基于香豆素343的荧光探针快速检测亚硫酸根

以香豆素343和2-苯并噻唑乙腈为原料,合成了香豆素343-亚硫酸根离子探针(Coumarin 343-SO₂),并用¹H NMR、¹³C NMR、MS和HRMS等技术手段对合成的化合物进行了表征。 该探针与亚硫酸根离子(SO₃^2-)发生亲核加成反应后,阻断了苯并噻唑与香豆素的共轭结构,从而引起荧光强度的变化,达到检测亚硫酸根离子的目的。 此探针对SO₃^2-具有响应快、高灵敏度、高选择性及检测限低至0.08 μmol/L的特点,其它常见的阴离子及还原性物质对SO₃^2-的检测均无干扰。 此外,该探针具有良好的细胞膜通透性,可用于活细胞中对SO₃^2-进行荧光成像。     

一种用于检测气态甲醛的新型荧光探针

甲醛是一种常见的挥发性有机物（VOC）,当其浓度达到一定水平时,会对人体健康产生危害,如刺激眼和鼻黏膜、引起咽喉疼痛、咳嗽和气喘等。长期接触甲醛会对人体造成严重损害。为此,我们设计合成了一种荧光探针TF（4-肼基-1,8-萘基-1,2-苯并咪唑）,TF的肼基团可以识别甲醛,并通过与甲醛的羰基部分缩合形成腙的反应实现甲醛的检测。TF显示出较高的灵敏性和选择性。此外,为了直接检测气态的甲醛,我们利用TF制备了荧光试纸,探究其在甲醛定性检测中的应用,同时还探究了一种简易监测装置用于室内甲醛的定量测量。     

香豆素类阴离子荧光探针的研究进展

香豆素是一种重要的天然产物,同时具有优良的生物活性和光学活性.阴离子广泛存在于生命体和自然环境中,对人类的生活有着巨大的影响,因此开发能够特异性检测某种阴离子的荧光探针具有非常重要的科学意义.主要总结了近几年香豆素类阴离子荧光探针的研究进展,重点讨论了检测F-、ClO-、ONOO-以及一些其他阴离子的香豆素类荧光探针的...     

基于香豆素荧光团的新型极性检测荧光探针的开发及其成像应用

极性是生物微环境的重要参数之一, 在很大程度上, 生物体内许多生命活动都受到极性变化的影响, 本工作通过改变香豆素母体上的推-拉电子基团, 设计并合成了一种具有较大斯托克斯位移的新型极性荧光探针COM-PO, 该探针的荧光强度和波长会随着测试体系的极性变化而发生改变. 当极性增加时, COM-PO的激发态能量会通过偶极-偶极的相互作用散失在溶剂中, 荧光发射强度降低, 而在低极性溶剂中荧光发射强度增强, 利用这种特性实现了对极性的检测. 本工作通过荧光光谱、荧光成像实验表明COM-PO能够在样品中实现极性检测, 该探针有望实现与极性相关的疾病的早期诊断.     

有机小分子荧光探针对甲醛的识别及其应用

甲醛不仅用作工业化学品,也是调节人体生理活动的必要代谢产物。但是,人体从外环境过量的摄入甲醛或者内环境甲醛代谢的不平衡,会造成器官癌变和老年痴呆等重大疾病。有机小分子荧光探针以其高灵敏度、高选择性、可视化和原位检测等特点,使其在生物体内外甲醛检测和生物成像领域具有应用优势,同时也为实际产品中甲醛的痕量检测提供一种新方法。近五年来,甲醛荧光探针得到了快速的发展。本文主要从甲醛荧光探针的反应类型、生物体中甲醛的荧光成像以及在实际样品(商品)检测应用三个方面,介绍有机小分子荧光探针对甲醛的识别和应用。最后总结指出,不同类型的有机小分子荧光探针在不断开发、结构优化和光学性能提升及满足辅助生物医学方向长期性研究的同时,也能拓展应用范围,达到短期内对实际产品中甲醛快速(原位)检测的目的。     

用于检测细胞内谷胱甘肽的比率型荧光探针

设计合成了1种用于检测生物巯基的比率型荧光探针(4),并考察了其对谷胱甘肽的识别作用.在4-羟乙基哌嗪乙磺酸(HEPES)缓冲液中,探针4可与谷胱甘肽快速反应,溶液颜色由淡黄色变为粉红色,从而实现"裸眼"检测,且在608 nm处的荧光信号增强.在1.6×10-5~2×10-4mol/L范围内,探针4能够定量检测谷胱甘肽,检出限为8.9×10-7mol/L.此外,探针4还可用于MCF-7细胞中谷胱甘肽的成像.     

香豆素衍生物荧光探针研究进展

对近5年来设计合成的新型香豆素荧光探针研究进展进行综述.系统阐述合成新型香豆素荧光探针在生物学领域的应用,主要包括检测内源性物质、监测细胞结构形态、对重金属离子的定性定量分析等.香豆素母核的活性位点多样,适于结构修饰,基于香豆素荧光探针对7、8位的活性位点进行改造,得到一系列新型香豆素衍生物荧光探针.通过对此类荧光传感...     

基于香豆素的比率型次氯酸荧光探针

次氯酸(HCl O)是生物体内重要的活性氧(ROS)之一,在人类免疫功能系统中扮演着重要的角色,有助于对入侵细菌和病原体进行破坏。本文设计并合成了基于香豆素为母体单元的比率型次氯酸荧光探针。研究结果表明,该探针对次氯酸识别显示出较高的选择性,检测线低至12 mol/L,荧光响应可在5 s内迅速完成,并伴随着溶液颜色由无色转变为黄绿色。其它常见的阴离子及氧化型物质对次氯酸检测均无干扰。此外,高分辨率质谱、荧光光谱和紫外可见光谱变化共同证实了该探针对次氯酸的检测机制为次氯酸对探针氧化水解。     

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.     

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.     

Development of a Two‐Photon Fluorescent Probe for Imaging of Endogenous Formaldehyde in Living Tissues

Investigation of the physiological and pathological functions of formaldehyde (FA) are largely restricted by a lack of useful FA imaging agents, in particular, those that allow detection of FA in the context of living tissues. Herein, we present the rational design, synthesis, and photophysical property studies of the first two‐photon fluorescent FA probe, Na‐FA . Importantly, the highly desirable attributes of the probe Na‐FA (such as a very large turn‐on signal (up to 900‐fold), a low detection limit, and a very fast onset imparted by the unique design aspects of the probe), make it possible to monitor endogenous FA in living tissues for the first time. Furthermore, sodium bisulfite was identified as a simple and convenient inhibitor of FA within biological environments.     

A Golgi Apparatus-Targeting,Naphthalimide-Based Fluorescent Molecular Probe for the Selective Sensing of Formaldehyde

Formaldehyde (FA) is a colorless, flammable, foul-smelling chemical used in building materials and in the production of numerous household chemical goods. Herein, a fluorescent chemosensor for FA is designed and prepared using a selective organ-targeting probe containing naphthalimide as a fluorophore and hydrazine as a FA-binding site. The amine group of the hydrazine reacts with FA to form a double bond and this condensation reaction is accompanied by a shift in the absorption band of the probe from 438 nm to 443 nm upon the addition of FA. Further, the addition of FA is shown to enhance the emission band at 532 nm relative to the very weak fluorescent emission of the probe itself. Moreover, a high specificity is demonstrated towards FA over other competing analytes such as the calcium ion (Ca²⁺), magnesium ion (Mg²⁺), acetaldehyde, benzaldehyde, salicylaldehyde, glucose, glutathione, sodium sulfide (Na₂S), sodium hydrosulfide (NaHS), hydrogen peroxide (H₂O₂), and the tert-butylhydroperoxide radical. A typical two-photon dye incorporated into the probe provides intense fluorescence upon excitation at 800 nm, thus demonstrating potential application as a two-photon fluorescent probe for FA sensing. Furthermore, the probe is shown to exhibit a fast response time for the sensing of FA at room temperature and to facilitate intense fluorescence imaging of breast cancer cells upon exposure to FA, thus demonstrating its potential application for the monitoring of FA in living cells. Moreover, the presence of the phenylsulfonamide group allows the probe to visualize dynamic changes in the targeted Golgi apparatus. Hence, the as-designed probe is expected to open up new possibilities for unique interactions with organ-specific biological molecules with potential application in early cancer cell diagnosis.     

超快速turn-on型ClO-荧光探针的合成及性能

为实现次氯酸根的实时、快速、便捷检测,我们以2,7-二溴-9-芴酮为原料,通过两步常规反应,合成了一种新型的turn-on型ClO^-荧光探针。在磷酸缓冲盐溶液（PBS）中,随着ClO^-浓度的增大,探针在511 nm的发射峰逐渐增大,呈绿色荧光发射。探针与ClO^-反应迅速,10 s内反应完成。此外,该探针对ClO^-有较低的检出限,检出限为0.74 μmol·L^-1。细胞实验表明探针可以在细胞水平检测内源性和外源性的ClO^-。     

A BODIPY‐based Fluorescent Probe for Thiophenol

Thiophenol has been listed as one of the main sources of pollution. Sensitive probes for thiophenol are very significant. Herein, a BODIPY‐based fluorescent probe, named BDP, for poisonous thiophenol detection has been reported. BDP shows rapid response (15 s) and clear fluorescence enhancement (30 folds) to thiophenol in solution. The intensity of fluorescence and concentration of thiophenol have a good linear relationship. The detection limit is as low as 13.6 nmol · L⁻¹. BDP is stable towards pH and light radiation. Cell experiments demonstrate that BDP has good cell membrane penetrability, low cell toxicity and excellent imaging properties in living cells. Therefore, BDP has significant value on the detection of thiophenol in solution and in living cell.     

A New Phenylazo-Based Fluorescent Probe for Sensitive Detection of Hypochlorous Acid in Aqueous Solution

In this paper, we designed and synthesized a novel phenylazo-based fluorescent probe (RHN) for the sensing and imaging of hypochlorous acid (HClO) in mitochondria in living cells. In this process, HClO promoted the oxidation of the phenylazo group to generate a free Rhodol fluorophore moiety, which in turn restored strong fluorescence and realized the detection of HClO. As expected, RHN exhibited high selectivity, high sensitivity and rapid response, with detection limits as low as 22 nM (1.155 ng/mL). Importantly, the results of the cell imaging experiments indicated that RHN has the ability to image and sense HClO in mitochondria, which is of great significance for exploration of the specific role of HClO in both the immune system and diseases.     

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。     

一种基于苯并噁唑类的可视化检测汞离子的荧光探针

设计合成了一种用于检测Hg²⁺的苯并噁唑类荧光探针4-(苯并[d]噁唑-2-基)-2-((二(2-(乙巯基)乙基)氨基)甲基)苯酚(ZY1), 用质谱、核磁氢谱和X射线单晶衍射等方法对其进行了结构表征, 并考察了其光谱性能. 研究结果表明, ZY1对Hg²⁺有较高的选择性和灵敏度, 它们之间的结合比为1:1, 共存离子及pH值(3.0～9.0)对其测定影响小. ZY1能够可视化检测Hg²⁺, 并在HeLa活细胞中实现了汞离子的成像, 这对检测生物体内的Hg²⁺将具有潜在的应用价值.     

选择性检测谷胱甘肽的荧光探针

本文设计合成了一种基于BODIPY衍生物选择性检测谷胱甘肽的比率式荧光探针1。荧光探针1中BODIPY的3位连有苯乙炔基团,5位连有咪唑盐离去基团,利用其与谷胱甘肽和半胱氨酸反应机理的不同实现了对谷胱甘肽的选择性检测。紫外可见吸收光谱和荧光光谱实验结果表明探针分子1与谷胱甘肽反应后的光谱发生明显红移,可以实现对谷胱甘肽的比率式检测。探针分子1对谷胱甘肽有极高的选择性,不受其它氨基酸尤其是半胱氨酸的干扰。荧光滴定实验表明探针分子1可实现对谷胱甘肽的定量检测,检测限为3.3×10-8 mol/L。探针分子成功地应用于活体细胞中检测谷胱甘肽。     

新型香豆素类氟离子荧光探针的合成及细胞成像研究

设计合成了一类基于分子内电荷转移（Intramolecular Charge Transfer,ICT）的香豆素类F^-荧光探针CS1,CS2和CS3,经¹H NMR,¹³C NMR,IR和HRMS表征了相应探针的结构,并解析了探针CS3的晶体结构.通过核磁和质谱实验验证了探针与F^-的作用机理是氟化物脱硅基.光谱分析实验结果显示,CS1,CS2和CS3均具有较好的选择性和灵敏度,且均能成功实现人乳腺癌细胞（MCF^-7）中F^-的检测.