhang length and the base identity exhibited no binding with Hyp. The binding event converted Hyp from the fully dark state to the emissive state under visible light illumination. Subsequently, the excited Hyp had an opportunity to transfer energy to dissolved oxygen. Resultantly, singlet oxygen (¹O₂) was generated to initiate the substrate oxidation. The catalytic performance of the DNAzyme can be improved using a long-lived mediator. Our developed i-motif-based DNAzyme can be driven by almost the whole range of visible lights, suggesting broad applications in the photocatalytic fields, for example, as an alternative strategy in developing biodevices.

Recent Advances in Strategies for Addressing Hypoxia in Tumor Photodynamic Therapy

Photodynamic therapy (PDT) is a treatment modality that uses light to target tumors and minimize damage to normal tissues. It offers advantages including high spatiotemporal selectivity, low side effects, and maximal preservation of tissue functions. However, the PDT efficiency is severely impeded by the hypoxic feature of tumors. Moreover, hypoxia may promote tumor metastasis and tumor resistance to multiple therapies. Therefore, addressing tumor hypoxia to improve PDT efficacy has been the focus of antitumor treatment, and research on this theme is continuously emerging. In this review, we summarize state-of-the-art advances in strategies for overcoming hypoxia in tumor PDTs, categorizing them into oxygen-independent phototherapy, oxygen-economizing PDT, and oxygen-supplementing PDT. Moreover, we highlight strategies possessing intriguing advantages such as exceedingly high PDT efficiency and high novelty, analyze the strengths and shortcomings of different methods, and envision the opportunities and challenges for future research.

How do bismuth-based nanomaterials function as promising theranostic agents for the tumor diagnosis and therapy?

The complexity of tumor microenvironment and the diversity of tumors seriously affect the therapeutic effect, the focus, therefore, has gradually been shifted from monotherapy to combination therapy in clinical research in order to improve the curative effect. The synergistic enhancement interactions among multiple monotherapies majorly contribute to the birth of the multi-mode cooperative therapy, whose effect of the treatment is clearly stronger than that of any single therapy. In addition, the accurate diagnosis of the tumour location is also crucial to the treatment. Bismuth-based nanomaterials (NMs) hold great properties as promising theranostic platforms based on their many unique features that include low toxicity, excellent photothermal conversion efficiency as well as high ability of X-ray computed tomography imaging and photoacoustic imaging. In this review, we will introduce briefly the main features of tumor microenvironment first and its effect on the mechanism of nanomedicine actions and present the recent advances of bismuth-based NMs for diagnosis and photothermal therapy-based combined therapies using bismuth-based NMs are presented, which may provide a new way for overcoming drug resistance and hypoxia. At the end, further challenges and outlooks regarding this promising field are discussed accompanied with some design tips for bismuth-based NMs, hoping to provide researchers some inspirations to design safe and effective nanotherapeutic agents for the clinical treatments of cancers.

Phototherapy and multimodal imaging of cancers based on perfluorocarbon nanomaterials

Phototherapy, such as photodynamic therapy (PDT) and photothermal therapy (PTT), possesses unique characteristics of non-invasiveness and minimal side effects in cancer treatment, compared with conventional therapies. However, the ubiquitous tumor hypoxia microenvironments could severely reduce the efficacy of oxygen-consuming phototherapies. Perfluorocarbon (PFC) nanomaterials have shown great practical value in carrying and transporting oxygen, which makes them promising agents to overcome tumor hypoxia and extend reactive oxygen species (ROS) lifetime to improve the efficacy of phototherapy. In this review, we summarize the latest advances in PFC-based PDT and PTT, and combined multimodal imaging technologies in various cancer types, aiming to facilitate their application-oriented clinical translation in the future.

Vaginal drug delivery approaches for localized management of cervical cancer

Cervical cancer or cervical intraepithelial neoplasia (CIN) remain a major public health problem among women globally. Traditional methods such as surgery are often associated with possible complications which may impact future pregnancies and childbirth especially for young female patients. Vagina with a high contact surface is a suitable route for the local and systemic delivery of drugs but its abundant mucus in continuous exchange presents a barrier for the popularization of conventional vaginal formulations including suppositories, gel, patch, creams and so on. So the development of new pharmaceutical forms based on nanotechnology became appealing owing to its several advantages such as mucosa penetration, bioadhesion, controlled drug release, and decreased adverse effects. This review provided an overview of the development of topical treatment of cervical cancer or CIN through vaginal drug delivery ranging from conventional vaginal formulations to new nanocarriers to the newly developed phototherapy and gene therapy, analyzing the problems faced by current methods used, and advising the developing trend in future. The methods of establishing preclinical animal model are also discussed.

Novel indole-BODIPY photosensitizers based on iodine promoted intersystem crossing enhancement for lysosome-targeted imaging and photodynamic therapy

In this work, we report the new lysosome-targeting indole-BODIPY derivatives BDP-Lys, IBDP-Lys, and I2BDP-Lys.

A carbazole functionalized semiconducting compound as a heavy atom free photosensitizer for phototherapy against lung cancer

Semiconducting compounds with high photostability and excellent photothermal ability are potential candidates for phototheranostics. In this paper, the heavy atom free compound 3,6-bis(5-(4-(9H-carbazol-9-yl)phenyl)furan-2-yl)-2,5-bis(2-octyldodecyl)pyrrolo[3,4-c]pyrrole-1,4(2H,5H)-dione (denoted as DPPCz) has been designed and synthesized through a C-H activation coupling reaction. DPPCz has a high singlet oxygen quantum yield (¹O₂ QY) of 40.3% in DCM. In addition, DPPCz NPs obtained by nanoprecipitation exhibit a high photothermal conversion efficiency (48.2%) in water. DPPCz NPs have a low half inhibitory concentration (IC₅₀) of 7.1 μg mL^-1 towards human lung cancer cells (A549) with irradiation while the dark toxicity is almost negligible even at high concentrations. Furthermore, in vivo photothermal imaging guided study demonstrates that these NPs are able to inhibit tumor growth with the help of laser. The H&E stained pictures of the normal tissues indicate the biosafety of DPPCz NPs in that no obvious damage was observed. Our results demonstrate that DPPCz NPs are potential semiconducting photosensitizers for phototheranostics.