基于苯并吡喃腈-香豆素体系的近红外比率型荧光探针用于检测He La细胞中的过氧亚硝酸盐(英文)

过氧亚硝酸根(ONOO-)是生物体内的一种重要的活性氧,与人体内的各种生理活动息息相关.利用苯并吡喃腈-香豆素体系,合成了一种用于ONOO-检测的近红外比率型荧光探针(E)-7-(二乙胺基)-3-(2-(苯并吡喃腈)乙烯基)-香豆素(DCCM).该探针在ONOO-存在下表现出强烈的响应,颜色从紫色变为浅粉色,最大发射峰蓝移217nm,荧光颜色从淡紫色变为蓝色,能够直观地对溶液中的ONOO-进行监测. DCCM可以灵敏地检测ONOO^-,最低检测限为6.0×10^-7 mol·L^-1,该探针被成功用于HeLa细胞中的ONOO-成像检测.     

Multiplex Detection of Enzymatic Activity with Responsive Lanthanide‐Based Luminescent Probes

Multiplex analyte detection in complex dynamic systems is desirable for the investigation of cellular communication networks as well as in medical diagnostics. A family of lanthanide‐based responsive luminescent probes for multiplex detection is reported. The high modularity of the probe design enabled the rapid assembly of both green and red emitters for a large variety of analytes by the simple exchange of the lanthanide or an analyte‐cleavable caging group, respectively. The real‐time three‐color detection of up to three analytes was demonstrated, thus setting the stage for the non‐invasive investigation of interconnected biological processes.     

A Ratiometric Luminescent Thermometer Co‐doped with Lanthanide and Transition Metals

Herein, we report the fabrication of a sensitive ratiometric and colorimetric luminescent thermometer with a wide operating‐temperature range, from cryogenic temperatures up to high temperatures, through the combination of lanthanide and transition metal complexes. Benefiting from the transition metal complex as a self‐reference, the lanthanide content in the mixed‐coordination complex, Eu_0.05(Mebip‐mim bromine)_0.15Zn_0.95(Mebip‐mim bromine)_1.9, was lowered to 5 %.     

An Activatable Lanthanide Luminescent Probe for Time‐Gated Detection of Nitroreductase in Live Bacteria

Herein we report the development of a turn‐on lanthanide luminescent probe for time‐gated detection of nitroreductases (NTRs) in live bacteria. The probe is activated through NTR‐induced formation of the sensitizing carbostyril antenna and resulting energy transfer to the lanthanide center. This novel NTR‐responsive trigger is virtually non‐fluorescent in its inactivated form and features a large signal increase upon activation. We show that the probe is capable of selectively sensing NTR in lysates as well as in live bacteria of the ESKAPE family which are clinically highly relevant multiresistant pathogens responsible for the majority of hospital infections. The results suggest that our probe could be used to develop diagnostic tools for bacterial infections.     

Polynuclear SmIII Polyamidoamine‐Based Dendrimer: A Single Probe for Combined Visible and Near‐Infrared Live‐Cell Imaging

We report herein the synthesis of a luminescent polynuclear dendritic structure (Sm^III‐G3P‐2,3Nap) in which eight Sm^III ions are sensitized by thirty‐two 2,3‐naphthalimide chromophores. Upon a single excitation wavelength, the dendrimer complex exhibits two types of emission in the visible and in the near‐infrared (NIR) ranges. Sm^III‐G3P‐2,3Nap was non‐cytotoxic after 24 h of incubation and up to 2.5 μM . The ability of the Sm^III‐based probe to be taken up by cells was confirmed by confocal microscopy. Epifluorescence microscopy validated Sm^III‐G3P‐2,3Nap as a versatile probe, capable of performing interchangeably in the visible or NIR for live‐cell imaging. As both emissions are obtained from a single complex, the cytotoxicity and biodistribution are inherently the same. The possibility for discriminating the sharp Sm^III signals from autofluorescence in two spectral ranges increases the reliability of analysis and reduces the probability of artifacts and instrumental errors.     

一种基于苯并噻唑的新型过氧亚硝酸盐荧光探针的合成及应用

该文以2-(2′-羟基-3′-醛基-5′-甲基苯基)苯并噻唑和1,1-二甲基肼为原料,通过一步缩合,简单过滤处理得到一种基于苯并噻唑的新型ONOO^-荧光探针BD。但由于N—N单键旋转产生非辐射能量损失,探针BD荧光较弱。在引入ONOO^-后,探针BD上的腙水解成醛基,N—N单键脱落,荧光增强,同时可观察到明显的颜色变化。在PBS缓冲溶液(DMSO∶H₂O=2∶8,体积比,pH 7.4)中,探针BD对ONOO^-具有快速响应(25 s)、高灵敏度(7 nmol/L)和高选择性的特点,可在较宽pH值范围内工作。此外,探针BD还成功地用于肝癌细胞中ONOO^-的荧光成像,因此,可作为揭示ONOO^-在细胞中作用的一个很有潜力的分析工具。     

Nanometrization of Lanthanide‐Based Coordination Polymers

Heteronuclear lanthanide‐based coordination polymers are microcrystalline powders, the luminescence properties of which can be precisely tuned by judicious choice of the rare‐earth ions. In this study, we demonstrate that such materials can also be obtained as stable solutions of nanoparticles in non‐toxic polyols. Bulk powders of the formula [Ln_2?2xLn′_2x(bdc)₃ ? 4 H₂O]_∞ (where H₂bdc denotes 1,4‐benzene‐dicarboxylic acid, 0≤x≤1, and Ln and Ln′ denote lanthanide ions of the series La to Tm plus Y) afford nanoparticles that have been characterized by dynamic light‐scattering (DLS) and transmission electron microscopy (TEM) measurements. Their luminescence properties are similar to those of the bulk materials. Stabilities versus time and versus dilution with another solvent have been studied. This study has revealed that it is possible to tune the size of the nanoparticles. This process offers a reliable means of synthesizing suspensions of nanoparticles with tunable luminescence properties and tunable size distributions in a green solvent (glycerol). The process is also extendable to other coordination polymers and other solvents (ethylene glycol, for example). It constitutes a new route for the facile solubilization of lanthanide‐based coordination polymers.     

Oligonucleotide‐Based Luminescent Detection of Metal Ions

Metal ions are prevalent in biological systems and are critically involved in essential life processes. However, excess concentrations of metals can pose a serious danger to living organisms. Oligonucleotides represent a versatile sensing platform for the detection of various molecular entities including metal ions. This review summarizes the recent advances in the development of oligonucleotide‐based luminescent detection methods for metal ions.     

A Two-Photon Fluorescent Probe for the Visual Detection of Peroxynitrite in Living Cells and Zebrafish

Peroxynitrite (ONOO⁻), as an important reactive oxygen species (ROS), holds great potential to react with a variety of biologically active substances, leading to the occurrence of various diseases such as cancer and neurodegenerative diseases. In this work, we developed a novel mitochondria-localized fluorescent probe, HDBT-ONOO⁻, which was designed as a mitochondria-targeting two-photon fluorescence probe based on 1,8-naphthylimide fluorophore and the reactive group of 4-(bromomethyl)-benzene boronic acid pinacol ester. More importantly, the probe exhibited good biocompatibility, sensitivity, and selectivity, enabling its successful application in imaging the generation of intracellular and extracellular ONOO⁻. Furthermore, exogenous and endogenous ONOO⁻ products in live zebrafish were visualized. It is greatly expected that the designed probe can serve as a useful imaging tool for clarifying the distribution and pathophysiological functions of ONOO⁻ in cells and zebrafish.     

A Single‐Wavelength‐Emitting Ratiometric Probe Based on Phototriggered Fluorescence Switching of Graphene Quantum Dots

Ratiometric fluorescent probes are of great importance in research, because a built‐in correction for environmental effects can be provided to reduce background interference. However, the traditional ratiometric fluorescent probes require two luminescent materials with different emission bands. Herein a novel ratiometric probe based on a single‐wavelength‐emitting material is reported. The probe works by regulating the luminescent property of graphene quantum dots with UV illumination as activator. The ratiometric sensor shows high sensitivity and specificity for iron ions. Moreover, the ratiometric sensor was successfully employed to monitor ferritin levels in Sprague Dawley rats with chemical‐induced acute liver damage. The proposed single‐wavelength ratiometric fluorescent probe may greatly broaden the applicability of ratiometric sensors in diagnostic devices, medical applications, and analytical chemistry.     

Hydrophilic,Upconverting, Multicolor,Lanthanide‐Doped NaGdF4 Nanocrystals as Potential Multifunctional Bioprobes

Monodisperse water‐soluble hexagonal phase Ln³⁺‐doped NaGdF₄ upconverting nanocrystals (UCNCs) have been successfully fabricated by means of a fast, facile, and environmentally friendly microwave‐assisted route with polyethylenimine as the surfactant. Fine‐tuning of the UC emission from visible to near‐IR and finally to white light has been achieved. Furthermore, studies of the magnetic resonance imaging as well as the magnetization (magnetization–magnetic field curves) and the targeted recognition properties of FA‐coupled amine‐functionalized NaGdF₄@SiO₂ UCNCs indicate that the obtained NaGdF₄ UCNCs can be potential candidates for dual‐mode optical/magnetic bioapplications.     

A Promising MgII‐Ion‐Selective Luminescent Probe: Structures and Properties of Dy–Mn Polymers with High Symmetry

Two Dy–Mn polymers, {[Dy(L¹)₃Mn_1.5(H₂O)₃]?3.125 H₂O}_n ( 1 , L¹=pyridine‐2,6‐dicarboxylic acid) and {[Dy(L²)₃Mn_1.5(H₂O)₆]?8.25 H₂O}_n ( 2 , L² = 4‐hydroxylpyridine‐2,6‐dicarboxylic acid), with high symmetry (S₆) have been prepared. Polymer 1 has a nanoporous 3D framework with channel of about 17.6 Å diameter, while 2 has a honeycomb‐type 2D structure with the cavity of approximately 14.4 Å diameter. In the construction of multidimensional porous polymers with 3d–4f mixed metals, it is the first observation that a ligand substituent effect leads to dramatic differences in the structures formed. Luminescent studies reveal that the emission intensities of 1 and 2 increase significantly upon the addition of Mg²⁺, whereas the introduction of other metal ions leaves the intensity unchanged or even weakens it; hence, both of them may serve as good candidates of Mg²⁺ luminescent probes. To our knowledge, complex 1 is also the first example of a 3d–4f metal‐based nanoporous polymer to exhibit luminescent selectivity for Mg²⁺. Magnetic susceptibility measurements reveal a rather rare ferromagnetic interaction in 2 . Thermal gravimetric analyses and powder X‐ray diffraction investigations have also been performed, suggestive of high thermal stability of 1 .     

Luminescent Bimetallic Lanthanide Bioprobes for Cellular Imaging with Excitation in the Visible‐Light Range

A series of homoditopic ligands H₂L^CX (X=4–6) has been designed to self‐assemble with lanthanide ions (Ln^III), resulting in neutral bimetallic helicates of overall composition [Ln₂(L^CX)₃] with the aim of testing the influence of substituents on the photophysical properties, particularly the excitation wavelength. The complex species are thermodynamically stable in water (log β₂₃ in the range 26–28 at pH 7.4) and display a metal‐ion environment with pseudo‐D₃ symmetry and devoid of coordinated water molecules. The emission of Eu^III, Tb^III, and Yb^III is sensitised to various extents, depending on the properties of the ligand donor levels. The best helicate is [Eu₂(L^C5)₃] with excitation maxima at 350 and 365 nm and a quantum yield of 9 %. The viability of cervix cancer HeLa cells is unaffected when incubated with up to 500 μm of the chelate during 24 h. The helicate permeates into the cells by endocytosis and locates into lysosomes, which co‐localise with the endoplasmatic reticulum, as demonstrated by counterstaining experiments. The relatively long excitation wavelength allows easy recording of bright luminescent images on a confocal microscope (λ_exc=405 nm). The new lanthanide bioprobe remains undissociated in the cell medium, and is amenable to facile derivatisation. Examination of data for seven Eu^III and Tb^III bimetallic helicates point to shortcomings in the phenomenological rules of thumb between the energy gap ΔE(³ππ*–⁵D_J) and the sensitisation efficiency of the ligands.     

Lanthanide‐Based Functional Misfit‐Layered Nanotubes

The synthesis of nanotubes from layered compounds has generated substantial scientific interest. “Misfit” layered compounds (MLCs) of the general formula [(MX)_1+x]_m[TX₂]_n, where M can include Pb, Sb, rare earths; T=Cr, Nb, and X=S, Se can form layered structures, even though each sub‐system alone is not necessarily a layered or a stable compound. A simple chemical method is used to synthesize these complex nanotubes from lanthanide‐based misfit compounds. Quaternary nanotubular structures formed by partial substitution of the lanthanide atom in nanotubes by other elements are also confirmed. The driving force and mechanism of formation of these nanotubes is investigated by systematic temperature and time‐dependent studies. A stress‐inducement mechanism is proposed to explain the formation of the nanotubes. The resulting materials may find applications in fields that include thermoelectrics, light emitters, and catalysis and address fundamental physical issues in low dimensions.     

Preparation and Properties of Transparent Ultrathin Lanthanide‐Complex Films

Highly transparent ultrathin films (UTFs) based on alternative layer‐by‐layer assembly of Eu‐ and Tb‐based lanthanide complexes (LCs) and Mg–Al‐layered double hydroxide (LDH) nanosheets are reported herein. UV–visible absorption and fluorescence spectroscopy showed an orderly growth of the two types of ultrathin films upon increasing the number of deposition cycles. AFM and SEM measurements indicate that the films feature periodic layered structures as well as uniform surface morphology. Luminescent investigations reveal that (LCs/LDH)_n UTFs can detect Fe³⁺ with relative selectivity and high sensitivity (Stern–Volmer constant K_SV=8.43×10³ L mol^?1); this suggests that (LCs/LDH)_n UTFs could be a promising luminescent probe for selectively sensing Fe³⁺ ion.