Polyphenol‐Inspired Facile Construction of Smart Assemblies for ATP‐ and pH‐Responsive Tumor MR/Optical Imaging and Photothermal Therapy

Smart assemblies have attracted increased interest in various areas, especially in developing novel stimuli‐responsive theranostics. Herein, commercially available, natural tannic acid (TA) and iron oxide nanoparticles (Fe₃O₄ NPs) are utilized as models to construct smart magnetic assemblies based on polyphenol‐inspired NPs–phenolic self‐assembly between NPs and TA. Interestingly, the magnetic assemblies can be specially disassembled by adenosine triphosphate, which shows a stronger affinity to Fe₃O₄ NPs than that of TA and partly replaces the surface coordinated TA. The disassembly can further be facilitated by the acidic environment hence causing the remarkable change of the transverse relaxivity and potent “turn‐on” of fluorescence (FL) signals. Therefore, the assemblies for specific and sensitive tumor magnetic resonance and FL dual‐modal imaging and photothermal therapy after intravenous injection of the assemblies are successfully employed. This work not only provides understandings on the self‐assembly between NPs and polyphenols, but also will open new insights for facilely constructing versatile assemblies and extending their biomedical applications.     

Dendrimer‐Assisted Formation of Fe3O4/Au Nanocomposite Particles for Targeted Dual Mode CT/MR Imaging of Tumors

A unique dendrimer‐assisted approach is reported to create Fe₃O₄/Au nanocomposite particles (NCPs) for targeted dual mode computed tomography/magnetic resonance (CT/MR) imaging of tumors. In this approach, preformed Fe₃O₄ nanoparticles (NPs) are assembled with multilayers of poly(γ‐glutamic acid) (PGA)/poly(l ‐lysine)/PGA/folic acid (FA)‐modified dendrimer‐entrapped gold nanoparticles via a layer‐by‐layer self‐assembly technique. The interlayers are crosslinked via 1‐ethyl‐3‐(3‐dimethylaminopropyl)carbodiimide chemistry, the assembled Au core NPs are then used as seed particles for subsequent seed‐mediated growth of Au shells via iterative Au salt reduction process, and subsequent acetylation of the remaining amines of dendrimers leads to the formation of Fe₃O₄/Au_n.Ac‐FA NCPs with a tunable molar ratio of Au/Fe₃O₄. It is shown that the Fe₃O₄/Au_n.Ac‐FA NCPs at an optimized Au/Fe₃O₄ molar ratio of 2.02 display a relatively high R₂ relaxivity (92.67 × 10^?3 M^?1 s^?1) and good X‐ray attenuation property, and are cytocompatible and hemocompatible in the given concentration range. Importantly, with the FA‐mediated targeting, the Fe₃O₄/Au_n.Ac‐FA NCPs are able to be specifically uptaken by cancer cells overexpressing FA receptors, and be used as an efficient nanoprobe for targeted dual mode CT/MR imaging of a xenografted tumor model. With the versatile dendrimer chemistry, the developed Fe₃O₄/Au NCPs may be differently functionalized, thereby providing a unique platform for diagnosis and therapy of different biological systems.     

Electrostatic Self‐Assembly of Au Nanoparticles onto Thermosensitive Magnetic Core‐Shell Microgels for Thermally Tunable and Magnetically Recyclable Catalysis

A facile route to fabricate a nanocomposite of Fe₃O₄@poly[N‐isopropylacrylamide (NIPAM)‐co‐2‐(dimethylamino)ethyl methacrylate (DMAEMA)]@Au (Fe₃O₄@PND@Au) is developed for magnetically recyclable and thermally tunable catalysis. The negatively charged Au nanoparticles with an average diameter of 10 nm are homogeneously loaded onto positively charged thermoresponsive magnetic core‐shell microgels of Fe₃O₄@poly(NIPAM‐co‐DMAEMA) (Fe₃O₄@PND) through electrostatic self‐assembly. This type of attachment offers perspectives for using charged polymeric shell on a broad variety of nanoparticles to immobilize the opposite‐charged nanoparticles. The thermosensitive PND shell with swollen or collapsed properties can be as a retractable Au carrier, thereby tuning the aggregation or dispersion of Au nanoparticles, which leads to an increase or decrease of catalytic activity. Therefore, the catalytic activity of Fe₃O₄@PND@Au can be modulated by the volume transition of thermosensitive microgel shells. Importantly, the mode of tuning the aggregation or dispersion of Au nanoparticles using a thermosensitive carrier offers a novel strategy to adjust and control the catalytic activity, which is completely different with the traditional regulation mode of controlling the diffusion of reactants toward the catalytic Au core using the thermosensitive poly(N‐isopropylacrylamide) network as a nanogate. Concurrent with the thermally tunable catalysis, the magnetic susceptibility of magnetic cores enables the Fe₃O₄@PND@Au nanocomposites to be capable of serving as smart nanoreactors for thermally tunable and magnetically recyclable catalysis.     

Tumor‐Targeting Multifunctional Rattle‐Type Theranostic Nanoparticles for MRI/NIRF Bimodal Imaging and Delivery of Hydrophobic Drugs

The development of theranostic systems capable of diagnosis, therapy, and target specificity is considerably significant for accomplishing personalized medicine. Here, a multifunctional rattle‐type nanoparticle (MRTN) as an effective biological bimodal imaging and tumor‐targeting delivery system is fabricated, and an enhanced loading ability of hydrophobic anticancer drug (paclitaxel) is also realized. The rattle structure with hydrophobic Fe₃O₄ as the inner core and mesoporous silica as the shell is obtained by one‐step templates removal process, and the size of interstitial hollow space can be easily adjusted. The Fe₃O₄ core with hydrophobic poly(tert‐butyl acrylate) (PTBA) chains on the surface is not only used as a magnetic resonance imaging (MRI) agent, but contributes to improving hydrophobic drug loading amount. Transferrin (Tf) and a near‐infrared fluorescent dye (Cy 7) are successfully modified on the surface of the nanorattle to increase the ability of near‐infrared fluorescence (NIRF) imaging and tumor‐targeting specificity. In vivo studies show the selective accumulation of MRTN in tumor tissues by Tf‐receptor‐mediated endocytosis. More importantly, paclitaxel‐loaded MRTN shows sustained release character and higher cytotoxicity than the free paclitaxel. This theranostic nanoparticle as an effective MRI/NIRF bimodal imaging probe and drug delivery system shows great potential in cancer diagnosis and therapy.     

In Vivo Tumor Visualization through MRI Off‐On Switching of NaGdF4–CaCO3 Nanoconjugates

The development of high‐performance contrast agents in magnetic resonance imaging (MRI) has recently received considerable attention, as they hold great promise and potential as a powerful tool for cancer diagnosis. Despite substantial achievements, it remains challenging to develop nanostructure‐based biocompatible platforms that can generate on‐demand MRI signals with high signal‐to‐noise ratios and good tumor specificity. Here, the design and synthesis of a new class of nanoparticle‐based contrast agents comprising self‐assembled NaGdF₄ and CaCO₃ nanoconjugates is reported. In this design, the spatial confinement of the T₁ source (Gd³⁺ ions) leads to an “OFF” MRI signal due to insufficient interaction between the protons and the crystal lattices. However, when immersed in the mildly acidic tumor microenvironment, the embedded CaCO₃ nanoparticles generate CO₂ bubbles and subsequently disconnect the nanoconjugate, thus resulting in an “ON” MRI signal. The in vivo performance of these nanoconjugates shows more than 60‐fold contrast enhancement in tumor visualization relative to the commercially used contrast agent Magnevist. This work presents a significant advance in the construction of smart MRI nanoprobes ideally suited for deep‐tissue imaging and target‐specific cancer diagnosis.     

A Biomimetic Polymer Magnetic Nanocarrier Polarizing Tumor‐Associated Macrophages for Potentiating Immunotherapy

The progress of antitumor immunotherapy is usually limited by tumor‐associated macrophages (TAMs) that account for the highest proportion of immunosuppressive cells in the tumor microenvironment, and the TAMs can also be reversed by modulating the M2‐like phenotype. Herein, a biomimetic polymer magnetic nanocarrier is developed with selectively targeting and polarizing TAMs for potentiating immunotherapy of breast cancer. This nanocarrier PLGA‐ION‐R837 @ M (PIR @ M) is achieved, first, by the fabrication of magnetic polymer nanoparticles (NPs) encapsulating Fe₃O₄ NPs and Toll‐like receptor 7 (TLR7) agonist imiquimod (R837) and, second, by the coating of the lipopolysaccharide (LPS)‐ treated macrophage membranes on the surface of the NPs for targeting TAMs. The intracellular uptake of the PIR @ M can greatly polarize TAMs from M2 to antitumor M1 phenotype with the synergy of Fe₃O₄ NPs and R837. The relevant mechanism of the polarization is deeply studied through analyzing the mRNA expression of the signaling pathways. Different from previous reports, the polarization is ascribed to the fact that Fe₃O₄ NPs mainly activate the IRF5 signaling pathway via iron ions instead of the reactive oxygen species‐induced NF‐κB signaling pathway. The anticancer effect can be effectively enhanced through potentiating immunotherapy by the polarization of the TAMs in the combination of Fe₃O₄ NPs and R837.     

Dual‐Stage Light Amplified Photodynamic Therapy against Hypoxic Tumor Based on an O2 Self‐Sufficient Nanoplatform

Tumor hypoxia severely limits the efficacy of traditional photodynamic therapy (PDT). Here, a liposome‐based nanoparticle (designated as LipoMB/CaO₂) with O₂ self‐sufficient property for dual‐stage light‐driven PDT is demonstrated to address this problem. Through a short time irradiation, ¹O₂ activated by the photosensitizer methylene blue (MB) can induce lipid peroxidation to break the liposome, and enlarge the contact area of CaO₂ with H₂O, resulting in accelerated O₂ production. Accelerated O₂ level further regulates hypoxic tumor microenvironment and in turn improves ¹O₂ generation by MB under another long time irradiation. In vitro and in vivo experiments also demonstrate the superior competence of LipoMB/CaO₂ to alleviate tumor hypoxia, suppress tumor growth and antitumor metastasis with low side‐effect. The O₂ self‐sufficient LipoMB/CaO₂ nanoplatform with dual‐stage light manipulation is a successful attempt for PDT against hypoxic tumor.     

Multifunctional pDNA‐Conjugated Polycationic Au Nanorod‐Coated Fe3O4 Hierarchical Nanocomposites for Trimodal Imaging and Combined Photothermal/Gene Therapy

It is very desirable to design multifunctional nanocomposites for theranostic applications via flexible strategies. The synthesis of one new multifunctional polycationic Au nanorod (NR)‐coated Fe₃O₄ nanosphere (NS) hierarchical nanocomposite (Au@pDM/Fe₃O₄) based on the ternary assemblies of negatively charged Fe₃O₄ cores (Fe₃O₄‐PDA), polycation‐modified Au nanorods (Au NR‐pDM), and polycations is proposed. For such nanocomposites, the combined near‐infrared absorbance properties of Fe₃O₄‐PDA and Au NR‐pDM are applied to photoacoustic imaging and photothermal therapy. Besides, Fe₃O₄ and Au NR components allow the nanocomposites to serve as MRI and CT contrast agents. The prepared positively charged Au@pDM/Fe₃O₄ also can complex plasmid DNA into pDNA/Au@pDM/Fe₃O₄ and efficiently mediated gene therapy. The multifunctional applications of pDNA/Au@pDM/Fe₃O₄ nanocomposites in trimodal imaging and combined photothermal/gene therapy are demonstrated using a xenografted rat glioma nude mouse model. The present study demonstrates that the proper assembly of different inorganic nanoparticles and polycations is an effective strategy to construct new multifunctional theranostic systems.     

Synthesis of PVP-coated ultra-small Fe3O4 nanoparticles as a MRI contrast agent

Ultra-small Fe₃O₄ nanoparticles were prepared by using the coprecipitation method, in which the polyvinylpyrrolidone (PVP) serves as a stabilizer. The nanoparticles were characterized by means of X-ray diffraction (XRD), transmission electron microscopy (TEM), infra spectrum (IR), X-ray photoelectron spectroscopy (XPS) and in vivo magnetic resonance imaging (MRI) test. The results showed that the particles’ size was determined by the dripping rate and that PVP molecules played the role of preventing the aggregation and restricting the size of Fe₃O₄ nanoparticles. The Fe₃O₄ nanoparticles with diameter from 6.5 to 1.9 nm obviously exhibited negative contrast enhancement and concentrated at the target area guided by a permanent magnet.     

“Dual‐Template” Synthesis of One‐Dimensional Conductive Nanoparticle Superstructures from Coordination Metal–Peptide Polymer Crystals

Bottom‐up fabrication of self‐assembled structures made of nanoparticles may lead to new materials, arrays and devices with great promise for myriad applications. Here a new class of metal–peptide scaffolds is reported: coordination polymer Ag(I)‐DLL belt‐like crystals, which enable the dual‐template synthesis of more sophisticated nanoparticle superstructures. In these biorelated scaffolds, the self‐assembly and recognition capacities of peptides and the selective reduction of Ag(I) ions to Ag are simultaneously exploited to control the growth and assembly of inorganic nanoparticles: first on their surfaces, and then inside the structures themselves. The templated internal Ag nanoparticles are well confined and closely packed, conditions that favour electrical conductivity in the superstructures. It is anticipated that these Ag(I)‐DLL belts could be applied to create long (>100 μm) conductive Ag@Ag nanoparticle superstructures and polymetallic, multifunctional Fe₃O₄@Ag nanoparticle composites that marry the magnetic and conductive properties of the two nanoparticle types.     

Multifunctional Magnetic–Optical Nanoparticle Probes for Simultaneous Detection,Separation, and Thermal Ablation of Multiple Pathogens

Multifunctional nanoparticles possessing magnetization and near‐infrared (NIR) absorption have warranted interest due to their significant applications in magnetic resonance imaging, diagnosis, bioseparation, target delivery, and NIR photothermal ablation. Herein, the site‐selective assembly of magnetic nanoparticles onto the ends or ends and sides of gold nanorods with different aspect ratios (ARs) to create multifunctional nanorods decorated with varying numbers of magnetic particles is described for the first time. The resulting hybrid nanoparticles are designated as Fe₃O₄? Au_rod? Fe₃O₄ nanodumbbells and Fe₃O₄? Au_rod necklacelike constructs with tunable optical and magnetic properties, respectively. These hybrid nanomaterials can be used for multiplex detection and separation because of their tunable magnetic and plasmonic functionality. More specifically, Fe₃O₄? Au_rod necklacelike probes of different ARs are utilized for simultaneous optical detection based on their plasmon properties, magnetic separation, and photokilling of multiple pathogens from a single sample at one time. The combined functionalities of the synthesized probes will open up many exciting opportunities in dual imaging for targeted delivery and photothermal therapy.     

Nanocatalysts‐Augmented and Photothermal‐Enhanced Tumor‐Specific Sequential Nanocatalytic Therapy in Both NIR‐I and NIR‐II Biowindows

The tumor microenvironment (TME) has been increasingly recognized as a crucial contributor to tumorigenesis. Based on the unique TME for achieving tumor‐specific therapy, here a novel concept of photothermal‐enhanced sequential nanocatalytic therapy in both NIR‐I and NIR‐II biowindows is proposed, which innovatively changes the condition of nanocatalytic Fenton reaction for production of highly efficient hydroxyl radicals (?OH) and consequently suppressing the tumor growth. Evidence suggests that glucose plays a vital role in powering cancer progression. Encouraged by the oxidation of glucose to gluconic acid and H₂O₂ by glucose oxidase (GOD), an Fe₃O₄/GOD‐functionalized polypyrrole (PPy)‐based composite nanocatalyst is constructed to achieve diagnostic imaging‐guided, photothermal‐enhanced, and TME‐specific sequential nanocatalytic tumor therapy. The consumption of intratumoral glucose by GOD leads to the in situ elevation of the H₂O₂ level, and the integrated Fe₃O₄ component then catalyzes H₂O₂ into highly toxic ?OH to efficiently induce cancer‐cell death. Importantly, the high photothermal‐conversion efficiency (66.4% in NIR‐II biowindow) of the PPy component elevates the local tumor temperature in both NIR‐I and NIR‐II biowindows to substaintially accelerate and improve the nanocatalytic disproportionation degree of H₂O₂ for enhancing the nanocatalytic‐therapeutic efficacy, which successfully achieves a remarkable synergistic anticancer outcome with minimal side effects.     

Engineered Bacterial Bioreactor for Tumor Therapy via Fenton‐Like Reaction with Localized H2O2 Generation

Synthetic biology based on bacteria has been displayed in antitumor therapy and shown good performance. In this study, an engineered bacterium Escherichia coli MG1655 is designed with NDH‐2 enzyme (respiratory chain enzyme II) overexpression (Ec‐pE), which can colonize in tumor regions and increase localized H₂O₂ generation. Following from this, magnetic Fe₃O₄ nanoparticles are covalently linked to bacteria to act as a catalyst for a Fenton‐like reaction, which converts H₂O₂ to toxic hydroxyl radicals (?OH) for tumor therapy. In this constructed bioreactor, the Fenton‐like reaction occurs with sustainably synthesized H₂O₂ produced by engineered bacteria, and severe tumor apoptosis is induced via the produced toxic ?OH. These results show that this bioreactor can achieve effective tumor colonization, and realize a self‐supplied therapeutic Fenton‐like reaction without additional H₂O₂ provision.     

Color‐Convertible,Unimolecular, Micelle‐Based,Activatable Fluorescent Probe for Tumor‐Specific Detection and Imaging In Vitro and In Vivo

Recent years have witnessed significant progress in molecular probes for cancer diagnosis. However, the conventional molecular probes are designed to be “always‐on” by attachment of tumor‐targeting ligands, which limits their abilities to diagnose tumors universally due to the variations of targeting efficiency and complex environment in different cancers. Here, it is proposed that a color‐convertible, activatable probe is responding to a universal tumor microenvironment for tumor‐specific diagnosis without targeting ligands. Based on the significant hallmark of up‐regulated hydrogen peroxide (H₂O₂) in various tumors, a novel unimolecular micelle constructed by boronate coupling of a hydrophobic hyperbranched poly(fluorene‐co‐2,1,3‐benzothiadiazole) core and many hydrophilic poly(ethylene glycol) arms is built as an H₂O₂‐activatable fluorescent nanoprobe to delineate tumors from normal tissues through an aggregation‐enhanced fluorescence resonance energy transfer strategy. This color‐convertible, activatable nanoprobe is obviously blue‐fluorescent in various normal cells, but becomes highly green‐emissive in various cancer cells. After intravenous injection to tumor‐bearing mice, green fluorescent signals are only detected in tumor tissue. These observations are further confirmed by direct in vivo and ex vivo tumor imaging and immunofluorescence analysis. Such a facile and simple methodology without targeting ligands for tumor‐specific detection and imaging is worthwhile to further development.     

Multistimuli Responsive Core–Shell Nanoplatform Constructed from Fe3O4@MOF Equipped with Pillar[6]arene Nanovalves

An intelligent theranostic nanoplatform based on nanovalve operated metal–organic framework (MOF) core–shell hybrids, incorporating tumorous microenvironment‐triggered drug release, magnetic resonance imaging (MRI) guidance, sustained release, and effective chemotherapy in one pot is reported. The core–shell hybrids are constructed by an in situ growth method, in which Fe₃O₄ particles with superior abilities of MRI and magnetic separation form the core and UiO‐66 MOF with high loading capacity compose the shell, and then are surface‐installed with pillararene‐based pseudorotaxanes as tightness‐adjustable nanovalves. This strategy endows the system with the ability of targeted, multistimuli responsive drug release in response to pH changes, temperature variations, and competitive agents. Water‐soluble carboxylatopillar[6]arene system achieved sustained drug release over 7 days due to stronger host–guest binding, suggesting that the nanovalve tightness further reinforces the desirable release of anticancer agent over a prolonged time at the lesion site.     

Platelet Membrane‐Camouflaged Magnetic Nanoparticles for Ferroptosis‐Enhanced Cancer Immunotherapy

Although cancer immunotherapy has emerged as a tremendously promising cancer therapy method, it remains effective only for several cancers. Photoimmunotherapy (e.g., photodynamic/photothermal therapy) could synergistically enhance the immune response of immunotherapy. However, excessively generated immunogenicity will cause serious inflammatory response syndrome. Herein, biomimetic magnetic nanoparticles, Fe₃O₄‐SAS @ PLT, are reported as a novel approach to sensitize effective ferroptosis and generate mild immunogenicity, enhancing the response rate of non‐inflamed tumors for cancer immunotherapy. Fe₃O₄‐SAS@PLT are built from sulfasalazine (SAS)‐loaded mesoporous magnetic nanoparticles (Fe₃O₄) and platelet (PLT) membrane camouflage and triggered a ferroptotic cell death via inhibiting the glutamate‐cystine antiporter system X_c^? pathway. Fe₃O₄‐SAS @ PLT‐mediated ferroptosis significantly improves the efficacy of programmed cell death 1 immune checkpoint blockade therapy and achieves a continuous tumor elimination in a mouse model of 4T1 metastatic tumors. Proteomics studies reveal that Fe₃O₄‐SAS @ PLT‐mediated ferroptosis could not only induce tumor‐specific immune response but also efficiently repolarize macrophages from immunosuppressive M2 phenotype to antitumor M1 phenotype. Therefore, the concomitant of Fe₃O₄‐SAS @ PLT‐mediated ferroptosis with immunotherapy are expected to provide great potential in the clinical treatment of tumor metastasis.     

A Tumor‐Microenvironment‐Activated Nanozyme‐Mediated Theranostic Nanoreactor for Imaging‐Guided Combined Tumor Therapy

Activatable theranostic agents that can be activated by tumor microenvironment possess higher specificity and sensitivity. Here, activatable nanozyme‐mediated 2,2′‐azino‐bis (3‐ethylbenzothiazoline‐6‐sulfonic acid) (ABTS) loaded ABTS@MIL‐100/poly(vinylpyrrolidine) (AMP) nanoreactors (NRs) are developed for imaging‐guided combined tumor therapy. The as‐constructed AMP NRs can be specifically activated by the tumor microenvironment through a nanozyme‐mediated “two‐step rocket‐launching‐like” process to turn on its photoacoustic imaging signal and photothermal therapy (PTT) function. In addition, simultaneously producing hydroxyl radicals in response to the high H₂O₂ level of the tumor microenvironment and disrupting intracellular glutathione (GSH) endows the AMP NRs with the ability of enhanced chemodynamic therapy (ECDT), thereby leading to more efficient therapeutic outcome in combination with tumor‐triggered PTT. More importantly, the H₂O₂‐activated and acid‐enhanced properties enable the AMP NRs to be specific to tumors, leaving the normal tissues unharmed. These remarkable features of AMP NRs may open a new avenue to explore nanozyme‐involved nanoreactors for intelligent, accurate, and noninvasive cancer theranostics.     

A Glucose/Oxygen‐Exhausting Nanoreactor for Starvation‐ and Hypoxia‐Activated Sustainable and Cascade Chemo‐Chemodynamic Therapy

Fenton reaction‐mediated chemodynamic therapy (CDT) can kill cancer cells via the conversion of H₂O₂ to highly toxic HO?. However, problems such as insufficient H₂O₂ levels in the tumor tissue and low Fenton reaction efficiency severely limit the performance of CDT. Here, the prodrug tirapazamine (TPZ)‐loaded human serum albumin (HSA)–glucose oxidase (GOx) mixture is prepared and modified with a metal–polyphenol network composed of ferric ions (Fe³⁺) and tannic acid (TA), to obtain a self‐amplified nanoreactor termed HSA–GOx–TPZ–Fe³⁺–TA (HGTFT) for sustainable and cascade cancer therapy with exogenous H₂O₂ production and TA‐accelerated Fe³⁺/Fe²⁺ conversion. The HGTFT nanoreactor can efficiently convert oxygen into HO? for CDT, consume glucose for starvation therapy, and provide a hypoxic environment for TPZ radical‐mediated chemotherapy. Besides, it is revealed that the nanoreactor can significantly elevate the intracellular reactive oxygen species content and hypoxia level, decrease the intracellular glutathione content, and release metal ions in the tumors for metal ion interference therapy (also termed “ion‐interference therapy” or “metal ion therapy”). Further, the nanoreactor can also increase the tumor’s hypoxia level and efficiently inhibit tumor growth. It is believed that this tumor microenvironment‐regulable nanoreactor with sustainable and cascade anticancer performance and excellent biosafety represents an advance in nanomedicine.     

Manganese Dioxide Coated WS2@Fe3O4/sSiO2 Nanocomposites for pH‐Responsive MR Imaging and Oxygen‐Elevated Synergetic Therapy

Recently, the development of multifunctional theranostic nanoplatforms to realize tumor‐specific imaging and enhanced cancer therapy via responding or modulating the tumor microenvironment (TME) has attracted tremendous interests in the field of nanomedicine. Herein, tungsten disulfide (WS₂) nanoflakes with their surface adsorbed with iron oxide nanoparticles (IONPs) via self‐assembly are coated with silica and then subsequently with manganese dioxide (MnO₂), on to which polyethylene glycol (PEG) is attached. The obtained WS₂‐IO/S@MO‐PEG appears to be highly sensitive to pH, enabling tumor pH‐responsive magnetic resonance imaging with IONPs as the pH‐inert T2 contrast probe and MnO₂ as the pH‐sensitive T1 contrast probe. Meanwhile, synergistic combination tumor therapy is realized with such WS₂‐IO/S@MO‐PEG, by utilizing the strong near‐infrared light and X‐ray absorbance of WS₂ for photothermal therapy (PTT) and enhanced cancer radiotherapy (RT), respectively, as well as the ability of MnO₂ to decompose tumor endogenous H₂O₂ and relieve tumor hypoxia to further overcome hypoxia‐associated radiotherapy resistance. The combination of PTT and RT with WS₂‐IO/S@MO‐PEG results in a remarkable synergistic effect to destruct tumors. This work highlights the promise of developing multifunction nanocomposites for TME‐specific imaging and TME modulation, aiming at precision cancer synergistic treatment.     

Multifunctional Magnetic Gd3+‐Based Coordination Polymer Nanoparticles: Combination of Magnetic Resonance and Multispectral Optoacoustic Detections for Tumor‐Targeted Imaging in vivo

To overcome traditional barriers in optical imaging and microscopy, optoacoustic‐imaging has been changed to combine the accuracy of spectroscopy with the depth resolution of ultrasound, achieving a novel modality with powerful in vivo imaging. However, magnetic resonance imaging provides better spatial and anatomical resolution. Thus, a single hybrid nanoprobe that allows for simultaneous multimodal imaging is significant not only for cutting edge research in imaging science, but also for accurate clinical diagnosis. A core‐shell‐structured coordination polymer composite microsphere has been designed for in vivo multimodality imaging. It consists of a Fe₃O₄ nanocluster core, a carbon sandwiched layer, and a carbocyanine‐Gd^III (Cy‐Gd^III) coordination polymer outer shell (Fe₃O₄@C@Cy‐Gd^III). Folic acid‐conjugated poly(ethylene glycol) chains are embedded within the coordination polymer shell to achieve extended circulation and targeted delivery of probe particles in vivo. Control of Fe₃O₄ core grain sizes results in optimal r₂ relaxivity (224.5 × 10^–3 m ⁻¹ s^‐1) for T₂‐weighted magnetic resonance imaging. Cy‐Gd^III coordination polymers are also regulated to obtain a maximum 25.1% of Cy ligands and 5.2% of Gd^III ions for near‐infrared fluorescence and T₁‐weighted magnetic resonance imaging, respectively. The results demonstrate their impressive abilities for targeted, multimodal, and reliable imaging.