Antipyrilquinoneimine dye formation by coupling aniline derivatives with 4-aminoantipyrine in the presence of ruthenium nanoparticles

The coupling of 4-aminoantipyrine (4-AAP) with aniline derivatives catalyzed by ruthenium nanoparticles (Rnp) has been studied by UV-Vis spectroscopy in aqueous medium. The rate constant for antipyrilquinoneimine dye formation depends on the nature of the aniline substituent and the pH, ionic strength and temperature of the reaction medium. The maximum rate constant of the dye formation reaction is observed at pH 3.6. Aniline derivatives with electron donating substituents show higher rate constant values than those with electron withdrawing substituents, with increasing rate constant values in the order: N,N-dimethyl aniline > o-toluidine > o-chloroaniline > m-chloroaniline. With pseudo first order kinetics, the total order is 1.0 + 1.0 + 1.0 = 3.0, which includes the orders with respect to amine, 4-AAP and Rnp. Studies on these effects help to complete the kinetic analysis as well as propose the reaction pathway. Furthermore, TEM measurement confirms that the nanoscalar size of the Rnp is 7 nm.     

Addition conjuguée dans le thf-hmpt d'arylacétonitriles lithies aux cyclohexèn-2 ones substituées: intervention des facteurs stériques et électroniques

The reaction of lithiated arylacetonitriles 2a-c with 2-cyclohexenones 3-9 in THF-HMPA (80:20 v/v) at ?70° leads in all cases but one to δ-ketoalkylnitriles, resulting from 1,4-addition. The only case where some 1,2-addition takes place is the reaction of 2a with 4,4-dimethyl 2-cyclohexenone 7. The formation of allylic alcoholates, products of 1,2-addition, is shown to be reversible in this solvent mixture. However, in several cases, kinetic control of 1,4-addition is demonstrated. The rate of formation of 1,4-addition products depends upon the arylacetonitrile substituents: 2a >2b >2c (i.e. the higher lying the nucleophile HOMO the faster the reaction). It is also sensitive to the cyclohexenone substituents; although methyl on C-2 and gem-dimethyl on C-5 or t-butyl on C-4 have small influence on the reaction rate, methyl on C-3 or gem dimethyl on C-4 induce a noticeable rate decrease. The addition, of 2b on 4-t-butyl 2-cyclohexenone 8 leads, at the early stage, to a predominating isomer 15b, to which the trans diaxial configuration of the substituents has been attributed by 250 MHz ¹H NMR. A single transition state model, reagent-like, where the nucleophile approaches the C-C bond by the less hindered face of the 2-cyclohexenone in a 1,2-diplanar conformation, the CN substituent being directed towards the C=0 group, accounts for all the substituent effects and the stereoselectivity observed.     

The effect of aryl substituents on arylcarbene reactivity

Substituted (p-MeO, p-Me, H, p-Cl, p-Br, m-Br, m-MeO, 3,4-Cl₂, p-CO₂Me, m-CN and p-CN) monophenylcarbenes are generated in a binary mixture of substrates (methanol, cis-4-methyl-2-pentene and cyclohexane) and the relative rate of O—H insertion into methanol to stereospecific cyclopropanation of the olefin to C—H insertion into cyclohexane are calculated from the ratios of products and substrates. It is found (i) that the reactivities of the substrates decrease in the order of methanol, olefin and cyclohexane and (ii) that electron-donating substituents generally lead to reaction with the more reactive substrates while the reaction with the less reactive substrates is favoured in the case of electron-withdrawing substituents. These results are interpreted in terms of the change in the electrophilicity of the singlet arylcarbene by the substituents rather than the change in the singlet-triplet equilibrium.     

Substituent effects of pyrazine on construction of crystal structures of Zn(II)-benzoate complexes and their catalytic activities (dinuclear,trinuclear, and pentanuclear to 1-D and 2-D)

Several substituted pyrazine ligands (2,3-dimethylpyrazine, 2,6-dimethylpyrazine, 2,5-dimethylpyrazine, quinoxaline) as well as simple pyrazine have been employed to investigate how the bridging pyrazine ligand influences on construction of Zn-benzoate complexes. Simple pyrazine and 2,5-dimethlpyrazine are used as bridging ligands to form two-dimensional and one-dimensional polymeric compounds, respectively. The other quinoxaline and two dimethyl-substituted pyrazine ligands are used only as terminal ligands to form dinuclear, trinuclear, and pentanuclear complexes. This result indicates that the substituents of pyrazine are very important roles for construction of Zn-benzoate complexes. Interestingly, the compounds 1–5 catalyzed efficiently the transesterification of a variety of esters, and among them, the pentanuclear complex 3 showed the most efficient reactivity. The substrates with the electron-withdrawing substituents have undergone faster transesterification, while those with the electron-donating ones have shown slow reaction. In addition, p-nitrophenyl acetate and p-nitrophenyl benzoate, known to be problematic substrates for the transesterification reaction, were also converted quantitatively to the corresponding products. Selectivity test of primary over secondary alcohol protection in the presence of 3 has provided, exclusively, the primary acetate, propyl acetate, suggesting that this catalytic system can be potentially useful in selecting for primary alcohols.     

Structure-dependent reversible mechanochromism of D-π-A triphenylamine derivatives

Three simple non-planar D-π-A TPA-based isomers (TPA-o, TPA-m, and TPA-p) were designed and synthesized via Suzuki reaction with higher yields. It was found that all of the three compounds had intramolecular charge transfer (ICT) properties resulting from electron donation from triphenylamine to the formyl moiety. Interestingly, TPA-based derivatives solids exhibited not only reversible mechanochromic behaviors, but structure-dependent emission properties. The solid emission studies illustrated that their fluorescence color could change reversibly between bright blue (455?nm), blue (445?nm), cyan (479?nm), and bright blue-green (497?nm), bright blue (460?nm), yellowish-green (511?nm) through grinding and dichloromethane (DCM) fuming treatment, giving the large spectral red-shifts of 42, 15, and 32?nm, respectively. The MFC activities of the three compounds are increased with the sequence of TPA-o (42?nm)?>?TPA-p (32?nm)?>?TPA-m (15?nm). The single crystal structure, powder X-ray diffraction (PXRD) and DSC studies indicated that the reversible phase change from crystalline to amorphous was responsible for MFC properties. This work demonstrated the feasibility of tuning the solid-state optical properties of fluorescent organic compounds by combining the simple alteration of chemical structure and the physical change of aggregate morphology under external stimuli. And these results will be of great help in understanding structure-property relationships of MFC mechanisms and designing new more MFC materials.     

Operationally convenient asymmetric synthesis of (S)-2-amino-3,3-bis-(4-fluorophenyl)propanoic acid

This study demonstrated that alkylation of chiral glycine Schiff base 3 with chloride 4 can be efficiently conducted in acetonitrile as a solvent using commercial-grade potassium tert-butoxide as a base. High reaction rate (1 h) chemical (>90%) and stereochemical (>95% de) outcomes of the alkylation step render this procedure reliable and operationally convenient for multi-gram synthesis of enantiomerically pure amino acid 1. Due to the simplicity of experimental procedures and commercial availability all reagents involved, this procedure can be easily reproduced in regular biochemistry laboratories allowing for systematic biological studies and medicinal applications of compound 1.     

Polymerization and properties of optically active α-(p-substituted benzenesulfonamido)-β-lactones

Optically active α-(p-substituted benzenesulfonamido)-β-lactones having as para substituents OMe, Me, H, and Cl were polymerized in bulk, in ethyl acetate solution with triethylamine or betaine, and in dioxane with butyllithium as initiators. The rate of polymerization was followed by the change of specific rotation with time and was decreasing in following order of para substituents: OMe > Me > H > Cl. The relative reactivity in logarithmic form was plotted against Hammett's σ functions showing a linear relationship with reaction constant ρ = ?0.57.     

Asymmetric epoxidation of cinnamic acid derivatives by in situ generated dioxiranes of chloroacetones: scope and limitations

Efficient epoxidation of chiral cinnamic acid derivatives has been achieved by in situ generated dioxiranes of chloroacetones with moderate to good diastereoselectivity (dr up to 90:10) in high yields. Reactivity of cinnamic acid derivatives containing different chiral auxiliaries versus chloroacetones–monochloroacetone 3 (MCA), 1,1-dichloroacetone 4 (DCA) and 1,1,1-trichloroacetone 5 (TCA) and Oxone? loading was studied. Both Oxone? loading and reaction time reduce with an increase of chlorine atoms in the acetone. The use of 1.1 equiv of TCA was found to be effective for the epoxidation of cinnamate substrates and enhances the reaction up to 4–10-fold compared to acetone and that also decreases the Oxone? loading. This method provided methyl (2R,3S)-3-(4-methoxyphenyl)glycidate (?)-2, a key intermediate for the synthesis of diltiazem hydrochloride, with >99% of enantiomeric purity.     

Efficient double bond migration of allylbenzenes catalyzed by Pd(OAc)2-HFIP system with unique substituent effect

A novel catalyst system of Pd(OAc)₂-HFIP induces double-bond migration of allylbenzenes under mild conditions with low catalytic loading to afford 1-propenylbenzenes. The reaction shows a unique substituent effect that is highly dependent on the distance of substituents from the allylic moiety. Thus, the reactivity of substrates bearing a methyl group is ordered in para > meta > ortho, whereas it is entirely reversed as ortho > meta > para for methoxy and chloro substituents.     

Substrate engineering: Effects of different N-protecting groups in the CAL-B-catalysed asymmetric O-acylation of 1-hydroxymethyl-tetrahydro-β-carbolines

In the frame of substrate engineering, the steric effect of different N-protecting groups on the enantioselectivity and reaction rate of CAL-B-catalysed (S)-selective O-acylation of N-protected 1-hydroxymethyl-tetrahydro-β-carbolines was investigated. Excellent enantioselectivities (E?>?200) were observed when the acylation of N-Boc [(±)-1], N-Cbz [(±)-3], and N-Fmoc-protected [(±)-4] substrates was performed with the use of CAL-B and acetic anhydride in toluene at 60?°C. The resolution of N-acetyl-protected substrate (±)-2 showed excellent E (>200) after 30?min, but as the reaction progressed, E started decreasing after 2 days, because of N→O and O→N acyl migrations. Preparative resolutions of (±)-3 and (±)-4 resulted in unreacted amino alcohols (R)-3 and (R)-4 and esters (S)-7a and (S)-8a with good enantiomeric excesses (≥88%) and high yields (≥44%).     

Spin selectivity in the oxygenation of singlet phenylhalocarbenes with oxygen

Singlet phenylhalocarbenes are shown to react with triplet oxygen and the apparent spin-forbidden oxygenation rates are strongly dependent on substituents, i.e. in the decreasing order of Br>Cl?F for halogen and of p-NO₂>H?p-MeO for p-substituents. These results suggest the oxygenation of triplet halocarbene equilibrated with ground-state singlet, resulting in the first estimation of energy difference between the singlet and triplet states.     

The reaction of B-alkyl-9-borabicyclo[3.3.1]nonanes with aldehydes and ketones. A facile elimination of the alkyl group by aldehydes

Certain B-alkyl-9-borabicyclo[3.3.1]nonanes (9-BBN) reduce benzaldehyde to benzyl alcohol under exceptionally mild conditions. Factors which contribute to a high rate of reaction include: an increase in the degree of substitution at the position β to the boron (isobutyl > 1-butyl >> ethyl), the ability of the alkyl group to form a syn-planar B—C—C—H conformation (cyclopentyl ? norbornyl > sec-butyl >> cyclohexyl), and the presence of an electron-withdrawing para-substituent on the benzaldehyde (p-Cl > p-H > p-CH₃O). The B-alkyl group is transformed into an olefin as the benzaldehyde is reduced. Elimination takes place predominantly if not exclusively towards the more highly substituted β hydrogen. The reaction obeys second order kinetics. The observations are consistent with a cyclic mechanism rather than a dehydroboration-reduction pathway.     

Synthesis of unsymmetrical biaryl ureas from N-carbamoylimidazoles: kinetics and application

N-Carbamoylimidazoles dissociate in solution to yield imidazole and an isocyanate that may be reacted with another aryl amine to form an unsymmetrical biaryl urea. This paper investigates the reaction kinetics and the influence of electron withdrawing/donating substituents on the reaction of N-carbamoylimidazoles with aniline. The overall reaction mechanism involves two zwitterionic intermediates, formed during dissociation and upon reaction of the liberated isocyanate with aniline. The rate limiting step for the reaction is a base catalysed proton transfer from the second zwitterionic intermediate. Although electron withdrawing substituents on the aryl group hinder dissociation, they significantly increase reaction rates compared to compounds bearing electron donating substituents. The imidazole liberated upon dissociation catalyses the rate determining step so that reactions of dissociated N-carbamoylimidazoles proceed more rapidly than those involving only isocyanates. In addition, the imidazole eliminates the need for anhydrous reaction conditions. The N-carbamoylimidazole methodology was demonstrated by preparing sorafenib, a biaryl urea kinase inhibitor, in good yield and excellent purity.     

Asymmetric addition of diethylzinc to aromatic aldehydes by chiral ferrocene-based catalysts

A series of chiral C₁- and C₂-symmetric ferrocenyl Schiff bases (1a-c), ferrocenyl aminoalcohols (2a), ferrocenylphosphinamides (2b-c), 1,1′-ferrocenyl-diol (3), and 1,1′-ferrocenyl-disulfonamide (4) were prepared and employed as base catalysts or as ligand for titanium(IV) complexes in the asymmetric addition of diethylzinc to aromatic aldehydes. High enantioselectivity up to almost 100% ee was achieved for the alkylation of benzaldehyde and p-methoxybenzaldehyde with 1 or 3. In contrast, however, the β-aminoalcohol (2a) and phosphinamides (2b and c) that are ubiquitous classes of base catalysts for this reaction proved inefficient in our hands, regardless of the types of substrates or reaction conditions. Comparative studies show that there exist various reaction parameters governing not only chemical yields but also optical yields. These include steric and electronic environment of the substrate, the solvent, the reaction temperature, and the nature of the ferrocene moieties.     

Solvolysis of 2-aryl-exo-5,6-trimethylene-2-norbornyl p-nitrobenzoates as a reference of 2-aryl-2-norbornyl p-nitrobenzoates solvolysis: Further evidence for the unimportance of σ-participation in the solvolysis of 2-aryl-2-norbornyl derivatives

The rates of solvolysis of 2 - aryl - exo - 5,6 - trimethylene - exo - and endo - 2 - norbornyl p-nitrobenzoates (7 and 8, respectively) with representative substituents [p-CH₃O, p-CH₃, H, m-CF₃, p-CF₃, and 3,5-(CF₃)₂] were determined in 80% aqueous acetone and compared with those of the parent 2-aryl-exo- and endo-2-norbornyl p-nitrobenzoates (5 and 6, respectively). The rate ratios for the endo-p-nitrobenzoates ($\text{6}\text{8}$) are essentially constant and close to unity for these substituents, indicating that the perturbation of the trimethylene bridge toward the C₂-position is virtually negligilbe. The rate ratios for the exo-p-nitrobenzoates ($\text{5}\text{7}$) can also be regarded as invariant over the reactivity range studied. The exo/endo rate ratios ($\text{7}\text{8}$) are 246 (p-CH₃O), 196 (P-CH₃), 129 (H), 80 (m-CF₃), 90 (p-CF₃), and 89 [3,5-(CF₃)₂], being similar to the corresponding $\text{5}\text{6}$ rate ratios. The solvolyses of these p-nitrobenzoates (7 and 8) afford predominantly ( > 97%) exo-alcohols. Since the secondary exo-5,6-trimethylene-2-norbornyl system, with its low exo/endo rate ratio, 11.2, is known to solvolyse without significant σ-participation, the tertiary derivatives should also undergo solvolysis without σ-participation. Consequently, the similarities in the solvolytic behaviors between the two systems (5 vs 7; 6 vs 8) strongly support the previous conclusion that σ-participation is unimportant in the solvolysis of 5.     

Mechanistic studies of DCC/HOBt-mediated reaction of 3-phenylpropionic acid with benzyl alcohol and studies on the reactivities of ‘active ester’ and the related derivatives with nucleophiles

Despite of the extensive study for peptide synthesis, DCC-mediated esterification is left still unclear. Therefore, DCC- and DCC/HOBt-mediated reactions of 3-phenylpropionic acid (1) with benzyl alcohol were carried out under several mechanistic considerations. Further, in order to determine the reactivities of the so-called ‘active esters’ compounds changing the substituents bearing carbonyl and related derivatives group for the purpose of the development of new class of non-symmetry cross-linkers, we have studied the reaction of model compounds, N-(3-phenylpropionyloxy)benzotriazole (6), N-(3-phenylpropionyloxy)phthalimide (7), 3-phenylpropionyloxybenzothiazole (8), and N-(3-phenylpropionyl)benzotriazole (9) with various nucleophiles under similar conditions were carried out for the comparison. It was revealed to exhibit the order of 6>>8>9>7.     

The first example of asymmetric Michael reaction catalyzed by chiral alkali metal alkoxides

Some chiral sodium alkoxides can be used as catalysts in the asymmetric Michael reaction as exemplified by the 1,4-addition of an achiral Ni^II complex of the Schiff base derived from glycine andN-(2-pyridylcarbonyl)-o-aminobenzophenone (1) to methyl methacrylate (2) or methyl acrylate (14). The products of the reaction of1 with2,viz., the corresponding diastereomeric complexes of 4-methylglutamic acid, are formed in dissimilar amounts (de 26–85%); theee value for the major diastereomer (2S,4R)-3a is 28%. After recrystallization, the enantiomeric purity of complex3a increases toee>85%. Acidcatalyzed hydrolysis of the enantiomerically enriched complex3a affords (2S,4R)-4-methylglutamic acid (ee>85%). The complex of glutamic acid15 resulting from the reaction of1 with14 is formed with anee of 45%. After recrystallization, the enantiomeric purities of complex15 and glutamic acid increase toee>90%.     

Chemistry of alkali metal-unsaturated hydrocarbon adducts : X. Electron-transfer reactions of α, β-unsaturated organosilanes

The chemical behavior of alkali metal adducts of α,β-unsaturated organosilanes was investigated by generating the adducts with lithium or potassium metal in donor solvents at ?78°C and studying the ensuing reduction, bimolecular coupling, cleavage and isomerization processes. Chosen for study were the triphenylvinyl derivatives of silicon, germanium and tin, as well as other vinyl-, phenyl-, allyl-, 1,3-alkadienyl-, 1-alkynyl- and cyclopropyl-silanes. By assessing gradations in substituent reactivity toward alkali metal, an empirical ordering of electron affinity for these substituents on silicon was determined: 1,3-alkadienyl > 1-alkynyl > 1-alkenyl > phenyl > > 2-alkenyl or cyclopropyl. Where available, ESR data were used to explain the reactivity and the reaction pathway observed for radical anion intermediates. Where such information was unobtainable, the behavior of unstable radical anions was ascribed to variations in p_π → d_π stabilization.     

Synthesis of arylated chalcone derivatives via palladium cross-coupling reactions

A useful protocol for arylation of the olefin double bond of chalcones to afford tri- and tetra-substituted chalcone derivatives is reported. The protocol begins with the Heck reaction between chalcones and aryl iodides providing β-arylchalcones. This reaction tolerates various functional groups on both rings, as well as deactivated aryl iodides. The products are obtained in moderate to excellent yields and the (E)-β-arylchalcones (E:Z?>?96:4) can be isolated via precipitation. Competitive Heck reactions pointed to a significant effect of ring one substituents on the reaction rate, while substituents on ring two have a much smaller effect. To access α,β-diarylchalcones, a sequential bromination-Suzuki cross coupling strategy was applied to the β-arylated compounds which afforded double arylated chalcone derivatives in 60–99% yield over two steps.     

Novel, biologically imperative, highly versatile and planar systems: Synthesis, characterization, electrochemical behavior, DNA binding and cleavage properties of substituted β-diketimine copper(II) and zinc(II) complexes with dipyrido(3,2-a:2′, 3′ -c)phenazine ligand

Novel copper(II) and zinc(II) complexes of the type [ML(dppz)]Cl₂, [L = Schiff base derived from the condensation of 3-(3- phenyl-allylidene)-pentane-2,4-dione and para-substituted aniline; X = -NO₂ (L¹), -H (L²), -OH (L³) and -OCH₃ (L⁴); dppz = dipyrido (3,2-a:2′, 3′ -c)phenazine] were synthesized and characterized by various analytical and spectral techniques. The physicochemical studies and spectral data indicated that all the complexes were monomeric and cationic with square-planar geometry. Spectroscopic data and viscosity measurements showed that the complexes intercalated to DNA with large binding constants. The substituted groups such as -NO₂, -H, -OH and -OCH₃ in aniline moiety influenced the observed trend in the redox potentials of the complexes. The peak potential separation and formal potential of complexes were independent of sweep rate or scan rate (ν) indicating a quasireversible one-electron redox process. In all the cases, i _p was linear function of ν^1/2, as expected for diffusion controlled process, and i _pa/i _pc ≈ 1 at all sweep rates. It was found that the decrease in i _pc was due to the higher binding of copper complexes and slowly diffusing DNA. In the presence of a reducing agent like 3-mercaptopropionic acid (MPA), the chemical nuclease activity order of the copper complexes under dark reaction condition was -NO₂ > -H > -OH > -OCH₃. The hydrolytic cleavage of DNA by the zinc complexes was supported by the evidence from free radical quenching and T4 ligase ligation.