Syntheses and Crystal Structures of Two Novel Spiro Compounds Containing 1,5-Dioxaspiro[5.5]undecane-2,4-dione

Two novel spiro compounds,3-benzylidene-1,5-dioxaspiro[5.5]undecane-2,4-dione 1 and 3-（2-fluorobenzylidene）-1,5-dioxaspiro[5.5]undecane-2,4-dione 2,have been synthesized and characterized by X-ray single-crystal diffraction,IR and elemental analysis.Compound 1 belongs to the monoclinic system,space group P21/n with a=12.326（3）,b=5.6420（11）,c=20.089（4）,β= 101.79（3）o,C16H16O4,Mr= 272.29,V=1367.7（5）3,Z=4,Dc=1.322g/cm3,F（000）=576,μ（MoKa）=0.095 mm-1,the final R=0.0420 and wR=0.1159.Compound 2 is of monoclinic system,space group P21/n with a=12.283（3）,b=5.6367（11）,c=20.055（4）,β=102.00（3）o,C16H15FO4,Mr=290.28,V=1358.2（5）3,Z=4,Dc=1.420 g/cm3,F（000）=608,μ（MoKa）=0.110 mm-1,the final R=0.0353 and wR=0.0860.

DNA Modification with Photochromic Spiro Compounds

The photochromic spiropyrans and spirooxazine having a succinimidyl ester or isothiocyanate pendant group can form covalent products with transaminated DNA. The absorption spectra and solid reflection spectra of modified DNA with these photochromic spiro compounds were investigated.

Synthesis and Structure Elucidation of New Spiro Compounds with Per（poly）fluoroalkyl Group

A series of spiro compounds have been synthesized via several steps. The structure of these compounds were confirmed by ^1H NMR, 13C NMR, IR, MS spectra and X-ray diffraction analysis. The possible mechanism to form these products was also proposed.

Chiral Separation of Spiro-compounds and Determination Configuration

Chiral spirocyclic compounds have attracted the attention of scholars and scientists owing to their potential applications in the pharmaceutical industry as either active pharmaceutical ingredients, catalysts in synthesizing active enantiomers, or as surface modifiers on silica particles to resolve entantiomers. In this study, five spiro compounds of 3,9-diphenyl-2,4,8,10-tetraoxaspiro[5.5]-undecane（1）, 3,9-（4-methoxyphenyl）-2,4,8,10-tetraoxaspiro [5.5] -undecane（2）, 3,9-（4-methylphenyl）-2,4,8,10-tetraoxaspiro [5.5] -undecane（3）, 4,4＇-（2,4,8,10-tetraoxaspiro[5.5]undecane-3,9-diyl）dibenzoic acid（4） and 3,9-di（4-formyl-phenyl）-2,4,8,10-tetraoxa-spiro[5.5]-undecane（5） were synthesized by grinding pentaerythritol with benzaldehyde, 4-methoxybenzaldehyde, 4-methylbenzaldehyde, 4-carboxybenzaldehyde or terephthalaldehyde monoacetal in the presence of InI3r3 under solvent-free conditions. A normal phase HPLC method was successfully developed to resolve entantiomers of compounds 1--5 on a chiral column. Specific optical rotation of R or S entantiomers（1） was determined and the corresponding configurations were proposed based on Lowe＇s rule.

Ab Initio Study of the Mechanism of Forming a Spiro-Ge-heterocyclic Ring Compound Involving Si from Me_2Si=Ge: and Formaldehyde

X2Si=Ge： （X = H, Me, F, CI, Br, Ph, Ar...） is a new species. Its cycloaddition reaction is a new area for the study of germylene chemistry. The mechanism of cycloaddition reaction between singlet state Me2Si=Ge： and formaldehyde has been investigated with the CCSD（T）//MP2/cc-pvtz method. From the potential energy profile, it could be predicted that the reaction has one dominant reaction pathway. The reaction rule presented is that the two reactants first form a four-membered Si-heterocyclic ring germylene through the [2＋2] cycloaddition reaction. Because of the 4p unoccupied orbital of Ge： atom in the four-membered Si-heterocyclic ring germylene and the π orbital of formaldehyde form a π→p donor-acceptor bond, the four-membered Si-heterocyclic ring germylene further combines with formaldehyde to form an intermediate. Because the Ge atom in the intermediate undergoes sp^3 hybridization after transition state, then the intermediate isomerizes to a spiro-Ge-heterocyclic ring compound involving Si via a transition state. The research result indicates the laws of cycloaddition reaction between HzSi=Ge： and formaldehyde. It has important reference value for the cycloaddition reaction between X2Si=Ge： （X = H, Me, F, CI, Br, Ph, Ar…） and asymmetric to-bonded compounds, which is significant for the synthesis of small-ring and spiro-Ge-heterocyclic compounds involving Si. The study extends research area and enriches the research content of germylene chemistry.

Ab Initio Study of the Mechanism of Forming a Spiro-Si-heterocyclic Ring Compound Involving Ge from Cl_2Ge=Si:and Formaldehyde

The X2Ge=Si： （X = H, Me, F, reaction is a new area for the study of silylene between singlet CI2Ge=Si： and formaldehyde CI, Br, Ph, At...） is a new species. Its cycloaddition chemistry. The mechanism of cycloaddition reaction has been investigated with CCSD（T）//MP2/6-31G＊ method. From the potential energy profile, it can be predicted that the reaction has two competitive dominant reaction pathways. The reaction rule presented is that the two reactants firstly form a four-membered Ge-heterocyclic ring silylene through the [2＋2] cycloaddition reaction. Owing to the 3p unoccupied orbital of Si： atom in the four-membered Ge-heterocyclic ring silylene and the π orbital of formaldehyde forming a π-p donor-acceptor bond, the four-membered Ge-heterocyclic ring silylene further combines with formaldehyde to form an intermediate. Because the Si： atom in intermediate shows sp3 hybridization after transition state, the intermediate isomerizes to a spiro-Si-heterocyclic ring compound involving Ge via a transition state. Simultaneously, the ring strain of the four-membered Ge-heterocyclic ring silylene makes it isomerize to a twisted four-membered ring product. The research result indicates the laws of cycloaddition reaction between X2Ge=Si： （X = H, Me, F, C1, Br, Ph, Ar...） and the asymmetric g-bonded compounds, which are significant for the synthesis of small-ring and spiro-Si-heterocyclic ring compound involving Ge The study extends the research area and enriches the research content of silvlene chemistrv.

Ab Initio Study of Mechanism of Forming a Si-heterocyclic Spiro-Sn-heterocyclic Ring Compound by Cycloaddition Reaction of Cl2Si=Sn: and Ethylene

X2Si=Sn:(X = H, Me, F, Cl, Br, Ph, Ar…) are new species of chemistry. The cycloaddition reaction of X2Si=Sn: is a new study field of stannylene chemistry. To explore the rules of cycloaddition reaction between X2Si=Sn: and the symmetric p-bonded compounds, the cycloaddition reactions of Cl2Si=Sn: and ethylene were selected as model reactions in this paper.The mechanism of cycloaddition reaction between singlet Cl2Si=Sn: and ethylene has been first investigated with the MP2/GENECP(C, H, Cl, Si in 6-311++G**;Sn in LanL2dz) method in this paper. From the potential energy profile, it could be predicted that the reaction has one dominant reaction channel. The reaction rule presented is that the 5p unoccupied orbital of Sn in Cl2Si=Sn: and the π orbital of ethylene forming a p→p donor-acceptor bond, resulting in the formation of an intermediate. Instability of the intermediate makes it isomerize to a four-membered Si-heterocyclic ring stannylene. Because the 5p unoccupied orbital of Sn atom in the four-membered Si-heterocyclic ring stannylene and the π orbital of ethylene form a p→p donor-acceptor bond, the four-membered Si-heterocyclic ring stannylene further combines with ethene to form another intermediate. Because the Sn atom in the intermediate shows sp3 hybridization after transition state, the intermediate isomerizes to a Si-heterocyclic spiro-Sn-heterocyclic ring compound. The research result indicates the laws of cycloaddition reaction between X2Si=Sn: and the symmetric π-bonded compounds. The study opens up a new research field for stannylene chemistry.

螺环类农药研究进展

综述了具有杀虫活性、杀菌活性和抗病毒活性螺环化合物在农药领域的研究进展,总结了具有生物活性的螺环化合物的结构特征,并展望了螺环化合物作为农药先导化合物的研究前景。

Photo‐catalyzed sequential dearomatization/carboxylation of benzyl o‐halogenated aryl ether with CO_(2) leading to spirocyclic carboxylic acids

Photo‐catalyzed tandem dearomatization/carboxylation of benzyl o‐halogenated aryl ether with CO_(2) was achieved,which affords spirocyclic carboxylic acids under mild conditions.The reaction has good functional group tolerance with high yields.Mechanism studies indicate that the transformation was realized via intramolecular radical addition and nucleophilic addition.

串联[3+2]环加成和丁炔二甲酸酯参与的扩环反应合成新型螺吲哚酮和螺二氢喹啉类化合物

因具有原料易得、方法简便、反应步骤和分离步骤少等特点,多组分反应和串联反应在有机合成中获得广泛的应用。本文报道一种简洁高效的串联反应合成螺环化合物的新方法。通过硫代脯氨酸、靛红和双查尔酮先在甲醇中进行[3+2]环加成反应,然后在甲醇回流条件下与丁炔二酸二甲酯通过扩环反应,分别生成了结构新颖的含巯基的螺吲哚酮化合物和螺二氢喹啉衍生物,其结构经IR,HR-MS,^(1)H NMR和^(13)C NMR表征,并确定了单晶分子结构。该反应具有原料简单易得,操作简便,原子经济性高等优点。

含芴、蒽螺环结构电致发光材料的研究进展

螺环芳香类化合物具有大的共轭体系和较好的刚性共面性,而且玻璃化温度高,热稳定性好(熔点大于300℃),制作电致发光(EL)器件工艺简单,不需要复杂的设备,因而有可能降低器件制作成本,特别是易于制备大面积器件.对近年来含芴、蒽螺环结构发光材料的研究进展进行了总结,重点介绍了含有双螺、单螺结构的有机电致发光材料的结构和特性,给出了部分有机化合物的合成方法.对含有硅元素的螺环化合物发光材料进行了简单介绍.

具有生理活性的含氧、氮、硫杂原子螺环化合物的研究进展

综述了近年来部分具有生理活性螺环化合物的研究进展,重点介绍了这类化合物的结构特征、生理活性和部分化合物的合成方法.展望了该类螺环化合物的应用前景.

含螺环结构农药研究进展

综述了近年来含螺环结构化合物在农药方面的研究进展,详细介绍了部分螺环化合物的合成方法,总结了螺环农药的结构特征.对该类化合物的应用前景进行了展望.

螺共轭效应及其应用

螺共轭术语是1967年由Simmons和Fukunaga首次提出的,由于其特殊的立体电子效应而引起了科学家们的广泛关注.综述了40年来有关螺共轭的理论发展以及在发光材料、光致变色材料、非线性光学材料、螺环染料、有机导体等方面的研究现状,展望了螺共轭效应的应用前景,并提出了一些新的设想.

含多个杂原子螺环化合物的研究与应用

综述了近年来含多个杂原子螺环结构化合物的发展现状及研究进展,并根据不同的结构介绍了在医药和农药方面的研究与应用。

α,β,γ,δ-四-{4-[3-(9-(4-(3-(9-(4-(2-(5,5-二酰氧基甲基-1,3-二噁烷基))))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基)))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基]}苯基卟啉星形化合物的合成

以对苯二甲醛、丙二腈、季戊四醇和吡咯为原料,合成了含有螺环结构单元的中间体3-[4-(2,2-二氰基)乙烯基]苯基-9-(4-甲酰基)苯基-2,4,8,10-四氧杂螺[5.5]十一烷(3)和α,β,γ,δ-四-(4-甲酰基苯基)卟啉(4).4与过量的季戊四醇反应,得到α,β,γ,δ-四-{4-[2-(5,5-二羟甲基-1,3-二噁烷基)]}苯基卟啉(5),5与3的反应产物经10%NaOH处理后,再与过量的季戊四醇反应,得到α,β,γ,δ-四-{4-[3-(9-(4-(3-(9-(4-(2-(5,5-二羟甲基-1,3-二噁烷基))))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基)))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基]}苯基卟啉(6),6与乙酐、丙酐、苯甲酰氯反应,得到α,β,γ,δ-四-{4-[3-(9-(4-(3-(9-(4-(2-(5,5-二乙酰氧基甲基-1,3-二噁烷基))))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基)))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基]}苯基卟啉(7),α,β,γ,δ-四-{4-[3-(9-(4-(3-(9-(4-(2-(5,5-二丙酰氧基甲基-1,3-二噁烷基))))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基)))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基]}苯基卟啉(8)和α,β,γ,δ-四-{4-[3-(9-(4-(3-(9-(4-(2-(5,5-二苯甲酰氧基甲基-1,3-二噁烷基))))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基)))苯基-2,4,8,10-四氧杂螺[5.5]十一烷基]}苯基卟啉(9)等三种卟啉星形化合物.中间体1～6和星形化合物7～9均进行了IR,1HNMR,MS和元素分析等结构表征.对影响反应的诸因素进行了讨论.

新型螺环树状化合物的合成

利用环己二酮单腙芳构化反应,得到9H,9H,11H,11H,12H,12H-六氢化苯并[9,10]-(1H,1H,3H,3H,4H,4H,5H,5H,7H,7H,8H,8H-十二氢)菲-2,6,10-三酮腙,然后与季戊四醇反应,得到9H,9H,11H,11H,12H,12H-六氢化苯并[9,10]-(1H,1H,3H,3H,4H,4H,5H,5H,7H,7H,8H,8H-十二氢)菲-2,6,10-三酮缩三(2,2-二羟甲基-1,3-丙二醇),再与9-[4-(2,6-二硫杂环己基)苯基]-3-[4-(二甲酯基甲基)苯基]-2,4,8,10-四氧杂螺[5.5]十一烷反应,制成标题化合物.中间体和标题化合物经过IR,1HNMR,MS和元素分析表征.

9,9-(′1,4-亚苯基)十四氢-二-吖啶-1,1,′8,8′-四酮缩双季戊四醇的合成

利用1,3-环己二酮和1,4-苯二甲醛为原料,在微酸介质中通过羟醛缩合和脱水反应,合成了9,9′-(1,4-亚苯基)-2H,2′H,3H,3′H,4H,4′H,5H,5H,′6H,6′H,7H,7′H,9H,9′H-十四氢-二-吖啶-1,1,′8,8′-四酮(化合物Ⅰ)。提出了化合物Ⅰ生成的反应机理。将化合物Ⅰ与季戊四醇在I2催化下反应,生成了目标化合物9,9-(′1,4-亚苯基)-2H,2′H,3H,3′H,4H,4′H,5H,5H,′6H,6′H,7H,7′H,9H,9′H-十四氢-二-吖啶-1,1,′8,8′-四酮缩双季戊四醇(化合物Ⅱ),收率为40%。产物和中间体用IR1、H NMR、MS和元素分析进行了结构表征。在含有螺环单元的化合物Ⅱ1H NMR中,亚甲基中的8个氢由于受手性轴和苯环的影响而裂分成8重峰。

二代螺环树形化合物1,2,3,4,5,6,7,8,9,10,11,12-十二氢-2,2;6,6;10,10-三[3,3-二(烷氧羰基)-1,1-环亚丁基二甲氧基]三亚苯基的合成

以1,4-环己二酮、丙二酸二乙酯及多元醇等为原料,经过两次"一锅煮"法合成了六种二代螺环树形化合物1,2,3,4,5,6,7,8,9,10,11,12-十二氢-2,2;6,6;10,10-三[3,3-二(烷氧羰基)-1,1-环亚丁基二甲氧基]三亚苯基螺环树形化合物,其中烷氧基为异戊氧基、三羟甲基甲氧基、2,2-二溴甲基-3-羟丙氧基、2,2-二羟甲基丙氧基、二羟甲基膦甲氧基和(N-羟甲基-N-二羟甲基氨基乙基)甲氧基.利用IR,NMR,MS和元素分析对合成的化合物进行了结构认证,对影响反应的因素进行了讨论.

一种苯磺酰基/螺-9,9′-氧杂蒽芴双极性分子的简易合成法:分子结构与光电性质（英文）

利用一种简易合成法制备了2′-苯磺酰基-螺-9,9′-氧杂蒽芴(PSSFX)。热重分析曲线和差热扫描曲线表明该化合物在222℃时失重5%,加热到160℃没有玻璃化转变温度,其熔点为124℃。通过磷光光谱计算得到该化合物的三线态能级T1为2.77eV。利用密度泛函计算得知其HOMO(-5.83eV)和LUMO(-1.62eV)轨道相分离。通过循环伏安法得到其HOMO、LUMO和Eg分别为-6.33,-2.34,3.94eV。这表明缺电子的苯磺酰基有利于改善其电子注入/传输性能。PSSFX在二氯甲烷溶液和晶体粉末的紫外吸收峰分别位于267nm和274/351nm左右,发射峰分别位于408nm和341nm左右。