Trifluoroethoxy‐Coating Improves the Axial Ligand Substitution of Subphthalocyanine

A novel trifluoroethoxy (TFEO)‐coated SubPc ( 1 ) and various axially functionalised derivatives thereof ( 2 ) have been efficiently synthesised. The advantage of the TFEO‐coating on SubPcs compared to conventional fluorine‐coated or uncoated molecules has been clearly demonstrated, as axial derivatisation has been realised in very good yields. Among various SubPcs synthesised, formyl‐SubPc 2 f has been further used as a building block for the synthesis of donor–acceptor SubPc–C₆₀ hybrid 8 , while iodo‐SubPc 2 e has been used for the synthesis of trifluoroethoxy‐coated SubPc–Pc dyads 9 and 10 . All of these compounds are highly soluble in all common organic solvents, which greatly facilitates their purification and characterisation. The SubPcs 2 a – c incorporating oligoethylene glycol moieties are attractive from a biological point of view, while SubPcs 8 – 10 may prove useful for studies of intramolecular electron‐ and energy‐transfer processes.     

Layered structures in proton‐transfer compounds of 5‐sulfosalicylic acid with the aromatic polyamines 2,6‐diamino­pyridine and 1,4‐phenyl­ene­diamine

The crystal structures of two proton‐transfer compounds of 3‐carb­oxy‐4‐hydroxy­benzene­sulfonic acid (5‐sulfosalicylic acid) with the aromatic polyamines 2,6‐diamino­pyridine [namely 2,6‐diamino­pyridinium 3‐carb­oxy‐4‐hydroxy­benzene­sulfonate monohydrate, C₅H₈N₃⁺·C₇H₅O₆S⁻·H₂O, (I)] and 1,4‐phenyl­ene­diamine [namely 1,4‐phenyl­ene­diaminium 3‐carboxyl­ato‐4‐hydroxy­benzene­sulfonate, C₆H₁₀N₂²⁺·C₇H₄O₆S²⁻, (II)] have been determined. Both compounds feature extensively hydrogen‐bonded three‐dimensional layered polymer structures having significant inter­layer π–π inter­actions between the cation and anion species. In (I), the pyridine N atom of the Lewis base is protonated and forms a direct hydrogen‐bonding inter­action with the water mol­ecule, which together with the two amine groups of the cation and the carboxylic acid group of the anion also give additional inter­actions with O‐atom acceptors of the sulfonate group. In (II), a dianionic species results from deprotonation of both the sulfonic and the carboxylic acid groups, and all available O‐atom acceptors inter­act with all dication donors, which lie about inversion centres.     

Alkyltelluro Substitution Improves the Radical‐Trapping Capacity of Aromatic Amines

The synthesis of a variety of aromatic amines carrying an ortho‐alkyltelluro group is described. The new antioxidants quenched lipidperoxyl radicals much more efficiently than α‐tocopherol and were regenerable by aqueous‐phase N‐acetylcysteine in a two‐phase peroxidation system. The inhibition time for diaryl amine 9 b was four‐fold longer than recorded with α‐tocopherol. Thiol consumption in the aqueous phase was found to correlate inversely to the inhibition time and the availability of thiol is the limiting factor for the duration of antioxidant protection. The proposed mechanism for quenching of peroxyl radicals involves O‐atom transfer from peroxyl to Te followed by H‐atom transfer from amine to alkoxyl radical in a solvent cage.     

Ethylene Oligomerization by 8—Aminoquinoline Nickel Dichloride Complex Supported on β—Cyclodextrin

IntroductionSincetheexcellentcapabilityoflatetransitionmetalcomplexesforolefinpolymerization ,wasdiscoveredbyBrookhart1andGibson2 ,theinterestinthesecatalystshasgreatlyincreasedinbothacademicandindustrialresearches.3Unfortunately,intheolefinpolymerizationprocessinitiatedbylatetransitionmetalcomplexes,thepolyolefinsproducedoftendepositatthereactorwallsandstirringdevice ,whichwillbedisadvantageoustothefurtherapplicationofthesecat alysts.Inordertoovercometheseproblems,theheteroge nizationoftheho…     

Structural Diversity in the Self‐assembly of Cd(II) Complexes Containing 2,6‐Dimethyl‐3,5‐dicyano‐4‐(4‐pyridyl)‐1,4‐dihydropyridine

The syntheses, structures and properties of the complexes [CdBr₂( L )₂·4H₂O]_n [ L = 2,6‐dimethyl‐3,5‐dicyano‐4‐(4‐pyridyl)‐1,4‐dihydropyridine], 1 and [Cd(SCN)₂( L )₂(H₂O)]_n, 2 , are reported. In polymeric complexes 1 — 2 , the L ligands bridge the metal centers through the pyrimidyl and cyano nitrogen atoms forming 1‐D double‐stranded chain and zigzag chain, respectively. The L ligands in complex 1 act as κ1, κ1‐bidentate bridging ligand, whereas the L ligands in complex 2 act as κ1‐monodentae and κ1, κ1‐bidentate bridging ligand. The molecules of these complexes are interlinked through various weak interactions that form the packed structure. All the complexes exhibit emissions which may be tentatively assigned as intraligand (IL) π→π* transitions.     

Site‐Specific Iron Substitution in STA‐28, a Large Pore Aluminophosphate Zeotype Prepared by Using 1,10‐Phenanthrolines as Framework‐Bound Templates

An AlPO₄ zeotype has been prepared using the aromatic diamine 1,10‐phenanthroline and some of its methylated analogues as templates. In each case the two template N atoms bind to a specific framework Al site to expand its coordination to the unusual octahedral AlO₄N₂ environment. Furthermore, using this framework‐bound template, Fe atoms can be included selectively at this site in the framework by direct synthesis, as confirmed by annular dark field scanning transmission electron microscopy and Rietveld refinement. Calcination removes the organic molecules to give large pore framework solids, with BET surface areas up to 540 m² g^?1 and two perpendicular sets of channels that intersect to give pore space connected by 12‐ring openings along all crystallographic directions.     

A Novel Role of Vesicles as Templates for the Oxidation and Oligomerization of p‐Aminodiphenylamine by Cytochrome c

The oxidation and subsequent oligo‐ or polymerization of aniline or the N‐C‐para coupled aniline dimer p‐aminodiphenylamine (N‐phenyl‐1,4‐phenylenediamine) with H₂O₂‐dependent heme peroxidases in aqueous medium at pH = 4.3 is strongly influenced in a positive way by the presence of anionic polymers, micelles or vesicles as soft ‘templates’ (macromolecular or polymolecular additives), to yield products which resemble the emeraldine salt form of polyaniline (PANI‐ES). The positive effect the templates exert on the reaction mainly originates from interactions between the templates and the monomers, reaction intermediates and products, whereby the reaction occurs localized in the vicinity of the templates, suppressing undesired side reactions. As shown in the present work, the templates may even play an additional role, depending on the type of catalyst. Through interactions between the heme protein cytochrome c and anionic vesicles, cytochrome c gains increased peroxidase activity. In this way, the templates not only serve for hosting the oxidation and oligo‐ or polymerization reactions for obtaining PANI‐ES type products, but also simultaneously activate the catalyst in order to trigger the reaction.     

N,N′‐Diethyl‐4‐nitrobenzene‐1,3‐diamine, 2,6‐bis(ethylamino)‐3‐nitrobenzonitrile and bis(4‐ethylamino‐3‐nitrophenyl) sulfone

N,N′‐Diethyl‐4‐nitrobenzene‐1,3‐diamine, C₁₀H₁₅N₃O₂, (I), crystallizes with two independent molecules in the asymmetric unit, both of which are nearly planar. The molecules differ in the conformation of the ethylamine group trans to the nitro group. Both molecules contain intramolecular N—H...O hydrogen bonds between the adjacent amine and nitro groups and are linked into one‐dimensional chains by intermolecular N—H...O hydrogen bonds. The chains are organized in layers parallel to (101) with separations of ca 3.4 Å between adjacent sheets. The packing is quite different from what was observed in isomeric 1,3‐bis(ethylamino)‐2‐nitrobenzene. 2,6‐Bis(ethylamino)‐3‐nitrobenzonitrile, C₁₁H₁₄N₄O₂, (II), differs from (I) only in the presence of the nitrile functionality between the two ethylamine groups. Compound (II) crystallizes with one unique molecule in the asymmetric unit. In contrast with (I), one of the ethylamine groups, which is disordered over two sites with occupancies of 0.75 and 0.25, is positioned so that the methyl group is directed out of the plane of the ring by approximately 85°. This ethylamine group forms an intramolecular N—H...O hydrogen bond with the adjacent nitro group. The packing in (II) is very different from that in (I). Molecules of (II) are linked by both intermolecular amine–nitro N—H...O and amine–nitrile N—H...N hydrogen bonds into a two‐dimensional network in the (10) plane. Alternating molecules are approximately orthogonal to one another, indicating that π–π interactions are not a significant factor in the packing. Bis(4‐ethylamino‐3‐nitrophenyl) sulfone, C₁₆H₁₈N₄O₆S, (III), contains the same ortho nitro/ethylamine pairing as in (I), with the position para to the nitro group occupied by the sulfone instead of a second ethylamine group. Each 4‐ethylamino‐3‐nitrobenzene moiety is nearly planar and contains the typical intramolecular N—H...O hydrogen bond. Due to the tetrahedral geometry about the S atom, the molecules of (III) adopt an overall V shape. There are no intermolecular amine–nitro hydrogen bonds. Rather, each amine H atom has a long (H...O ca 2.8 Å) interaction with one of the sulfone O atoms. Molecules of (III) are thus linked by amine–sulfone N—H...O hydrogen bonds into zigzag double chains running along [001]. Taken together, these structures demonstrate that small changes in the functionalization of ethylamine–nitroarenes cause significant differences in the intermolecular interactions and packing.     

Synthesis of a Thymidine Dimer Containing a Tetrazole‐2,5‐diyl Internucleosidic Linkage and Its Insertion into Oligodeoxynucleotides

Thymidine dimers in which the natural phosphodiester linkage has been replaced by a 2,5‐disubstituted tetrazole ring are synthesized and incorporated into oligodeoxynucleotides (ODNs). The synthesis is accomplished by two strategies based on an alkylation of 5′‐O‐trityl‐on and 5′‐O‐trityl‐off 3′‐deoxy‐3′‐(1H‐tetrazol‐5‐yl)thymidines with 5′‐iodo‐5′‐deoxythymidine in the presence of Et₃N, and the formation of only 2‐substituted tetrazol‐5‐yl linkages is observed in 89 and 46% yields, respectively. The nucleoside dimer formed is reacted with 4,4′‐dimethoxytrityl chloride (DMTCl), followed by treatment with 2‐cyanoethyl tetraisopropylphosphordiamidite in the presence of N,N‐diisopropylammonium tetrazolide, to afford the 5′‐O‐DMT‐protected dinucleoside phosphoramidite that is used for incorporation into ODNs on an automated DNA synthesizer. The modified ODNs with one and up to five tetrazole internucleosidic linkages are obtained in good yields. The thermal stability of DNA/DNA and DNA/RNA duplexes is studied by UV experiments and reported also.     

Crystal Structure and Ethylene Oligomerization Catalytic Activity of {2-Carbethoxy-6-[1-[（2,6-diethylphenyl）imino]ethyl]pyridine}CoCl2

The unsymmetric precursor ethyl 6-acetylpyridine-2-carboxylate （4） was synthesized from 2,6-dimethylpyridine （1）. On the basis of this precursor, a new mono（imino）pyridine ligand （5） and the corresponding Co（Ⅱ） complex {2-carbethoxy-6-[1-[（2,6-diethylphenyl）imino]ethyl]pyridine}CoCl2 （6） were prepared. The crystal structure of complex indicates that the 2-carbethoxy-6-iminopyridine is coordinated to the cobalt as a tridentate ligand using [N, N, O] atoms, and the coordination geometry of the central cobalt is a distorted trigonal bipyramid, with the pyridyl nitrogen atom and the two chlorine atoms forming the equatorial plane. Being applied to the ethylene oligomedzation, this cobalt complex shows catalytic activity of 1.820× 10^4 g/mol-Cooh at 101325 Pa of ethylene at 15.5℃ for 1 h, when 1000 equiv, of methylaluminoxane （MAO） is employed as the cocatalyst.     

Solvent and structural effects on the oxidation of 2,6‐diphenyl‐piperidin‐4‐ones by quinolinium chlorochromate

The kinetics of oxidation of 3‐R‐2,6‐diphenyl‐piperidin‐4‐ones (where R = H, Me, Et, and i‐Pr) by quinolinium chlorochromate has been studied under pseudo‐first‐order conditions in different pure (protic and aprotic) solvents. The rate data is correlated with different solvent parameters using linear multiple regression analysis. From the regression coefficients, information on the solvent–reactant and the solvent–transition state interactions is obtained and the solvation models are proposed. Reasons for the difference in reactivity with structure are also discussed. © 2002 Wiley Periodicals, Inc. Int J Chem Kinet 34: 585–588, 2002     

Effect of urea on analyte complexation by 2,6‐dimethyl‐β‐CD in peptide enantioseparations by CE

The aim of the present study was the investigation of the effect of urea on analyte complexation in CD‐mediated separations of peptide enantiomers by CE in the pH range of about 2–5. pH‐independent complexation and mobility parameters in the absence and presence of 2 M urea were obtained by three‐dimensional, non‐linear curve fitting of the effective analyte mobility as a function of pH and heptakis‐(2,6‐di‐O‐methyl)‐β‐CD concentration. Urea led to decreased binding strength of the CD towards the protonated and neutral analyte enantiomers as well as to decreased mobilities of the free analytes. In contrast, mobilities of the fully protonated enantiomer–CD complexes as well as the pK_a values of the free and complexed analytes increased. The effect of urea on separation efficiency varied with pH and CD concentration. In the case of Ala‐Tyr and Ala‐Phe, separations improved in the presence of urea at pH 2.2. In contrast, separations were impaired by urea at pH 3.8 and low concentrations of the CD. Decreased separation efficiency was noted for Asp‐PheOMe and Glu‐PheNH₂ at low CD concentrations when urea was added but separations improved at higher CD concentrations over the entire pH range studied. The effect of urea on analyte complexation appeared to be primarily non‐stereoselective. Furthermore, the pH‐dependent reversal of the enantiomer migration order observed for Ala‐Tyr and Ala‐Phe can be rationalized by the complexation and mobility parameters.     

Synthesis of Purine‐based Triazoles by Copper (I)‐catalyzed Huisgen Azide–Alkyne Cycloaddition Reaction

An efficient protocol for the synthesis of substituted 1,2,3‐triazol‐9H‐purines via copper (I)‐catalyzed click chemistry of 2,6‐dichloropurine with aromatic azide has been reported. A wide range of 1,4‐disubstituted triazoles ( N‐9 substituted purines) was accessible in good‐to‐excellent yields with remarkable functional group tolerance. The base‐catalyst ratio was tuned to achieve optimum reaction condition (>95% conversion and purity in most cases). Furthermore, the structure of 4i has been unambiguously assigned by X‐ray crystallographic study to yield structural information on the 1,3‐dipoles entering the reaction.     

A Nine‐Coordinated ZrIV Complex and a Self‐Assembling System Obtained from a Proton Transfer Compound Containing 2,6‐Pyridinedicarboxylate and 2,6‐Pyridinediammonium; Synthesis and X‐ray Crystal Structure

Starting with a zirconium salt and LH₂ , (pydaH₂)²⁺(pydc)^2?, (pyda=2, 6‐pyridinediamine; pydcH₂=2,6‐pyridinedicarboxylic acid), as a 1:1 proton transfer self‐associated compound, two different compounds were resulted. One of them is a new complex of Zr^IV with a flat pyridine containing ligand and structure of (pydaH)₂[Zr(pydc)₃] · 5H₂O (1) and the other, (pydaH)⁺(NO₃)^? (2) is an ion pair with no zirconium ion. The zirconium(IV) complex (1) is crystallized in triclinic system with space group and Z = 2, the crystallographic parameters are: a = 10.612(5) Å, b = 10.617(5) Å, c = 16.815(8) Å, α = 103.654(9)°, β = 95.821(9)°, γ = 98.891(9)° and R‐value for 16767 collected reflections is 0.0592. The ion pair (2) has crystals of monoclinic system with P2₁ space group and Z = 2. Its crystallographic parameters are: a = 3.6227(11) Å, b = 10.034(4) Å, c = 10.296(4) Å, β = 93.422(9)° and R‐value for 4031 collected reflections is 0.0521. The two compounds were characterized with elemental analysis, ESI/MS, NMR and IR spectroscopy.     

Synthesis and Luminescence of Eu‐N2,N6‐Bis(2‐hydroxyethyl)pyridine‐2,6‐dicarboxamide Complexes Containing Mesoporous Material

Ligand N²,N⁶‐bis(2‐hydroxyethyl)pyridine‐2,6‐dicarboxamide (L=BHPC) was synthesized and used to construct lanthanide‐based mesoporous material Eu‐L‐MCM‐41. In the structure of resulting Eu‐L‐MCM‐41, Eu³⁺ was chelated by BHPC, and the Eu‐L complexes were anchored into the forming MCM‐41 host by the reaction between the hydroxyl group and active Si‐OH. The mesoporous material Eu‐L‐MCM‐41 was characterized by UV, IR, small‐angle X‐ray diffraction (SAXRD) patterns, nitrogen adsorption/desorption isotherms, TGA and fluorescence spectra. The results indicate that ligand and Eu³⁺ have been introduced into the MCM‐41 host, and Eu‐L‐MCM‐41 exhibits characteristic luminescence of Eu³⁺.     

GM1 Ganglioside Inhibits β‐Amyloid Oligomerization Induced by Sphingomyelin

β‐Amyloid (Aβ) oligomers are neurotoxic and implicated in Alzheimer's disease. Neuronal plasma membranes may mediate formation of Aβ oligomers in vivo. Membrane components sphingomyelin and GM₁ have been shown to promote aggregation of Aβ; however, these studies were performed under extreme, non‐physiological conditions. We demonstrate that physiological levels of GM₁, organized in nanodomains do not seed oligomerization of Aβ₄₀ monomers. We show that sphingomyelin triggers oligomerization of Aβ₄₀ and that GM₁ is counteractive thus preventing oligomerization. We propose a molecular explanation that is supported by all‐atom molecular dynamics simulations. The preventive role of GM₁ in the oligomerization of Aβ₄₀ suggests that decreasing levels of GM₁ in the brain, for example, due to aging, could reduce protection against Aβ oligomerization and contribute to the onset of Alzheimer's disease.