Synthese von ‘Push-Pull’-Oligoacetylenen

Synthesis of ‘Push-Pull’-OligoAcetylenes ‘Push-pull’ triacetylenes 11a , b , c , as well as ‘push-pull’ tetraacetylene 13b have been prepared by reaction of the corresponding trichloroene(oligoinyl)amines 9 and 10 with 2 mol-equiv. of BuLi followed by acylation. The sequences (Schemes 3 and 4) are very simple and straightforward, they could in principle be applied to the synthesis of ‘push-pull’ pentaAcetylenes 15 and hexaacetylenes 17 (Scheme 5). Main limitations are the moderate yields as well as the low thermal stability of push-pull oligoacetylenes.     

Synthese, 13C-NMR-Spektren und räumliche Struktur von ‘Push-Pull’-Diacetylenen

Synthesis, ¹³C-NMR Spectra, and X-Ray Investigation of ‘Push-Pull’ Diacetylenes Phenyl-substituted ‘push-pull’ diacetylenes 1f and 1g have been prepared by acetylation and benzoylation of the appropriate lithiodiynylamines 4 (Scheme 2). ¹³C-NMR spectra of diacetylenes 1a–g (Table 1) are discussed with respect to the expected polarisation of the diacetylene unit by ‘push’ and ‘pull’ substituents. X-Ray investigations of 1c , 1e , and 1f have been performed in view of the planned solid-state polymerisation of ‘push-pull’ diacetylenes. In the crystalline state, diacetylenes 1c and 1f are stacked, however, the stacking parameters do not allow a solid-state polymerisation.     

Der ‘Push-Pull’-Effekt von ‘Push-Pull’-Oligoacetylenen. Eine 13C-NMR-Untersuchung

The ‘Push-Poll’ Effect of ‘Push-Pull’ Oligoacetylenes. A ¹³C-NMR Investigation According to ¹³C-chemicaI shifts of ‘push-pull’ oligoacetylenes 1 – 4 , the ‘push-pull’ effect (i.e. π delocalization induced by ‘push-pull’ substituents) rapidly decays in this series. To correct for other than π -charge-density effects, Δδ values of symmetrically placed C-atoms of the oligoacetylene chain are discussed. Stereoelectronic resteffects (SER) of the substituents on terminal C-atoms of PP-ketones 1a – 3a and PP -esters 1b – 4b are estimated from the residual Δδ of the asymptotes of Fig. 3. Fig. 4 convincingly shows that Δδ values are dramatically decreasing with increasing number n of acetylene units between the push and pull substituents. Assignment problems of ‘push-pull’ triacetylenes 3 have been solved by ¹³C labelling of the CO group of 3a .     

“Push-Pull”-Acetylene für die Peptid-Synthese

“Push-Pull” Acetylenes as Reagents for Peptide Synthesis A series of ‘push-pull’ acetylenes 1 is easily available from the corresponding “push-pull” olefins by a simple bromination-dehydrobromination sequence. The versatility of the acetylenes with regard to peptide synthesis is discussed.     

Photoinduzierte Cycloadditionen von 2,2-Dimethyl-3-phenyl-2H-azirin an Nitrile und «push-pull»-Olefine. 43. Mitteilung über Photoreaktionen

Photoinduced Cycloadditions of 2,2-Dimethyl-3-phenyl-2H-azirine with Nitriles and ‘push-pull’ Olefines. Electron deficient nitriles of the type 5a–e in contrast to nonactivated nitriles undergo regiospecific [2+3]cycloadditions to benzonitrile isopropylide ( 2b ), which was generated in situ by irradiation of 2,2-dimethyl-3-phenyl-2H-azirine ( 1b ), to yield the 2H-imidazole derivatives 6a – e (Scheme 2). The structure of the photoproducts was mainly deduced from ¹³C-NMR. and mass spectrometry. Whereas normal olefins or enolethers do not react with 2b , push-pull olefins of the type 10a – d readily undergo the cycloaddition to give the 3-alkoxy-5,5-dimethyl-2-phenyl-1-pyrrolines 11a – d (Scheme 3 and 4). The structure of the photoproducts 11a – d indicates that the regiospecificity of the cycloaddition corresponds to that of acrylonitriles and acrylesters with 2b .     

«Push-Pull»-Acetylene als Hilfsmittel zur Synthese von Amiden

Amide Synthesis by Means of ‘Push-Pull’-Acetylenes ‘Push-Pull’-acetylenes react easily with carbon acids, Addition of amines to the crude reaction mixture gives amides in an excellent yield by a simple one-pot procedure. Because of the high selectivity of the acetylenes 1 towards carboxylic functions and of the high selectivity of the enol esters 4 towards amine functions, ‘push-pull’-acetylenes could be excellent reagents for peptide synthesis.     

«Push-Pull»-Acetylene als Hilfsmittel zur Synthese von Peptiden

Peptide synthesis by Means of ‘Push-Pull’-Acetylenes ‘Push-pull’-acetylenes 1 are excellent reagents for peptide synthesis: Addition of ‘push-pull’-acetylenes to solutions of N-protected amino acids (or vice versa) gives enol esters 5 , which react selectively with the amino function of a second amino acid. In this way serine, tyrosine, 4-hydroxyproline, cysteine as well as histidine are linked to form dipeptide esters without protection of the second functional group (OH, SH or NH). The amount of racemization is very low. Similarly tri- as well as tetrapeptides are available. The versatility of the reaction is discussed.     

Synthese von ‘Push-Pull’-Diacetylenen

Synthesis of ‘Push-Pull’ Diacetylenes The first synthesis of push-pull diacetylenes of type 1 is described. Reaction of perchlorobutenyne ( 8 ) with two equivalents of dialkylamine, followed by dechlorination using two equivalents of butyllithium gives lithio-dialkylamino-diynes 7 . Final acylation of these intermediates leads to push-pull diacetylenes 1b–1e in good yields. The method allows the introduction of both push and pull substituents in a simple one-pot-procedure. In addition, 1a is prepared by hydroxymethylation of lithio-morpholino-diyne 7c , followed by oxidation with manganese dioxide in acetone.     

Synthese neuer Heptafulvene,Röntgenstrukturanalyse von ‘8,8-(1′,4′-Dioxotetramethylen)heptafulven’(2-(Cyclohepta-2,4,6-trien-1-yliden)cyclopentan-1,3-dion)

Synthesis of New Heptafulvenes; X-Ray Analysis of ‘8,8-(1′,4′-Dioxotetramethylene)heptafulvene’ (2-(Cyclohepta-2,4,6-trien-1-ylidene)cyclopentane-1,3-dione) Experimental procedures for the synthesis of heptafulvene ( 3a ), 8,8-tetramethylene heptafulvene ( 3c ) and ‘8,8-(1′,4′-dioxotetramethylene) heptafulvene’ (2-(cyclohepta-2,4,6-trien-1-ylidene)-cyclopentane-1,3-dion; 3d ) are described. The most important sequences include a low-temperature reaction of tropylium salts with lithium or Grignard carbenoids (Scheme 1) to give 3a and 3b as well as hydride abstraction from substituted cycloheptatrienes followed by deprotonation to give 3c and 3d . Limitations of these sequences are discussed. Two other heptafulvenes 3h and 3i are available by silylation of heptafulvenolates according to well-known procedures. NMR-Spectroscopic evidence as well as an X-ray analysis of 3d are presented. Compound 3d is a relatively polar heptafulvene with a planarised seven-membered ring as well as a partly delocalized π system.     

The Crystal structure of 2-Diisopropylamino-3,7-dehydrotropone

Die erste Röntgenstrukturanalyse eines 3,7-Dehydrotropon ( 1 )-Derivates, nämlich von 2-Diisopropylammo-3,7-dehydrotropon ( 4 ) zeigt das Ringsystem in 4 als planaren Bicyclus mit nahezu C_2V-Symmetrie. Dementsprechend enthalten Dehydrotropone formell zwei trans-konfigurierte Doppelbindungen in einem 7-gliedrigen Ring; auch das O-Atom und das N-Atom mit seinen Ligandatomen liegen in derselben Ebene wie die Ringatome. Die Bindung zwischen den beiden C-Atomen, welche die Heteroatome tragen, (C(1) and C(2)), ist wesentlich langer (1,56 Å) als die anderen Bindungen im Ringsystem (1,37-1,46 Å). Dies impliziert eine ‘push-pull’-π-Elektronen-Delokalisierung, in der auch das O-und das N-Atom involviert sind, und macht eine ‘aromatische’ Ring-Delokalisierung weniger wahr-scheinlich. Im Gegensatz zu 2-(t-Butyl)-3,7-dehydrotropon ( 3 ) existiert das 2-Diiso-propylamino-3,7-dehydrotropon ( 4 ) im Kristall als Monomeres, was dem stabili-sierenden Einfluss der ‘push-pull’-Delokausierung zugeschrieben werden kann.     

Die Reaktion von 1-Halogeno-1-Lithiocyclopropanen mit CuCl2: Konkurrenz zwischen ‘Carben-Dimerisierung’ und oxidativer Kupplung

The Reaction of 1-Halogeno-1-lithiocyclopropanes with CuCl₂: Competition between ‘Carbene Dimerization’ and Oxidative Coupling The 1-chloro-1-lithiocyclopropanes 2a – d react at low temperature with CuCl₂ to give diastereoisomeric mixtures of oxidative-coupling products 5a – d and of ‘carbene dimers’ 6a–d . The relative amount of 5a – d increases with CuCl₂ concentration and reaction time. Diastereoselectivity of the reaction seems to be low, and separation as well as spectroscopic structure assignment of single diastereoselectivity of the reaction seems to be low, and separation as well as spectroscopic structure assignment of single diastereoisomers are difficult. The conformational behavior of 1,1′-dichloro-1,1′-bi(cyclopropyls) 5c and 5d is discussed. Contrary to 2a – d , 1-bromo-1-lithiocyclopropanes normally react with CuCl₂ to give ‘carbene dimers’ 6 and no coupling products 5 . So far the only exception is 1-bromo-1-lithio-2-phenylcyclopropane 2e which in the presence of CuCl₂ gives some percents of coupling products 5e besides carbene dimers 6b as main products. An X-ray structure analysis of the predominant diastereoisomer 5e was performed.     

Lewis acid catalysed [2+2] cycloreversion of cookson's cage ketones under ambient conditions: model system for light energy conversion

Design of ‘push-pull’ Cookson's cage ketones and their quantitative [2+2] cycloreversion to $\text{cis}$, $\text{syn}$, $\text{cis}$-triquinanes at room temp, under Lewis acid catalysis, is reported. This observation has promising ramifications on the utility of 1 2 system for reversible storage of solar energy.     

Synthese von β-D-Glucopyranosiden einiger hydroxylierter Vitamin-D-Verbindungen

Synthesis of β-D -Glucopyranosides of some Hydroxylated Vitamin-D Compounds Cholesta-5, 7-diene-1α, 3β-diol (1a) was glycosylated with ‘α-acetobromoglucose’ (2) as well as with ‘α-acetobromocellobiose’ (4) to yield the 3-(glycosides) 1b and 1c , respectively. Irradiation of these products with UV light followed by thermal isomerization led to the corresponding vitamin-D derivatives 3a and 3c. Direct glucosylation of vitamin D₃ (3f) and vitamin D₂ (5a) with 2 gave the derivatives 3g and 5b , respectively. With 25-hydroxycholecalciferol ( = calcidiol; 6a ) as substrate, besides the 3-(glucoside) 6b small amounts of the C(25)-analog 6c were formed. The reaction of 1α, 25-dihydroxycholecalciferol ( = calcitriol; 6e ) with 2 furnished the 3- and the 1-(glucoside) ( 6f and 6g , respectively) as the major components and the C(25)-analog 6h in minor quantity. From the acetylated 3-(glucosides) 3a, 3g, 5b, 6b , and 6f , the free glucopyranosides 3b, 3h, 5c, 6d , and 6i , respectively, were prepared as well as the free glucopy-ranosyl-glucopyranoside 3d from the acetylated disaccharide 3c.     

Synthesis and Conformational Analysis of 2′-Deoxy-2′-(3-methoxybenzamido)adenosine,a rational-designed inhibitor of trypanosomal glyceraldehyde phosphate dehydrogenase (GAPDH)

A series of 2′-benzamido-2′-deoxyadenosine analogues were synthesized in an effort to find new lead structures for the treatment of sleeping sickness. The 2′-deoxy-2′-(3-methoxybenzamido)adenosine ( 1h ) was proved to be a selective inhibitor of the parasite glyceraldehyde 3-phosphate dehydrogenase which confirms the modeling studies. The solution-state conformation of 2′-(thiophene-2-carboxamido) analogue 1d demonstrates a 2′-endo conformation, an orientation of the thiophene ring under the ribose moiety, and the base part occupying a ‘syn’/‘anti’ equilibrium.     

«3-Fluorisopren» (2-Fluor-3-methyl-1,3-butadien) und einige heterosubstituierte Abkömmlinge

‘3-Fluoroisoprene’ (2-Fluoro-3-methyl-1,3-butadiene) and Some Hetero-substituted Derivatives Thereof The readily accessible 1-chloro-1-fluoro-2-iodomethyl-2-methylcyclopropane undergoes zinc-promoted ring-cleavage yielding 2-fluoro-3-methyl-1, 3-butadiene (‘3-fluoroisoprene’) in almost quantitative yield. Alternatively the iodine atom may be replaced by electron-attracting groups such as cyano, benzenesulfonyl or triphenylphosphonio. Ring-opening of the resulting derivatives can then be brought about by various bases and leads to substituted fluorodienes. - The chemical reactivity of ‘3-fluoroisoprene’ has been studied in some detail. For example, it was found to add bromine at temperatures below 0° under kinetic control and to afford mainly the 1,4-adduct having the (Z)-configuration besides smaller quantities of the 1,2- and 3,4-adduct. At room temperature this mixture slowly undergoes a transformation yielding, as the sole products, both stereoisomeric 1, 4-adducts in a 1:1 ratio.     

Synthese von ‘D-Isothreonin’ und ‘L-Alloisothreonin’ aus L-Alanin

Synthesis of ‘D -Isothreonine’ and ‘L -Alloisothreonine’ Starting from L -Alanine Starting from L -alanine, ‘D -isothreonine’ ( = (2R, 3S)-3-amino-2-hydroxybutanoic acid) and ‘L -alloisothreonine’ ( = (2S, 3S)-3-amino-2-hydroxybutanoic acid) were synthesized.     

The Synthesis and Characterization of New Optically Active ‘dimeric’ ‘pineno’-[4,5]-fused 2,2′-bipyridines linked without spacer or by small spacer groups

Linked chiral bipyridines 2–4 are prepared by combining two optically active ‘pineno’-[4,5]-fused 2,2′-bipyridines in a stereoselective reaction (Scheme 1). These potential ligands are new members of the ‘chiragen’ family, and are characterized by NMR spectroscopy and, in the case of 2 and 3 by single-crystal X-ray analysis. A new synthesis of ‘dipineno’-[4,5;4′,5′]-fused 2,2′ -bipyridine 8 is described, which, when coupled, gives additional four chiral centres to the analogous ‘chiragen’ series ( → 9 ). Analysis of the CD spectra allowed conformational information about the solution species to be determined.     

Prediction of the Bivariate Molecular Weight‐Long Chain Branching Distribution in High‐Pressure Low‐Density Polyethylene Autoclaves

In the present study a population balance approach is described to follow the time evolution of bivariate molecular weight‐long chain branching (MW‐LCB) distributions in high pressure low density polyethylene autoclaves. The model formulation is based on a sectional grid method, the so‐called fixed pivot technique (FPT). According to this method, the ‘live’ and ‘dead’ polymer chain populations are assigned to a selected number of discrete points. Then, the resulting dynamic discrete‐continuous molar species equations for ‘live’ and ‘dead’ polymer chains are solved at the specified grid points. It is shown that a very good agreement exists between theoretical results and experimental data which proves the capability of the FPT method in calculating the joint MW‐LCB distribution for branched polymers.

     

Formation of Cyclic ‘ortho’-Anhydrides of Heptalene-1,2-dicarboxylic Acids

1-(Alkoixycarbonyl)heptalene-2-carboxylic acids as well as 2-(alkoxycarbonyl)heptalene-1-carboxylic acids react with the iminium salt formed from N,N-dimethylformamide (DMF) and oxalyl chloride, in the presence of an alcohol, to yield the corresponding cyclic ‘ortho’ -anhydrides (ψ-esters; cf. Schemes 2,3,6, and 8). When the alkoxy moiety of the acids and the alcohols is different, then diastereoisomeric ‘ortho’ -anhydrides are formed due to the non-planarity of the heptalene skeleton. The approach of the alcohol from the β-side is strongly favored (cf. Scheme 5 and Table 1). This effect can be attributed to the bent topology of the heptalene skeleton which sterically hinders the approach of the nucleophile from the α-side of the postulated intermediates, i.e. the charged O-alkylated anhydrides of type 19 (cf. Scheme 6). Whereas the ‘ortho’-anhydrides with four substituents in the ‘peri’ -positions of the heptalene skeleton are configurationally stable up to 100°, the ‘ortho’ -anhydrides with only three ‘peri’ -substituents slowly epimerize at 100° (cf. Scheme 7) due to the thermally induced inversion of the configuration of the heptalene skeleton.     

Transition-Metal Complexes with Bidentate Ligands Spanning trans-Positions. III. Preparation and solution studies of complexes [MX(1)] (M = Cu,Ag and Au; X = anionic ligand; 1 = 2, 11-bis(diphenylphosphinomethyl)benzo[c]phenanthrene)

The preparation of monomeric complexes [MX( 1 )] is reported where M = Cu, Ag, Au; X = I, Cl, NO₃, BF₄ and 1 = 2,11-bis(diphenylphosphinomethyl)benzo[c]phenanthrene. The solution structure of the complexes is discussed on the basis of molecular weight, conductivity and NMR. measurements. In acetonitrile and nitromethane, the nitrate and fluoroborate complexes exist as ionic species [M( 1 )]⁺X^? whereas the halo-complexes are present as equilibrium mixtures of ‘covalent’ and ‘ionic’ forms. All the complexes are associated in CH₂Cl₂-solutions. The values of ¹J show that this association in [Ag(NO₃) ( 1 )] and [Ag(BF₄) ( 1 )] is best described in terms of ion-pairing while that for species [AgX( 1 )] (X = Cl, Br and I) is mainly ‘covalent’ in nature. Evidence is presented for the formation of the complex ion [Ag(CH₃CN)_n( 1 )]⁺ in acetonitrile solution.