三苯基锡与邻氨基苯甲酸型Schif碱配合物的合成及表征

合成了两种新的三苯基锡与邻氨基苯甲酸型Ｓｃｈｉｆ碱的配合物，经元素分析、ＵＶ、ＩＲ、１ＨＮＭＲ测定，对其结构进行了表征。结果表明，两种配合物具有不同的结构。在三苯基锡与水杨醛缩邻氨基苯甲酸Ｓｃｈｉｆ碱的配合物中，锡原子是六配位的，存在着酚羟基氧和亚氨基氮与锡的配键。在三苯基锡与２－羟基－１－萘醛缩邻氨基苯甲酸Ｓｃｈｉｆ碱的配合物中，锡原子是五配位的，酚羟基氧和亚氨基氮均未与锡配位，但存在着羰基氧与锡的配键     

三苯基锡与邻氨基苯甲酸型Schiff碱配合物的合成及表征

合成了两种新的三苯基锡与邻氨基苯甲酸型Ｓｃｈｉｆｆ碱的配合物，经元素分析，ＵＶ，ＩＲ，ＨＮＭＲ测定，其结果进行了表征。结果表明，两种配合物具有不同的结构。在三苯基锡与水杨醛缩邻氨基苯甲酸Ｓｃｈｉｆｆ碱的配合物中，锡原子六配位的，存在着酚羟基氧和亚氨基氮与锡配键。在三苯基锡与２－羟基－１－萘醛缩邻氨基苯甲酸Ｓｃｈｉｆｆ碱的配合物中，锡原子是五配位的，酚羟基氧和亚氨基氮均未与锡配闰，但存在羰基氧与锡配     

基于水杨酰腙配体的二丁基锡配合物的合成、晶体结构、热稳定性及与DNA相互作用

2-羰基丙酸水杨酰腙与二丁基氧化锡反应, 合成了二丁基锡2-羰基丙酸水杨酰腙配合物, 经元素分析、¹H NMR、¹³C NMR、IR、UV-Vis和X射线单晶衍射等技术手段表征分子结构, 结构分析表明, 该配合物晶体属四方晶系, 锡与配位原子形成变形五角双锥构型的双核有机锡配合物, 分子以Sn₂O₂四元环为中心对称。 热分析结果表明, 在空气氛下, 配合物在103 ℃以下可稳定存在; 研究了配合物在近生理条件下与DNA的相互作用, 用紫外光谱、荧光光谱法及粘度法研究了配合物与鲱鱼精DNA的相互作用, 结果表明, 配合物与鲱鱼精DNA作用方式为插入结合。     

水合三环己基锡4-吡啶甲酸酯配合物的合成、结构及抗癌活性

三环己基氢氧化锡与4-吡啶甲酸按物质的量比1:1在乙醇溶剂中反应,合成了水合三环己基锡4-吡啶甲酸酯配合物。采用元素分析、红外光谱、核磁共振、差热分析和X-射线单晶衍射等对配合物进行了结构表征,并对配合物进行量子化学计算和体外抗癌活性研究。结果表明:配合物中心锡原子为五配位畸变三角双锥构型;配合物对人肝癌细胞(HUH7)、人肺腺癌细胞(A549)、人表皮癌细胞(A431)和人结肠癌细胞(HCT-116)的抑制活性高于顺铂。     

一维链状有机锡配位聚合物[(PhCH_2)_3Sn·(O_2CC_5H_4N)·(H_2O)]_n的合成及晶体结构

有机锡的羧酸配合物因其具有很强的生物活性以及多变的结构类型受人们的广泛关注１～４。研究结果表明中心锡原子的配位形式决定于直接与锡原子相连的烃基的结构和羧酸基配体的类型５６。为了研究该类配合物的生物活性及其结构关系近年来合成了许多不同类型的有机锡的羧酸配合物。尤其是对羧酸配体中具有额外孤电子对的有机锡羧酸配合物的研究导致了许多新型结构的有机锡化合物的发现７～９。为探索三烃基锡羧酸配合物的结构类型、羧酸配体中杂原子与锡原子的作用方式以及分子结构与其生物活性的关系本文合成了三苄基４吡啶甲酸锡结晶水合物…     

双三苯基锡(Ⅳ)哌嗪荒酸盐的谱学和结构分析

利用三苯基氯化锡和哌嗪荒酸二钠在二氯甲烷中反应,合成了双核有机锡(Ⅳ)配合物双三苯基锡(Ⅳ)哌嗪荒酸盐。研究了该配合物的谱学性质和晶体结构;在该配合物的晶体中,锡原子呈五配位畸变三角双锥构型。     

一维链状有机锡配合物[Ph3Sn(OCOC5H4NO)]n的合成和晶体结构

有要锡配合物因基具有很强的生物活性以及多变的结构而日益受到人们的关注[1～4].有关该化合物的结构研究表明,中心锡原子的配位形式决定于直接与锡原子相连接的烃基的结构和羧酸基配体的类型[5～7].为了进一步探索有机锡羧配合物的结构类型、羧酸配体中带额外孤电子对的杂原子与锡原子的作用方式,本文合成了一个有机锡羧酸配合物[Ph3Sn(OCOC5H4NO)]n,并用X-射线衍射单晶结构分析方法测定了它的晶体结构.     

2-羰基丙酸(芳甲酰基)腙二(2,4-二氯苄基)锡配合物的合成、晶体结构、热稳定性及与DNA相互作用研究

在含水甲苯中,2,4-二氯苄与锡粉反应合成了二(2,4-二氯苄基)二氯化锡,将其分别与2-羰基丙酸(苯甲酰基)腙及2-羰基丙酸(水杨酰基)腙反应,合成了2个取代苄基锡配合物(C2、C3),配合物C2和C3通过元素分析、1H NMR、13C NMR、IR、UV-Vis等表征,运用X-射线单晶衍射测试了2个有机锡配合物的分子结构,结构分析表明,锡与配位原子形成变形五角双锥构型的双核有机锡配合物,分子以Sn2O2四元环为中心对称。热分析结果表明,在空气氛下,配合物C2在121℃、C3在128℃以下可稳定存在;在Tris-HCl缓冲溶液中,以EB做为荧光探针,用荧光光谱法初步研究了配合物与鲱鱼精DNA的相互作用,结果表明配合物与鲱鱼精DNA作用是插入结合与静电结合共同作用所致。     

2-氨基苯并噻唑配合物的晶体结构及抑菌活性

合成了2-氨基苯并噻唑与钴和锌的两种金属配合物,利用红外光谱、元素分析、X射线单晶衍射和热重分析等对其结构进行了表征;并研究了两种金属配合物对金黄色葡萄球菌、大肠杆菌、酵母菌的抑菌活性.结果表明,Zn(Ⅱ)和Co(Ⅱ)分别与2个O原子和2个N原子通过4配位形成扭曲的四面体构型;两种配合物对三种菌种均有较强的选择性抑制作用.     

含扑酸的三烃基锡配合物的合成及结构研究(英文)

用扑酸(H2pa,2,3-diphenylpropionic acid)和三烃基锡氯化物R3SnCl(R=Ph,Bu,Me)合成了3个有机锡配合物{[(Ph3Sn)(pa)]·Et3N}n(1)、(Bu3Sn)2(pa)(2)和[(Me3Sn)2(pa)]·CH2Cl2(3)。通过元素分析、红外光谱、核磁共振谱及X-ray单晶衍射等手段对配合物进行了表征。结构表明三苯基锡扑酸酯为一维链状聚合物,扑酸作为桥联配体链接各个锡原子,中心锡采取五配位的三角双锥构型;而三甲基锡和三丁基锡扑酸酯配合物为二核锡配合物,锡采取四配位的四面体构型。     

环己基(三甲基硅基亚甲基)锡二芳香酸酯的合成、结构和抗癌活性

采用环己基(三甲基硅基亚甲基)二氯化锡和芳香酸(物质的量比1:2)在三乙胺存在下,合成了8种新的混合二烃基锡化合物环己基(三甲基硅基亚甲基)锡二芳香酸酯。 通过IR、¹H NMR、¹³C NMR和元素分析等技术手段对它们的结构进行了表征;部分化合物的生物活性测定初步结果表明,它们对肺腺癌细胞(A549)有较好的体外抗癌活性,抑制率均在75%以上。     

卤代芳香族羧酸与含氮配体合成镧系配合物的结构、热化学和荧光性质（英文）

采用室温溶液挥发法合成了五种结构新颖的镧系配合物,其结构通式为[Ln(2,4-DFBA)₃(phen)]₂ (Ln=Sm 1, Eu2, Er 3, 2,4-DFBA为2,4二氟苯甲酸的简写,phen为1,10-菲啰啉的简写),[Ln(2-Cl-6-FBA)₂(terpy)(NO₃)(H₂O)]₂ (Ln=Tb4, Dy 5, 2-Cl-6-FBA为2-氯-6-氟苯甲酸的简写, terpy为2,2’:6’2’’-三联吡啶的简写)。五个配合物可以分为两个系列,使用不同的镧系离子作为中心离子。通过X射线单晶分析,5种配合物均属于单斜晶系,空间群为P21/n。配合物1,2和配合物3虽然具有相同的分子通式,但配位方式明显不同,形成了前者为9配位的松饼型,后者是8配位的双帽三棱柱几何构型。二维面状超分子结构的形成方式也明显不同,区别在于配合物1和2通过微弱的π-π堆积作用形成。配合物4和5是同构的,结构中引入了硝酸根离子较为有趣,通过C―H···F氢键和π-π堆积作...     

三环已基锡L-扁桃酸酯配合物的合成、结构及性质

三环己基氢氧化锡与L-扁桃酸(物质的量比1:1)在苯和乙醇混合溶剂中反应合成了三环己基锡L-扁桃酸酯。 经X射线衍射方法测定了其晶体结构,配合物属斜方晶系,空间群为P2₁2₁2₁,晶体学参数a=0.80825(4) nm,b=1.77151(8) nm,c=1.8385(2) nm,α=β=γ=90°,V=2.6324(2) nm³,Z=4,D_c=1.310 g/nm³,μ(MoKα)=9.92 cm^-1,F(000)=1080,R₁=0.0472,wR₂=0.1341。 中心锡原子与环己基碳原子和氧原子构成畸型四面体。 对其结构进行量子化学从头计算,探讨了配合物的稳定性、分子轨道能量以及一些前沿分子轨道的组成特征。 研究了配合物的热稳定性、电化学性能、圆二色谱和体外抗癌活性。     

2, 4, 6-三甲基苯甲酸与5, 5'-二甲基-2, 2'-联吡啶构筑的系列镧系超分子配合物的晶体结构、热分解机理和性能

Six ternary lanthanide complexes formulated as [Ln(2, 4, 6-TMBA)₃(5, 5'-DM-2, 2'-bipy)]₂ (Ln = Pr 1, Nd 2, Sm 3, Eu 4, Gd 5, Dy 6; 2, 4, 6-TMBA = 2, 4, 6-trimethylbenzoate; 5, 5'-DM-2, 2'-bipy = 5, 5'-dimethyl-2, 2'-bipyridine) have been synthesized under solvothermal conditions and characterized by single-crystal X-ray diffraction, elemental analysis, thermogravimetric analysis, etc. The results of crystal diffraction analysis show that complexes 1–6 are binuclear units, crystallizing in the triclinic Pī space group. Complexes 1–5 are isostructural, and each of the central metal ions has a coordination number of 9. The asymmetric unit of complexes 1–5 consists of one Ln³⁺, one 5, 5'-DM-2, 2'-bipy ligand, and three 2, 4, 6-TMBA^- moieties with three coordination modes: chelation bidentate, bridging bidentate, and bridging tridentate. The coordination geometry of Ln³⁺ is distorted monocapped square antiprismatic. The binuclear units of complexes 1–5 form a one-dimensional (1D) supramolecular chain along the c-axis via π–π stacking interactions between the 2, 4, 6-trimethylbenzoic acid rings. The 1D chains are linked to form a supramolecular two-dimensional (2D) sheet in the bc plane via π–π stacking interactions between the pyridine rings. Although the molecular formulae of complex 6 and complexes 1–5 are similar, the coordination environment of the lanthanide ions is different in the two cases. The asymmetric unit of complex 6 contains a Dy³⁺ ion coordinated by a bidentate 5, 5'-DM-2, 2'-bipy and three 2, 4, 6-TMBA^- ligands adopting bidentate and bridging bidentate coordination modes. The Dy³⁺ metal center has a coordination number of 8, with distorted square antiprismatic molecular geometry. The binuclear molecule of 6 is assembled into a six-nuclear unit by π–π weak staking interactions between two 5, 5'-DM-2, 2'-bipy ligands; then, adjacent six-nuclear units form a 1D chain via offset π–π interactions between 5, 5'-DM-2, 2'-bipy ligands on different adjacent units. The adjacent 1D chains are linked by C―H···O hydrogen bonding interactions to form a 2D supramolecular structure. The thermal stability and thermal decomposition mechanism of all the complexes are investigated by the combination of thermogravimetry and infrared spectroscopy (TG/FTIR) techniques under a simulated air atmosphere in the temperature range of 298–973 K at a heating rate of 10 K·min^-1. Thermogravimetric studies show that this series of complexes have excellent thermal stability. During the thermal decomposition of the complex, the neutral ligand is lost first, followed by the acid ligand, and finally, the complex is decomposed into rare earth oxides. The three-dimensional infrared results are consistent with the thermogravimetric results. The photoluminescence spectra of complex 4 show the strong characteristic luminescence of Eu³⁺. The five typical emission peaks at 581, 591, 621, 651, and 701 nm correspond to the ⁵D₀ → ⁷F₀, ⁵D₀ → ⁷F₁, ⁵D₀ → ⁷F₂, ⁵D₀ → ⁷F₃, and ⁵D₀ → ⁷F₄ electronic transitions of Eu³⁺, respectively. The emission at 621 nm is due to the electric dipole transition ⁵D₀ → ⁷F₂, while that at 591 nm is assigned to the ⁵D₀ → ⁷F₁ the magnetic dipole transition. The lifetime (τ) of complex 4 is calculated as 1.15 ms based on the equation τ = (B₁τ₁² + B₂τ₂²))/(B₁τ₁ + B₂τ₂), and the intrinsic quantum yield is calculated to be 45.1%. Further, the magnetic properties of complex 6 in the temperature range of 2–300 K are studied under an applied magnetic field of 1000 Oe.     

Synthesis, structure and luminescent property of a 2D polymer containing silver ions

Silver(I) complex with 4,5-dicarboxyimidazole (H₃dcbi) has been synthesized by hydrothermal method and proven to be a novel 2D coordination polymer [Ag(H₂dcbi)]_n (1), which crystallized in monoclinic crystal system and space group of P2(1)/c. Each Ag(I) ion is coordinated to three O atoms and one N atom, which completes the trigonal pyramidal geometry of Ag(I) ion. Solid-state fluorescent emission spectra of 1 were investigated.     

Complex of trivalent lanthanum ion with galactitol in the solid state: the crystal structure and an FT-IR study of LaCl3·galactitol·6H2O

The crystal structure of LaCl₃·galactitol·6H₂O has been determined. It is monoclinic. The space group is P2₁/n with unit cell dimensions a=10.5091(7), b=12.5366(7), c=14.4420(10) Å, β=90.974(2)°, V=1902.4(2) ų and Z=4. Each La³⁺ ion in the unit cell is coordinated to 10 oxygen atoms, three from O1, O2 and O3 of one alditol, three from O4, O5 and O6 of another alditol and four from water molecules, with La–O distances from 2.5099 to 2.6916 Å. The other two water molecules are hydrogen-bonded. FT-IR spectrum of LaCl₃·galactitol·6H₂O is apparently different from that of other lanthanide–galactitol complexes. It is consistent with the differences between their crystal structures. Both the IR result and the crystal structure of LaCl₃·galactitol·6H₂O complex show that it has the different coordination mode compared with other lanthanide complexes.     

Facile synthesis of a 4-anilinoquinazoline dimer by Suzuki cross-coupling reaction

A novel 4-anilinoquinazoline dimer linked by a carbon-carbon bond in the C-7 position was synthesized via a one step Suzuki cross-coupling reaction. All structures of new compounds were characterized by ¹H NMR, ¹³C NMR, and HRMS. The inhibition rate of the synthetic 4-anilinoquinazoline dimer 8 against epidermal growth factor receptor-tyrosine kinase enzymes (EGFR) in vitro was 44.4% at the concentration of 5.5 μmol/L.     

Coordination geometry of tetradentate Schiff’s base nickel complexes: the effects of donors, backbone length and hydrogenation

The X-ray crystal structures of (N,N′-bis-(o-amidobenzilidene)-1,3-diaminopropane)nickel (Niambpr), (N,N′-bis-(o-amidobenzilidene)-1,4-diaminobutane)nickel (Niambut), (N,N′-bis-(o-thiobenzilidene)-1,4-diaminobutane)nickel(II) (Nitsalbut), bis-acetonitrile-(N,N′-bis-(o-aminobenzyl)-1,2-diaminoethane) nickel(II) tetrafluoroborate [Ni(H₄amben)(MeCN)₂] [BF₄]₂, bis-O-acetato-(N,N′-bis-(o-aminobenzyl)-1,2-diaminoethane) nickel(II) [Ni(H₄amben)(OAc)₂ · H₂O] and bis-O-acetato-(N,N′-bis-(o-aminobenzyl)-1,3-diaminopropane) nickel(II) [Ni(H₄ambpr)(OAc)₂] are presented. These structures complete the structural characterisation of the simple unsubstituted Schiff’s base complexes with N₄ and N₂S₂ donor sets and allow us to assess the effects of donor groups and polymethylene chain length on the coordination geometries of nickel(II). The hydrogenated N₄ complexes offer an insight into the effects of increased flexibility and character of the internal nitrogen donors. Unlike the parent N₄ imine species the hydrogenated amine species do not deprotonate at the peripheral nitrogen donors and do not seem to be restricted to the meridial plane of the nickel.     

Synthesis,structure and biological activity of organotin derivatives with pyridylmethylthiobenzoic acid

Reaction of 2-(2-pyridylmethylthio)benzoic acid (1) with R₂SnO (R = Et or ⁿBu) in a 1:1 molar ratio gives the dimeric compounds {[(2-PyCH₂SC₆H₄CO₂)SnR₂]₂O}₂. A similar reaction of 2-(4-pyridylmethylthio)benzoic acid (2) with Et₂SnO yields an analogous result. However, treatment of 2 with ⁿBu₂SnO in a 1:1 molar ratio only gives the diorganotin dicarboxylate (4-PyCH₂SC₆H₄CO₂)₂Sn(ⁿBu)₂. X-ray crystal structure analyses indicate that the pyridyl nitrogen atoms do not coordinate to the tin atoms in the dimer, whilst in the diorganotin dicarboxylate the tin atom has a seven-coordinate distorted pentagonal-bipyramidal geometry, and this compound forms a linkage coordination polymer through the interactions of the pyridyl nitrogen atoms with the adjacent tin atoms. In addition, treatment of 1 or 2 with (Ph₃Sn)₂O in a 2:1 molar ratio affords triphenyltin carboxylates, in which the tin atoms also show different coordination environments. In the solid state, triphenyltin 2-(2-pyridylmethylthio)benzoate is a monomer and the pyridyl nitrogen atom does not participate in coordination to the tin atom either, while the interactions between the pyridyl nitrogen atoms and the adjacent tin atoms link triphenyltin 2-(4-pyridylmethylthio)benzoate into a coordination polymer. Preliminary in vitro tests for fungicidal activity show that all these compounds display good activity to Physolospora piricola in a low concentration. Moreover, the triphenyltin carboxylates show a higher inhibition percentage than the diorganotin carboxylates.     

可区别铁离子荧光探针异构体的合成及其水样分析

分别以2-（2-氨基苯基）菲并咪唑和2-（3-氨基苯基）菲并咪唑为原料,与5-硝基水杨醛反应合成了两个菲并咪唑-苯酚异构体衍生物（PI?o?OH和PI?m?OH）。在水相体系中（V（DMF）∶V（HEPES） = 1∶1,pH = 7.4）,两个异构体发射中等强度的荧光。Fe³⁺存在下,两个异构体的荧光强度分别淬灭为原来的1/3和1/6,淬灭常数为4.8×10³和4.6×10³ L/mol,且淬灭效果不受其它干扰离子和pH值变化的影响。间位异构体PI?m?OH与Fe³⁺的荧光识别在2 min之内完成,配合速度明显优于邻位基异构体,且配合稳定性高于邻位异构体,配合常数为3.82×10⁴ L/mol。通过高分辨质谱和Job's曲线,确定了两个异构体与Fe³⁺识别配合比为1∶1,并建议了PI?m?OH-Fe³⁺ and PI?o?OH-Fe³⁺两个配合物的结构。两个异构体均可实现实际水样中Fe³⁺的定量检测,表明它们在实际水样的Fe³⁺分析中具有一定的应用价值。