"Three-in-One" Nanozyme Composite for Augmented Cascade Catalytic Tumor Therapy.

Cascade catalytic reaction exhibits simple procedure and high efficiency, such as that from the orderly assembly of different enzymes in biological systems. Mimicking of the natural cascade procedure becomes critical, but the orderly assembly of different enzymes is still challenging. Herein, single Au-Pt nanozyme is reported with "three-in-one" functions to initiate cascade conversions for O2 supply as mimic catalase, H2 O2 production with its glucose oxidase-like property, and • OH generation as mimic peroxidase for chemodynamic therapy (CDT). Thus, the complex assembly and cross-talk among the different enzymes are avoided. To this end, metastable Cu2 O NPs, as scaffolds, are used to anchor ultrasmall Au-Pt nanozyme, while metal-organic framework (MOF) is used to encapsulate the nanozyme for tumor microenvironment response and shielding protein adsorption. Pluronic F127 is then modified on the surface to improve hydrophilicity and biocompatibility of the composite. The endogenous acidity and glutathione in tumor degrade MOF to expose nanozyme for cascade catalytic CDT. The high photothermal conversion ability also enhances the CDT, while Cu2+ ions consume GSH to further improve CDT efficiency as augmented cascade catalytic tumor therapy. Thus, a new paradigm is provided with drug-free single nanozyme for improving tumor therapeutic efficacy and minimizing side effects.

Rational design of dual-ligand Eu-MOF for ratiometric fluorescence sensing Cu2+ ions in human serum to diagnose Wilson's disease.

Copper levels in body fluids provide an important reference for the diagnosis of Wilson's disease, which associated with blood abnormalities, kidney and cardiovascular disease, and neuropathy. Metal-organic frameworks (MOF) can easily realize dual-emission from single excitation as ratiometric fluorescence sensing and visible detection platform with the intensity ratio of two emissions for simple, rapid, sensitive, and specific analysis of biological samples. Here, we rationally designed a dual-emission Eu-MOF with dual-ligand strategy, denoted as Eu-DATA/BDC. While terephthalic acid (H2BDC) was selected to sensitize Eu3+ ions for the antenna effect emission, 2,5-diaminoterephthalic acid (H2DATA) maintained its own emission and was used to identify Cu2+ ions. Thus, dual-emission from Eu-DATA/BDC and specific recognition of Cu2+ ions were realized for ratiometric sensing of Cu2+ ions. A wide linear concentration range (1-40 µM), low detection limit (0.15 µM), and fast response (less than 10 s) were realized. The color change also achieved the visible detection by naked eye. Copper levels were tested with human serum samples and compared to the ICP-OES results, confirmed the potential of Eu-DATA/BDC probe in the diagnosis of Wilson's disease. The response mechanism to Cu2+ ions was proposed as electron transfer between host and guest for fluorescence quenching. Thus, dual-ligand is a simple and efficient strategy to prepared dual-emission Eu-MOF for the ratiometric sensing and visible detection.

Design and Multiple Applications of Mixed-Ligand Metal-Organic Frameworks with Dual Emission.

Herein, we revealed the factors that affect the emission in mixed-ligand metal-organic frameworks (MOFs) with the combination of terephthalic acid (BDC), 2-aminoterephthalic acid (BDC-NH2), and 2,5-dihydroxylterephthalic acid [BDC-(OH)2] as models. The -NH2 and -(OH)2 groups change the π-conjugation and luminescence behaviors than BDC, so the ligands show different optical behaviors. The Zn2+ ion with a 3d10 full electronic structure shows little effect on the emission of the ligand and is selected as the metal node. We found that the emission of BDC is weak and incompatible to that of BDC-NH2, so only the emission of BDC-NH2 was observed in the BDC/BDC-NH2-MOF. Crosstalk occurs between the emissions from BDC and BDC-(OH)2 for the single emission from BDC/BDC-(OH)2-MOFs, even different ratios are selected. The MOFs prepared with BDC-NH2 and BDC-(OH)2 show dual emission at 450 and 550 nm, while the relative intensity was easily tuned with the ligand ratio and excitation wavelength. Thus, abundant optical behaviors and extensive applications were realized, including but not limited to (1) dual emission from single MOFs, (2) tunable color from blue to yellow with the excitation from 290 to 370 nm for information encryption and decryption, (3) white emission obtained under an excitation of 330 nm, and (4) response of -NH2 groups to HCHO and Fe3+ ions for ratiometric fluorescence sensing and visual detection. This work revealed the factors that affect the emission in mixed-ligand MOFs, studied their optical behaviors, and realized different applications with single MOFs.

Triple cascade nanocatalyst with laser-activatable O2 supply and photothermal enhancement for effective catalytic therapy against hypoxic tumor.

Nanozymes have been combined with glucose oxidase (GOx) for dual-enzyme cascade catalytic therapy. However, their catalysis efficiency is restricted because of the hypoxia tumor microenvironment (TME). Although many methods are developed for O2 supply, the O2 leakage and consumption of H2O2 compromised their practical application. Herein, a biocompatible carbon nitride (C3N4)/nanozyme/GOx triple cascade nanocatalyst was designed with laser-activatable O2 self-supply via water splitting to relieve tumor hypoxia and thus improve the catalysis efficiency. To this end, polydopamine (PDA) nanosphere was prepared and attached with C3N4 nanosheet to improve water splitting efficiency and realize photothermal-enhanced catalysis, simultaneously. The PDA@C3N4 composite was then coated with MIL-100 (Fe), where GOx was loaded, to form C3N4/MIL-100/GOx triple cascade nanocatalyst. The triple cascade catalysis was realized with laser-activatable O2 supply from PDA@C3N4, H2O2 generation with GOx, and •OH production from peroxidase-like MIL-100 (Fe) for tumor therapy. Upon 808 nm irradiation, PDA, as a photothermal agent, realized photothermal therapy and enhanced the catalytic therapy. Thus, the synergy of laser-activatable O2 supply and photothermal enhancement in our triple cascade nanocatalyst improved the performance of catalytic therapy without drug resistance and toxicity to normal tissues.

Construction of NaYF4 Library for Morphology-Controlled Multimodality Applications.

Morphology and size of the nanoparticles are highly related to the properties; establishing a library to summarize the relationship between the morphology/size and property is very helpful for associated applications. However, the NaYF4 library and thus the correlation between the morphology and property are still absent. Here NaYF4 library is presented and their morphologies and structures are illustrated at atomic scale for the first time. How about the crystal formation affects the morphology is further used to guide the property. Through rational doping, upconversion luminescence, magnetic resonance (MR) and computed tomography are investigated with the nanoprisms, nanoflowers, and nanoplates as models to reveal the effect of the size and morphology. The difference of the properties provides strong evidence on the importance of the library. In particular, the "imperfect structure" of nanoflower is observed on atomic scale and enhances the MR response. The different upconversion intensity ratio for the emissions at 475 and 693 nm is observed from doped NaYF4 with different morphology. Thus, controllable fabrication of NaYF4 with desired morphology is indispensable to achieve the optimal properties as the guidance on how to choose matrix from the library to meet the specific applications.

Dual-Ligand Lanthanide Metal-Organic Framework for Sensitive Ratiometric Fluorescence Detection of Hypochlorous Acid.

Sensitivity, selectivity, visible detection, and rapid response are the main concerns for an analytical method. Herein, we reported a metal-organic framework (MOF)-based ratiometric fluorescence detection strategy for hypochlorous acid (HClO). The MOF was prepared with dual ligands, 2-aminoterephthalic acid (BDC-NH2) and dipicolinic acid (DPA) and Eu3+ ions as a metal node, denoted as Eu-BDC-NH2/DPA. The dual-ligand strategy realized the dual emission for ratiometric sensing and visual detection, adjusted the size and morphology of MOFs to obtain a good dispersion for a rapid response, and provided an amino group for the special recognition of HClO. Thus, the MOF exhibited a dual emission derived from BDC-NH2 and Eu3+ ions at 433 and 621 nm, respectively, under a single excitation at 270 nm. A hydrogen bond forms between an -NH2 group and HClO to weaken the blue fluorescence at 433 nm, while the antenna effect emission from Eu3+ ions kept stable, so ratiometric sensing was realized with an easy-to-differentiate color change for visible detection. The ratiometric sensing showed a self-calibration effect and reduced the background. Thus, the high sensitivity, visual detection, low detection limit (37 nM), and short response time (within 20 s) for the detection of HClO were realized with the MOF as a probe. The analysis of real samples demonstrated the practical application of the MOF for HClO. The introduction of mixed ligands is an effective strategy to regulate the emission behaviors of MOFs for the improved analytical performance.

[Experience in overlay tympanoplasty].

OBJECTIVE: To explore the experience and value of overlay tympanoplasty. METHODS: Sixty-three ears with overlay tympanoplasty were reviewed and followed up for the external auditory canal, tympanic membrane and hearing. RESULTS: The diseases of the patients included middle ear cholesteatoma in 25 ears and chronic suppurative otitis media in 38 ears. The surgical techniques involved three kinds: overlay tympanoplasty, overlay tympanoplasty with canal wall up mastoidectomy and overlay tympanoplasty with canal wall down mastoidectomy. In middle ear cholesteatoma and suppurative otitis media patients, the case received the three techniques are 4, 17, 4 ears and 19, 18, 1 ears respectively. All patients gained stage I incision cure. Followed up for 0.5 to 3.5 years respectively, the external auditory canal was wide and tympanic membrane gained a good shape. The hearing in all case kept intact or increased while hearing decrease did not occur. Complications were free in patients with punctual visit. CONCLUSIONS: Overlay tympanoplasty has positive significance in treating the chronic otitis media with the merits of standard procedure, sufficient operative field and thorough erosion elimination.