As traditional anticancer treatments fail to significantly improve the prognoses, exploration of therapeutic modalities is urgently needed. Herein, a biomimetic magnetosome is constructed to favor the ferroptosis/immunomodulation synergism in cancer. This magnetosome is composed of an Fe3O4 magnetic nanocluster (NC) as the core and pre-engineered leukocyte membranes as the cloak, wherein TGF-β inhibitor (Ti) can be loaded inside the membrane and PD-1 antibody (Pa) can be anchored on the membrane surface. After intravenous injection, the membrane camouflage results in long circulation, and the NC core with magnetization and superparamagnetism enables magnetic targeting with magnetic resonance imaging (MRI) guidance. Once inside the tumor, Pa and Ti cooperate to create an immunogenic microenvironment, which increases the amount of H2O2 in polarized M1 macrophages and thus promotes the Fenton reaction with Fe ions released from NCs. The generated hydroxyl radicals (•OH) subsequently induce lethal ferroptosis to tumor cells, and the exposed tumor antigen, in turn, improves the microenvironment immunogenicity. The synergism of immunomodulation and ferroptosis in such a cyclical manner therefore leads to potent therapeutic effects with few abnormalities, which supports the engineered magnetosomes as a promising combination modality for anticancer therapy.
As a type of programmed cell death, ferroptosis is distinct from apoptosis. The combination of the two thus provides a promising modality with which to significantly improve anticancer treatment efficacy. To fully utilize this combination, we herein designed a nanolongan delivery system, which possessed a typical structure of one core (up-conversion nanoparticles, UCNP) in one gel particle (Fe3+ cross-linked oxidized starch) with multiple on-demand conversions. The charge conversion of the nanolongan surface in a slightly acidic microenvironment enhanced circulation time for utilizing the enhanced permeability and retention effect, enabled efficient uptake by tumor cells, and induced subsequently lysosomal escape. As the core component, the UCNP with light conversion from near-infrared light to ultraviolet light circumvented the impediment of limited penetration depth and enabled the reduction of Fe3+ to Fe2+. Accordingly, gel networks of nanolongan could be deconstructed due to this valence conversion, leading to the rapid release of Fe2+ and doxorubicin (Dox). In this case, the Fenton reaction between Fe2+ and intracellular H2O2 generated potent reactive oxygen species for ferroptosis, while the co-released Dox penetrated into nucleus and induced apoptosis in a synergistic way. As a result, superior anticancer therapeutic effects were achieved with little systemic toxicity, indicating that our nanolongan could serve as a safe and high-performance platform for ferroptosis–apoptosis combined anticancer therapy.
A novel cancer vaccine is developed by using Fe 3 O 4 magnetic nanoclusters (MNCs) as the core and cancer cell membranes decorated with anti-CD205 as the cloak. Because of the superparamagnetism and magnetization of MNCs, it is first achieved for the magnetic retention of vaccine in the lymph nodes with a magnetic resonance imaging (MRI) guide, which opened the time window for antigen uptake by dendritic cells (DCs). Meanwhile, the camouflaged cancer cell membranes serve as a reservoir of various antigens, enabling subsequent multiantigenic response. Additionally, the decorated anti-CD205 direct more vaccine into CD8 + DCs, facilitating the major histocompatibility complex (MHC) I cross-presentation. These unique advantages together lead to a great proliferation of T cells with superior clonal diversity and cytotoxic activity. As a result, potent prophylactic and therapeutic effects with few abnormalities are observed on five different tumor models. Therefore, such a cancer-derived magnetosome with the integration of various recent nanotechnologies successfully demonstrates its promise for safe and high-performance cancer vaccination.
Although adoptive T-cell therapy has been successful in hematological malignancy treatment, its application in solid tumors remains a great challenge. Here, using a pH-sensitive benzoic−imine bond and inverse electrondemand Diels−Alder cycloaddition, we prepared magnetic nanoclusters (NCs) armed with responsive PD-1 antibody (aP), which could then bind onto effector T cells due to their PD-1 expression. After adoptive transfer, the magnetization and superparamagnetism of NCs enabled us to magnetically recruit effector T cells and aP simultaneously to tumor sites with MRI guidance. Owing to the acidic intratumoral microenvironment, the benzoic−imine bond then hydrolyzed, leading to the release of aP. The therapeutic effects of adoptive T cells and free aP could thus be spatiotemporally coupled. As a result, we achieved inhibition of tumor growth with few side effects, demonstrating the great promise of such a chemical approach for safe and high-performance adoptive T-cell therapy against solid tumors.
Precisely delivering siRNA to its target site in cancer cells is a highdemanding but challenging task. Herein, a biomimetic magnetosome is developed using magnetic nanocluster (MNC) as the core and Arg-Gly-Asp (RGD) decorated macrophage membrane as the cloak, which is achieved via a combination of MNC synthesis, azide-membrane engineering, electrical assembly, and click chemistry. Such a feature-packed magnetosome enables us to gain the success of high-performance siRNA delivery through superior stealth effect, magnetic resonance imaging, magnetic accumulation, RGD targeting, and favorable cytoplasm trafficking. As a result, target gene expression can be significantly suppressed and tumor growth is effectively inhibited, while the systemic toxicity is not notable. These results together vote the biomimetic magnetosome as a promising siRNA delivery system for anticancer therapy.
Effective multimodality phototheranostics under deep-penetration laser excitation is highly desired for tumor medicine, which is still at a deadlock due to lack of versatile photosensitizers with absorption located in the long-wavelength region. Herein, we demonstrate a stable organic photosensitizer nanoparticle based on molecular engineering of benzo[c]thiophene (BT)-based photoactivated molecules with strong wavelength-tunable absorption in the near-infrared region. Via molecular design, the absorption and singlet oxygen generation of BT molecules would be reliably tuned. Importantly, the nanoparticles with a red-shifted absorption peak of 843 nm not only show over 10-fold reactive oxygen species yield compared with indocyanine green but also demonstrate a notable photothermal effect and photoacoustic signal upon 808 nm excitation. The in vitro and in vivo experiments substantiate good multimodal anticancer efficacy and imaging performance of BT theranostics. This work provides an organic photosensitizer nanoparticle with long-wavelength excitation and high photoenergy conversion efficiency for multimodality phototherapy.
Extracellular vesicles (EVs) hold great potential in both disease treatment and drug delivery. However, accurate drug release from EVs, as well as the spontaneous treatment effect cooperation of EVs and drugs at target tissues, is still challenging. Here, an engineered self‐activatable photo‐EV for synergistic trimodal anticancer therapy is reported. M1 macrophage‐derived EVs (M1 EVs) are simultaneously loaded with bis[2,4,5‐trichloro‐6‐(pentyloxycarbonyl) phenyl] oxalate (CPPO), chlorin e6 (Ce6), and prodrug aldoxorubicin (Dox‐EMCH). After administration, the as‐prepared system actively targets tumor cells because of the tumor‐homing capability of M1 EVs, wherein M1 EVs repolarize M2 to M1 macrophages, which not only display immunotherapy effects but also produce H2O2. The reaction between H2O2 and CPPO generates chemical energy that activates Ce6, creating both chemiluminescence for imaging and singlet oxygen (1O2) for photodynamic therapy (PDT). Meanwhile, 1O2‐induced membrane rupture leads to the release of Dox‐EMCH, which is then activated and penetrates the deep hypoxic areas of tumors. The synergism of immunotherapy, PDT, and chemotherapy results in potent anticancer efficacy, showing great promise to fight cancers.
Hypoxic microenvironment severely reduces therapeutic efficacy of oxygendependent photodynamic therapy in solid tumor due to the hampered cytotoxic oxygen radicals generation. Herein, a biocompatible nanoparticle (NP) is developed by combining bovine serum albumin, indocyanine green (ICG), and an oxygen-independent radicals generator (AIPH) for efficient sequential cancer therapy, denoted as BIA NPs. Upon near-infrared irradiation, the photothermal effect generated by ICG will induce rapid decomposition of AIPH to release cytotoxic alkyl radicals, leading to cancer cell death in both normoxic and hypoxic environments. Moreover, such nanosystem provides the highest AIPH loading capacity (14.9%) among all previously reported radical nanogenerators (generally from 5-8%). Additionally, the aggregation-quenched fluorescence of ICG molecules in the NPs can be gradually released and recovered upon irradiation enabling real-time drug release monitoring. More attractively, these BIA NPs exhibit remarkable anticancer effects both in vitro and in vivo, achieving 100% tumor elimination and 100% survival rate among 50 days treatment. These results highlight that this albumin-based nanoplatform is promising for high-performance cancer therapy circumventing hypoxic tumor environment and possessing great potential for future clinical translation.
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