一锅法可控合成金属有机框架材料Mn-荧光素用于核磁共振/荧光成像（英文）

通过一锅法,首次将核磁共振成像试剂Mn~(2+)和荧光成像试剂荧光素(FSD)自组装于一个简单的金属有机框架材料(MnFSD)上。实验结果表明,Mn-FSD的粒径可被控制在微纳米水平内并进行生物成像。体外和体内实验结果证实,Mn-FSD可在细胞和裸鼠中显示强绿色荧光。同时,Mn-FSD表现出较高的弛豫值(r_1=4.95 L·mmol~(-1)·s~(-1))。     

金属有机框架材料用于去除环境污染物研究进展

金属-有机框架(Metal-Organic Frameworks,MOFs)是以有机配体为连接体以及以金属离子或金属离子簇为节点,由配位键自组装形成的具有周期性结构的金属配位聚合物.自20世纪以来,MOFs的研究取得了突破性的进展.研究发现,MOFs不仅在光、电、磁、催化方面具有潜在的应用前景,而且在识别与交换、存储与吸附、化合物的选择性分离等方面也具有日益广泛的应用,正在发展成为一种新型多功能材料.近年来,研究人员对MOFs在吸附去除各种环境污染物机理和应用进行了较为系统深入的研究.本文就以下几方面进行阐述:MOFs对农药分子的吸附去除;水中有机染料分子与PPCPs(药物及个人护理产品)的吸附去除;水中重金属离子的吸附去除;大气中PMs(悬浮颗粒物)的吸附去除四个部分.     

羧酸类金属有机框架材料的合成及应用

金属-有机框架材料(Metal-Organic?Frameworks,简称MOFs)是由金属离子（簇）与有机桥接配体通过配位共价键或弱相互作用自组装形成的一类具有分子内孔隙的有机-无机杂化材料。羧酸类MOFs材料中金属中心和有机羧酸配体的可变性导致了其结构和功能的多样性,在气体的吸附与分离、荧光、传感、药物传输以及电催化等多个领域展现了独特的应用前景,并被认为是当今科学上最有前途的材料之一。对于有机配体的选择,从早期易坍塌的含氮杂环类配体过渡到了如今稳定性好的羧酸类配体,解决了不少以前出现的MOFs材料结构单一易坍塌问题。     

金属有机框架材料的研究进展

金属有机框架(metal-organic frameworks,MOFs)材料是一类由有机配体与金属中心经过自组装形成的具有可调节孔径的材料。与传统无机多孔材料相比,MOFs材料具有更大的比表面积,更高的孔隙率,结构及功能更加多样,因而已经被广泛应用于气体吸附与分离、传感器、药物缓释、催化反应等领域中。新兴材料的出现极大地促进了各个学科间的相互发展,本文综述了近年来MOFs材料的研究发展,包括MOFs材料自身的特点、国内外发展现状、应用领域以及复合MOFs材料的研究热点,并对今后的发展进行了展望。     

二维金属有机框架材料的合成及电催化应用

二维金属有机框架材料(MOFs)由于具备高比表面积、 多孔性以及丰富的活性位点等优异特性而受到广泛关注, 并且在电催化领域展现出巨大的应用潜力. 研究者们已在二维MOFs的可控制备与电催化性能调控方面取得许多突破性进展, 显示出相关研究对开发高性能电催化剂的关键作用. 本文总结了二维MOFs的自上而下和自下而上合成策略以及二维MOFs衍生物的典型合成方法, 概述了二维MOFs在各尺度下的电催化性能调控策略, 并介绍了各种合成方法和调控策略在电催化中的应用. 最后讨论了该领域面临的挑战, 并对未来的发展方向进行了展望.     

一种三维四元酸锰有机框架材料的合成、结构表征及荧光性能（英文）

通过水热法合成了一种结构新颖的金属有机框架物{[Mn(ttac)·(bibp)·H_2O]·[bibp]·H_2O}_n(其中H4ttac为4,5-二(3′-羧基苯基)-邻苯二甲酸,bibp为4,4′-联(咪唑基)联二苯).运用X射线单晶衍射、元素分析以及红外光谱对其进行了结构表征.结构测试表明该配合物通过一维链连接成二维层状结构,相邻的层之间存在游离的bibp分子,并且与已配位的bibp分子之间存在π…π堆积弱作用力进而构建成三维孔状结构,且该孔状结构中存在游离的水分子.此外,本文还研究了该配合物的荧光性质,荧光实验结果显示与配体相比,配合物的荧光发射波长发生蓝移.     

一种新的镧系金属有机骨架材料的合成、 结构及荧光检测性质

利用溶剂热方法合成了一种以Tb³⁺离子为中心的金属有机骨架材料［Tb₂(bpt)₂(H₂O)₂］·(DMA)_4.5, 并通过单晶X射线衍射(SXRD)、 粉末X射线衍射(PXRD)、 元素分析(EA)、 热重分析(TGA)、 傅里叶变换红外光谱 (FTIR)以及荧光光谱技术(FS)表征了该材料的结构与基本物理化学性质. 单晶衍射分析结果显示该材料具有包含一维直孔道的三维结构, 结构中孔道窗口尺寸约为1.23 nm×1.10 nm. 荧光分析测试结果表明该材料对Cr³⁺离子有荧光响应, 离子检测限低至0.22 mg/L, 同时具有良好的选择性, 在Cr³⁺离子的荧光检测领域具有重要的应用潜力.     

室温快速合成一种钴基金属有机框架材料纳米颗粒用于高效氧析出

采用一种在室温下快速、温和的方法制备Co-MOF-74纳米颗粒,该纳米颗粒结晶度好、形貌均匀,可在碱性介质中实现高效电催化析氧反应（OER）。相较于传统的水热合成法,通过引入三乙胺大大降低了合成所需时间,只需室温下搅拌2 h即可得到Co-MOF-74纳米颗粒（约20 nm）。该纳米催化剂呈现出更高的比表面积（760 m²·g^-1）、良好的OER活性和稳定性,在10 mA·cm^-2的电流密度下过电势仅为275 mV。     

金属有机框架材料吸附性能应用的研究

金属有机框架材料(MOFs)是一种多孔聚合物材料,其相关研究近年来取得迅速发展。MOFs是以金属离子为中心,桥连的有机配体作为支撑经延伸形成的一类具有周期性网络结构的晶态多孔材料[1]。由于其较强的功能性、较高的比表面积、超高的孔隙率以及可调控的孔道结构[2],MOFs在储气、分离、催化、载药和光学等领域受到了极大的重视,并具有广泛的应用前景。本文从MOFs材料的结构设计出发,介绍近几年MOFs材料在能源气体(H2、CH4)的储存,H2S、CO2、有机气体分子的捕集以及医学领域(对于一些药物的吸附装载)的研究进展,并对MOFs材料在应用上存在的问题进行了阐述,对其未来的发展趋势作出展望。     

磁性金属-有机骨架材料的合成及其应用

磁性金属-有机骨架(magnetic metal-organic frameworks,MMOFs)材料是近年来兴起的新型纳米功能材料,它由MOFs材料和磁性材料组合而成,具有高选择性、良好分散性和可多次重复利用等优点,在环境、医学和生物学研究领域应用广泛。本文介绍了MMOFs材料的四种合成方法,包括嵌入法、叠层法、封装法和混合法,其中嵌入法是指将磁性颗粒材料镶嵌在MOFs表面,叠层法是将MOFs层覆盖和叠加生长在官能化磁性颗粒材料表面,封装法是MOFs材料围绕磁性颗粒在其周围生长并将其包埋起来,混合法是将MOFs和磁性颗粒物通过物理或化学作用发生聚合合成。MOFs与磁性颗粒材料结合形成的MMOFs,既保留了MOFs材料的结构与性能,又增添了颗粒材料的磁性,从而大大拓展了MOFs的应用范围。鉴于MMOFs可携带特定的物质释放于指定位置,容易从复杂基质中分离,并可通过外部磁性进行定位与收集等优势与特点,其在生物医药、环境样品预处理和催化等领域得到了广泛的应用。     

磁共振/光学双模态分子探针的研究现状与展望

基于磁共振与荧光成像的双模态成像技术不仅克服了传统单一分子影像技术在灵敏度、特异度、分辨率等方面的固有缺陷，更是拓宽了分子影像技术在诊断及治疗监控等领域的研究范围及应用前景。本文将对磁共振/荧光双模态分子探针的应用情况和研究进展等进行综述。     

Nanotexaphyrin: One‐Pot Synthesis of a Manganese Texaphyrin‐Phospholipid Nanoparticle for Magnetic Resonance Imaging

The discovery and synthesis of novel multifunctional organic building blocks for nanoparticles is challenging. Texaphyrin macrocycles are capable and multifunctional chelators. However, they remain elusive as building blocks for nanoparticles because of the difficulty associated with synthesis of texaphyrin constructs capable of self‐assembly. A novel manganese (Mn)‐texaphyrin‐phospholipid building block is described, along with its one‐pot synthesis and self‐assembly into a Mn‐nanotexaphyrin. This nanoparticle possesses strong resilience to manganese dissociation, structural stability, in vivo bio‐safety, and structure‐dependent T₁ and T₂ relaxivities. Magnetic resonance imaging (MRI) contrast enhanced visualization of lymphatic drainage is demonstrated with respect to proximal lymph nodes on the head and neck VX‐2 tumors of a rabbit. Synthesis of 17 additional metallo‐texaphyrin building blocks suggests that this novel one‐pot synthetic procedure for nanotexaphyrins may lead to a wide range of applications in the field of nanomedicines.     

双金属金属有机骨架材料的制备及性能研究进展

金属有机骨架材料(MOFs)具有拓扑结构的多样性和丰富的比表面积,使其在催化和吸附领域具有潜在的应用价值。 双金属MOFs具有两种金属中心,较之单金属MOFs具有更加多元的催化活性位点和吸附位点,因此吸附选择性、选择催化性以及结构稳定性等均得到了提升。 本文就如何制备性能优异的双金属MOFs材料,以及这种材料的结构特点、性能提升和应用前景展开了概述。     

Synthesis and Properties of a Biodegradable Dendritic Magnetic Resonance Imaging Contrast Agent

Novel biodegradable dendritic contrast agents (DCAs) based on polyester dendrimers were synthesized and characterized.The DCAs were stable at acidic pH,but hydrolyzed rapidly at physiological pH,which rendered the DCA's long-term Gd3+ retention as low as that of small molecule CAs.Their longitudinal relaxivities of 10.2 to 17.5 L·mmol-1·s-1 were about 2.4 to 4.1 times higher than that of DTPA-Gd,indicating their superior contrast-enhancing capability to the clinically used contrast agent.The in vivo MRI study suggested that the DCA at lower generation (G2-DTPA-Gd) could effectively enhance the MRI of tumor,while the one at higher generation (G5-DTPA-Gd) showed more potential in liver imaging.     

Dysprosium Complexes and Their Micelles as Potential Bimodal Agents for Magnetic Resonance and Optical Imaging

Six diethylene triamine pentaacetic acid (DTPA) bisamide derivatives functionalized with p‐toluidine (DTPA‐BTolA), 6‐aminocoumarin (DTPA‐BCoumA), 1‐naphthalene methylamine (DTPA‐BNaphA), 4‐ethynylaniline (DTPA‐BEthA), p‐dodecylaniline (DTPA‐BC₁₂PheA) and p‐tetradecyl‐aniline (DTPA‐BC₁₄PheA) were coordinated to dysprosium(III) and the magnetic and optical properties of the complexes were examined in detail. The complexes consisting of amphiphilic ligands (DTPA‐BC₁₂PheA and DTPA‐BC₁₄PheA) were further assembled into mixed micelles. Upon excitation into the ligand levels, the complexes display characteristic Dy^III emission with quantum yields of 0.3–0.5 % despite the presence of one water molecule in the first coordination sphere. A deeper insight into the energy‐transfer processes has been obtained by studying the photophysical properties of the corresponding Gd^III complexes. Since the luminescence quenching effect is decreased by the intervention of non‐ionic surfactant, quantum yields up to 1 % are obtained for the micelles. The transverse relaxivity r₂ per Dy^III ion at 500 MHz and 310 K reaches a maximum value of 27.4 s^?1 mM ^?1 for Dy‐DTPA‐BEthA and 36.0 s^?1 mM ^?1 for the Dy‐DTPA‐BC₁₂PheA assemblies compared with a value of 0.8 s^?1 mM ^?1 for Dy‐DTPA. The efficient T₂ relaxation, especially at high magnetic field strengths, is sustained by the high magnetic moment of the dysprosium ion, the coordination of water molecules with slow water exchange kinetics and long rotational correlation times. These findings open the way to the further development of bimodal optical and magnetic resonance imaging probes starting from single lanthanide compounds.     

General Protocol for the Synthesis of Functionalized Magnetic Nanoparticles for Magnetic Resonance Imaging from Protected Metal–Organic Precursors

The development of magnetic nanoparticles (MNPs) with functional groups has been intensively pursued in recent years. Herein, a simple, versatile, and cost‐effective strategy to synthesize water‐soluble and amino‐functionalized MNPs, based on the thermal decomposition of phthalimide‐protected metal–organic precursors followed by deprotection, was developed. The resulting amino‐functionalized Fe₃O₄, MnFe₂O₄, and Mn₃O₄ MNPs with particle sizes of about 14.3, 7.5, and 6.6 nm, respectively, had narrow size distributions and good dispersibility in water. These MNPs also exhibited high magnetism and relaxivities of r₂=107.25 mM^?1 s^?1 for Fe₃O₄, r₂=245.75 mM^?1 s^?1 for MnFe₂O₄, and r₁=2.74 mM^?1 s^?1 for Mn₃O₄. The amino‐functionalized MNPs were further conjugated with a fluorescent dye (rhodamine B) and a targeting ligand (folic acid: FA) and used as multifunctional probes. Magnetic resonance imaging and flow‐cytometric studies showed that these probes could specifically target cancer cells overexpressing FA receptors. This new protocol opens a new way for the synthesis and design of water‐soluble and amino‐functionalized MNPs by an easy and versatile route.     

一锅法合成缩氨硫脲类化合物

香草醛和肼基二硫代甲酸甲酯经一锅法合成了两个新的缩氨硫脲类化合物,其结构经UV, 1H NMR, IR和元素分析表征.     

Organic Nanoprobes for Fluorescence and 19F Magnetic Resonance Dual‐Modality Imaging

Multimodal imaging techniques have been demonstrated to be greatly advantageous in achieving accurate diagnosis and gained increasing attention in recent decades. Herein, we present a new strategy to integrate the complementary modalities of ¹⁹F magnetic resonance imaging (¹⁹F MRI) and fluorescence imaging (FI) into a polymer nanoprobe composed of hydrophobic fluorescent organic core and hydrophilic fluorinated polymer shell. The alkyne‐terminated fluorinated copolymer (Pn) of 2,2,2‐trifluoroethyl acrylate (TFEA) and poly(ethylene glycol) methyl ether acrylate (PEGA) was first prepared via atom transfer radical polymerization (ATRP). The PEGA plays an important role in both improving ¹⁹F signal and modulating the hydrophilicity of Pn. The alkynyl tail in Pn is readily conjugated with azide modified tetra‐phenylethylene (TPE) through click chemistry to form azo polymer (TPE‐azo‐Pn). The core‐shell nanoprobes (TPE‐P3N) with an average particle size of 57.2 ± 8.8 nm are obtained via self‐assembly with ultrasonication in aqueous solution. These nanoprobes demonstrate high water stability, good biocompatibility, strong fluorescence and good ¹⁹F MRI performance, which present great potentials for simultaneous fluorescence imaging and ¹⁹F–MR imaging.     

手性金属-有机框架的设计、合成及应用

手性金属-有机框架具有框架结构多样性和功能可调性等特点,在对映异构体的识别与分离和不对称催化等领域中具有重要的应用.近年来,关于手性金属-有机框架的应用还扩展到其它研究领域,如在圆偏振荧光和手性铁电体等方面的研究中.与非手性金属-有机框架相比,手性金属-有机框架的设计不但要考虑手性的引入途径,还要考虑其结晶与纯化,因此在合成上相对困难.本综述论述了三种构筑手性金属-有机框架的有效策略,包括直接利用手性配体合成、非手性配体的自发拆分或手性模板诱导合成和非手性金属-有机框架的手性化.对近年来手性金属-有机框架在手性分子识别、对映异构体分离、不对称催化、圆偏振荧光以及手性铁电体等方面的研究进展进行了讨论.