A Self-Delivery Nanodrug Simultaneously Inhibits COX-2/PGE2 Mediated Inflammation and Downregulates PD-L1 to Boost Photoimmunotherapy.

Phototherapy promotes anti-tumor immunity by inducing immunogenic cell death (ICD), However, the accompanying inflammatory responses also trigger immunosuppression, attenuating the efficacy of photo-immunotherapy. Herein, they co-assembled a cell-membrane targeting chimeric peptide C16-Cypate-RRKK-PEG8-COOH (CCP) and anti-inflammatory diclofenac (DA) to develop a nanodrug (CCP@DA) that both enhances the immune effect of phototherapy and weakens the inflammation-mediated immunosuppression. CCP@DA achieves cell membrane-targeting photodynamic and photothermal synergistic therapies to damage programmed death ligand 1 (PD-L1) and induce a strong ICD to activate anti-tumor response. Simultaneously, the released DA inhibits the cycoperoxidase-2 (COX-2)/prostaglandin E2 (PGE2) pathway in tumor cells to inhibit pro-tumor inflammation and further down-regulate PD-L1 expression to relieve the immunosuppressive microenvironment. CCP@DA significantly inhibited tumor growth and inflammation both in vitro and in vivo, while maintaining a potent anti-tumor immune response. Additionally, it exhibits excellent anti-metastatic capabilities and prolongs mouse survival time with a single dose and low levels of near-infrared (NIR) light exposure. This work provides a valuable strategy to control the therapy-induced inflammation for high-efficiency photoimmunotherapy.

A self-delivery chimeric peptide for high efficient cell membrane-targeting low-temperature photothermal/photodynamic combinational therapy and metastasis suppression of tumor.

Cellular barriers such as the cell membranes, lysosomes or nuclear pores of tumor cells hinder the drugs delivery and weaken the efficiency of traditional tumor therapies. Targeted destructing tumor cell membranes can quickly destroy cell homeostasis and kill cells without facing intracellular delivery barriers. Herein, we designed a self-delivery phototherapeutic chimeric peptide (CCP) for high efficient cell membrane-targeting combinational low-temperature photothermal therapy (LTPTT) and photodynamic therapy (PDT). The self-assembled CCP nanoparticles display remarkable tumor accumulation after systemic administration without additional carriers, avoiding the carriers related side toxicities. The CCPs are able to generate reactive oxygen species (ROS) and mild heat (<45 °C) locally at cell membrane and quickly induce immunogenic cell death to achieve efficient combinational LTPTT/PDT. The damage-associated molecular patterns released after cell membrane rupture effectively elicit antitumor immunity to eradicate residual tumor cells. With a single dosage and short-term near-infrared (NIR) light irradiation, CCPs significantly inhibit growth and metastasis of tumor, and prolong survival time of tumor-bearing mice. This work presents a unique cell membrane-targeting phototherapy strategy to kill tumor and suppress metastasis in an effective, safe and minimally invasive manner.

Biomimetic nanoparticles for effective mild temperature photothermal therapy and multimodal imaging.

Downregulation of adenosine triphosphate (ATP)-dependent heat shock proteins (HSPs) can significantly reduce the tumorigenicity of cancer cells and overcome heat endurance to achieve high-performance mild temperature (≤45 °C) photothermal therapy (PTT). Herein, we designed and constructed 4T1 cancer cell membrane-coated, lonidamine (LN)-loaded and DL-menthol (DLM)-loaded hollow mesoporous Prussian blue nanoparticles (PBLM@CCM NPs). DLM with mild phase change characteristics served as a plugging agent to avoid early leakage and allow thermally controllable release of LN, which enabled selective intracellular delivery of LN to reduce the HSPs and overcome the heat endurance in PTT by inhibiting the generation of intracellular ATP. The biocompatible PBLM@CCM NPs with good tumor targeting efficiency achieved high-efficiency mild temperature PTT. Meanwhile, PBLM@CCM NPs could allow photoacoustic (PA) imaging and generate heat to promote the phase change of DLM for ultrasound (US) imaging, which is of great value for future clinical translational studies.

Autophagy-inhibiting biomimetic nanodrugs enhance photothermal therapy and boost antitumor immunity.

The instinctive protective stress responses of tumor cells hamper low-temperature photothermal therapy (LTPTT), resulting in tumor recurrence and metastasis. The rapid blood clearance and low-efficiency tumor enrichment of nanomedicines also decrease the efficacy of LTPTT. In this study, we fabricated coassembled photothermal agents (indocyanine green, ICG) and autophagy inhibitors (chloroquine, CQ) and red blood cell and cancer cell hybrid membrane (RCm)-camouflaged ICGCQ@RCm nanoparticles (ICGCQ@RCm NPs) to enhance tumor LTPTT. The ICGCQ@RCm NPs exhibited prolonged blood drug circulation and markedly enhanced drug accumulation in tumor tissues. The ICGCQ@RCm NPs reduced the thermal tolerance of tumor cells to sensitize ICG-mediated LTPTT by inhibiting protective autophagy. The ICGCQ@RCm NPs exerted strong immunogenic cell death (ICD) after efficient LTPTT to activate antitumor immunity. In addition, ICGCQ@RCms optimized the therapeutic efficacy by imaging-guided LTPTT, taking advantage of the near-infrared (NIR) fluorescence of ICG. Consequently, the ICGCQ@RCm NPs effectively inhibited tumors under mild LTPTT, significantly suppressed tumor metastasis and prolonged the survival time of tumor-bearing mice. Furthermore, the ICGCQ@RCm NPs showed high biosafety in vitro and in vivo. The ICGCQ@RCm NPs demonstrated tumor-targeting and imaging-guided autophagy inhibition-sensitized LTPTT using two Food and Drug Administration (FDA)-approved drugs, which have great potential for clinical application.