Generation and fate of free radicals of Δ2-oxazolin-5-ones

The reaction of Δ² -oxazolin-5-ones 1a and 1b with nickel peroxide in benzene produces the corresponding 4,4-dehydrodimers 5a and 5b as the main products in yields over 75%. Under the same conditions, the 2-aryl -4-methyl - Δ²-oxazolin-5-ones 1c, 1d and 1e yield five products. In the case of 1c, the constituents of the product mixture were separated and identified as two 4,4-dehydrodimers ( meso and d] pair isomers) 5c and 5c', (40.7%), 2,4-dehydrodimer 6c (34.9%), acetylanisoylimide 8c (8.5%) and anisamide (15.9%). Adequate mechanistic schemes are discussed to account for the products formed.     

Pyrimidines-19: Ring transformation of 5-nitrouracil into nitroresorcinols

The first intermolecular right transformation of a uracil derivative into the benzene system is reported. Treatment of 1,3-dimethyl-5-nitrouracil (1) with acetone in NaOMe/MeOH afforded 6-acetonyl-5,6-dihydro-1,3-dimethyl-5-nitrouracil (6) which was converted into 4-nitroresorcinol (5) upon treatment with NaOEt/EtOH at reflux. Reaction of1 with butanone gave two major products, 3-(5,6-dihydro-1,3-dimethyl-5-nitrouracil-6-yl)butanone (7) and the 1-(uracil-6-yl)butanone isomer (8). Prolonged treatment of7 with NaOEt/EtOH afforded 4-methyl-6-nitro-resorcinol (9) whereas8 was converted into 2-methyl-4-nitro-resorcinol (10). Treatment of1 with diethyl acetonedicar?ylate in NaOEt/EtOH afforded diethyl-2-(5,6-dihydro-1,3-dimethyl-5-nitrouracil-6-yl)-acetonedicar?ylate (2). Prolonged treatment of2 with NaOEt/EtOH at reflux afforded (5,6-dihydro-1,3-dimethyl-6-nitrouracil-6-yl)-acetate (3). Apparently,2 underwent a retroClaisen reaction to give3. Reaction of1 with ethyl acetoacetate in NaOEt/EtOH gave adduct isomers4 which underwent transformation reaction to give eventually 6-nitroresorcinol (5).     

Synthesis of 1-(3′-deoxy-β-D-glycero-pentofuran-2′-ulosyl)uracil by selective elimination reactions

For the synthesis of y 1-(3′-deoxy-β-D-glycero-pentofuran-2′-ulosyl)uracil (16), the precursor, 5′-O-benzoyl derivative (2),² was elaborated in a variety of ways. 1-(5′-O-Benzoyl-3′-O-tosyl-β-D- lyxofuranosyl)uracil (4)² was benzoylated to N³-benzoyl-1-(2′,5′-di-O-benzoyl-3′-O-tosyl-β-D- lyxofuranosyl)uracil (5), which directly yielded 2 on treatment with sodium benzoate. 1-(3′,5′-Di-O- benzoyl-2′-O-tosyl-β-D-lyxofuranosyl)uracil (8) and its 3′,5′-O-isopropylidene analog (10) resisted elimination reactions, thus proving absolute selectivity in the elimination of the derivatives of 1-β-D- lyxofuranosyl-uracil. Seeking a more economical path to 2, 1-(5′-O-benzoyl-β-D-lyxofuranosyl)uracil (11) was first benzoylated to give 2′,5′-di-O-benzoate (12), accompanied by 3′,5′-di- and 2′,3′,5′-tri-O- benzoate. Mesylation of the major product (12) gave 1-(2′,5′-di-O-benzoyl-3′-O-mesyl-β-D- lyxofuranosyl)uracil (15), which, on treatment with sodium benzoate, gave 2 in an highly improved yield. Basic hydrolysis on 2 gave compound 16.     

Search for a simpler synthetic model system for intramolecular 1,3-dipolar cycloaddition to the 5,6-double bond of a pyrimidine nucleoside

In search for a simpler model system for the study of intramolecular thermal reactions between the base and 5'-functionalized sugar moiety in nucleosides, 1-(3-azidopropyl)uracil (2), 1-(4-azidobutyl) pyrimidines (12 and 13) and 1-(5-azidopentyl)-uracil (14) was synthesized through the corresponding ω-benzoyloxy-(6,7 and 8) and ω-hydroxyalkyl-pyrimidines (9,10 and 11). Heating 2 gave 1,N⁶-trimethylene-6-aminouracil (4), while heating 12 and 13 gave N¹-C₆ cleaved addition products. 15 and 16, respectively. 15 was regiospecifically transformed to 1,2,3-triazole derivatives, 17,18 and 19. Heating 1-(4-azidobutyl)-5-bromouracil (20) yielded 3,9-tetramethylene-8-azaxanthine (22). 9 with NBA gave 1,0⁶-tetramethylene-5-bromo-6-hydroxy-5,6-dihydrouracil (24) and the 5-brominated analog of 9 (25). The 4-functionalized butyl side chain proved to serve as a substitute for the 5'-functionalized sugar moiety in pyrimidine ribonucleosides.     

Electrochemical study of catechol and some 3-substituted catechols in the presence of 4-hydroxy coumarin: application to the electro-organic synthesis of new coumestan derivatives

Electrochemical oxidation of catechol (1d), 3-methylcatechol (1a), 3-methoxycatechol (1b) and 2,3-dihydroxybenzoic acid (1c) in the presence of 4-hydroxycoumarin as nucleophile in aqueous solution has been studied using cyclic voltammetry and controlled-potential coulometry. The results indicate that (1a–1d) participating in a 1,4 (Michael) addition reaction convert to coumestan derivatives (5a–5d). The electrochemical synthesis of 5a–5d has been successfully performed in an undivided cell in good yield and purity.     

Spiro-compounds,synthesis and catalytic dehydrogenation of substituted spiro[5,5] undecanes

Catalytic dehydrogenation of 1-propyl-8,9-benzospiro[5,5]undecane-7-ol (5: R = H), and 1-propyl-3′-methyl-8,9-benzospiro[5,5]undecane-7-ol (5: R = Me) has been carried out to study the effect of a bulky alkyl group on the ring in the ring transformation of the spiro[5,5]undecane system. The catalytic dehydrogenation of the spiro-compound 5(R = H) gave phenanthrene and 1-ethylpyrene (minor product) and spiro compound 5(R = Me) gave only 3-methylphenanthrene. For the synthesis of 5 (R = H or Me), the anhydride (1) of 1-carboxy-2-propylcyclohexane-1-acetic acid was condensed with benzene and toluene to give 2 (R = H or Me) which was reduced catalytically to 3(R = H or Me). Intramolecular acylation of 3(R = H or Me) gave the spiroketone (4: R = H or Me) which was reduced to 5(R = H or Me).     

Aminomethinylierung H-aktiver verbindungen in der reihe analgetischer wirkstoffe

Electrophilic attack of the active methylene group in 3-methyl-1-phenyl-5-pyrazolone (2) by s-triazine (1) leads to aminomethinylation of 2 with formation of 3-methyl-1-phenyl-4-aminomethylene-5-pyrazolone (4). Subsequent interaction of 4 with 2 explains the formation of 4,4′-methenyl-bis-[3-methyl-1-phenyl-5-pyrazolone (5). 1-Phenyl-3,5-pyrazolidinedione (6) reacts analogously with 1 forming 1-phenyl-4-aminomethylene-3,5-pyrazolidinedione (7). N,N′-Bis-indanyl-formamidine (9) results from the interaction of 2-amino-indane (8) with 1.     

Synthesis,antimicrobial and cytotoxic activity of novel azetidine-2-one derivatives of 1H-benzimidazole

A series of 1-methyl-N-[(substituted-phenylmethylidene)-1H-benzimidazol-2-amines (4a–4g) were prepared via the formation of 1-methyl-1H-benzimidazol-2-amine (3), which was prepared by the cycloaddition of o-phenylenediamine (1) with cyanogen bromide in the presence of aqueous base followed by N-methylation with methyl iodide in the presence of anhydrous potassium carbonate in dry acetonitrile. Moreover, the four-membered β-lactam ring was introduced by the cycloaddition of 4a–4g and chloroacetyl chloride in the presence of triethylamine catalyst to give 3-chloro-1-(1-methyl-1H-benzimidazol-2-yl)-(4′-substituted)-phenylazetidin-2-one 5a–5g. A total of 14 compounds were synthesized and characterized by IR, ¹H NMR, ¹³C NMR and Mass spectral technique, in addition they were evaluated for anti-bacterial and cytotoxic properties. Among the chemicals tested 4a, 4b, 5a, 5b, 5g exhibited good antibacterial activity and 5f, 5g shown good cytotoxic activity in vitro.     

Approaches to the regiospecific synthesis of Anthracycline antibiotics

Synthetic approaches to anthracycline antibiotics were studied through the use of Claisen rearrangements on 1-methallyloxy-5-methoxyantraquinone (9) which required reducing conditions to proceed through a hydroquinone intermediate in situ. 1-(2′-Methylene-4′-pentenoxy)-5-methoxyanthraquinone (13) underwent a similar reductive rearrangement but also produced a spiro compound 16 as a result of an ene reaction between the phenol and side chain double bond. 1-Hydroxy-2-methally-5-methoxyanthraquinone (11) could not be oxidized to quinizarin 17. 1-Hydroxy-2-methally-5,9,10-trimethoxyanthracene (21) was oxidatively coupled to the dimer at C-2. Dimer 23 reacted with diazomethane to form a 1,3-dipolar adduct 24.     

Lipase-mediated kinetic resolution of cis-1,2-indandiol and the Ritter reaction of its mono-acetate

Lipase-mediated kinetic resolution of cis-1,2-indandiol 5 in the presence of lipase PS was examined. Enantiomerically enriched (1S,2R)-2-acetoxy-1-indanol 6a was obtained when cis-1,2-indandiol 5 was treated with one equivalent of vinyl acetate. Treatment of 5 with two equivalents of vinyl acetate furnished a mixture of (1R,2S)-2-acetoxy-1-indanol 6a and (1R,2S)-1-acetoxy-2-indanol 6b. A route to both enantiomers of 1 was also developed by using the enantiomerically enriched mono-acetate thus obtained.     

Synthesis of 12-acetoxy-1, 3-dodecadiene,an insect sex pheromone of the red bollworm moth,from a butadiene telomer

8-Phenoxy-1, 6-octadiene (1) formed by the Pd-catalyzed telomerization of butadiene with phonol was converted to 8-phenoxy-6-octen-1-ol (3). The alcohol 3 was converted to 8-iodo-1-phenoxy-2-octene (5). The Grignard reagent 7 prepared from 4-chloro 1-butyl tetrahydropranyl ether was coupled with the iodide 5 by the catalysis of CuI and bipyridyl to give 12-phenoxy-10-dodecen-1-ol (9), which was converted to 12-acetoxy-1-phenoxy-2-dodecene (10). Finally, 12-acetoxy-1, 3-dodecadiene (11) was obtained by the palladium catalyzed elimination of phenol from phenoxyacetoxy-dodecene (10).     

Synthesis of pyrrolizines by intramolecular capture of 1,4-dipolar intermediates in reactions of enamines with dimethyl acetylenedicarboxylate

Solvent polarity and reaction temperature strongly influence the reactions of dimethyl acetylenedicar-boxylate (DMAD) with 1-pyrrolidinyl enamines of acyclic and cyclic ketones. Whereas DMAD and 1-[1-phenyl-2-(phenylthio)ethenyl]pyrrolidine (3) give only a mixture of the isomeric 1,3-butadienes (5) in apolar solvents, in methanol the main product is the pyrrolizine 7, together with 5. Again in methanol, DMAD reacts at 0-5° with 8, 9 and 10 to give exclusively 1:1 adducts, the pyrrolizines 11,12 and 13, respectively, whereas at ?50° 8 and 9 give 1:2 (enamine : DMAD) adducts, the pyrrolizines 14 and 15, respectively; a single crystal X-ray analysis of 14 gave the structure of the 1:2 adducts. In the same solvent methyl propiolate and 8 give only the linear Michael adduct 17. The enamine-ketone 18 reacts with DMAD in propylene carbonate at 0–5° to give, via (2 + 2)-cycloaddition and ring expansion, 19, and the linear Michael adduct 20. The mechanism of (2 + 2)-cycloaddition and pyrrolizine formation is discussed in terms of a common tied-ion pair intermediate formed in the first, rate-determining step, followed by a second solvent-dependent step.     

Benzisoxazolium cations—II : Reaction with anthranilic acid: Intramolecular reaction of an N-aroyl-N-alkylsalicylamide

Reaction of 2-ethylbenzisoxazolium fluoborate (1) with anthranilic acid gives O-aroylsalicylamide (5a) and the quinazolone (6a), whose structure is established by an unambiguous synthesis of its methyl ether (6b). The O-aroyl amide (5a), formed via the ketoketenimine (Scheme 1) from the salt 1, undergoes O→N migration to the imide (8) which through an intramolecular reaction followed by dehydration is converted to the quinazolone 6a (Scheme 2). Independently the O-aroyl amide (5a) could be transformed to the quinazolone (6a) under basic conditions. The formation of quinazolone (6a) suggests the labile N-alkyl-N-aroyl isomer (8), which is expected to be in equilibrium with the O-aroyl isomer (5a), is captured. (Scheme 2).     

Synthese von Tricarbonyl-η5-cyclohexadienyl-wolframat und Tricarbonyl-η5-cyclohexadienyl-methyl-wolfram

η⁶-Arene-tricarbonyl-tungsten (arene = benzene (1a), toluene (1b), m-xylene (1C), P-xylene (1D), o-xylene (1E), mesitylene (1F)) yield with potassium-tri-sec-butylboranate correspondingly methyl-substituted tricarbonyl-η⁵-cyclohexadienyl-tungstates (2A–2F). Similarly 1A reacts with methyllithium to tricarbonyl-η⁵-anti-6-methylcyclohexadienyl-tungstate (4A). In THF 2A–2F and 4A are converted by methyliodide to tricarbonyl-μ⁵-cyclohexadienyl-tungsten (3A–3F) and tricarbonyl-η⁵-anti-6-methylcyclophexadienyl-methyl-tungsten (5A). The complexes were characterized by C, H elemental analyses and by IR and ¹H-NMR spectroscopy.     

A convenient synthesis of 1α- and 1β-hydroxycholesterol

An efficient procedure for the preparation of 1α-hydroxycholesterol 3-acetate 4 is described, which starts from cholesterol and involves as key steps transannular cyclization of the ten-membered ring ontaining (E)-3β-acetoxy-5,10-seco-1(10)-cholesten-5-one 1 to the oxetane derivative 1α,5-epoxy-5α-cholestan-3β-ol acetate 3, and opening of the four-membered ether ring in the latter compound. 1β-Hydroxycholesterol diacetate 9 was obtained by oxidation of 4 to the 1-oxo derivative 8, followed by metal hydride reduction and acetylation.     

Dye-sensitized photo-oxygenation of tryptophan

Dye-sensitized photo-oxygenation of L-tryptophan (1) has been studied at various pH and in various buffers. Disappearance of 1 in both acetate and phosphate buffers was rapid at higher pH. The tricyclic hydroperoxide (8) was the sole product in the oxidation of 1 over the range pH 3.6–7.1 in acetate and phosphate buffers. However, the oxidation of 1 in alkaline phosphate and borate buffers (pH 7.7–8.4) gave 5-hydroxyformylkynurenine (10) as the major product. The intermediate, 3a,5-dihydroxypyrroloindole (16), which may be formed from the tricyclic hydroperoxide (8) via the quinoneimine (15), was obtained in good yield by the immediate reduction of the reaction mixture with NaBH₄. Molecular oxygen (ground state) oxidation of 16 in the alkaline media provided 10. The similar oxidation and reduction of tryptamine (17a) gave 3a,5-dihydroxypyrroloindole (18b) which was not further oxidized to 5-hydroxyformylkynureamine. On the other hand, dye-sensitized photo-oxygenation of 1 in Na₂CO₃-AcOH (pH 7) gave formylkynurenine (3) as the major product.     

Synthesis,characterization and ethylene polymerization of 1-(2,6-dimethyl-4-fluorenylphenylimino)-2-aryliminoacenaphthylnickel bromides

A series of 1-(2,6-dimethyl-4-fluorenylphenylimino)-2-aryliminoacenaphthylene compounds (aryl = 2,6-di(Me)Ph (L1), 2,6-di(Et)Ph (L2), 2,6-di(i-Pr)Ph (L3), 2,4,6-tri(Me)Ph (L4), 2,6-di(Et)-4-MePh (L5)) was prepared and used to form their corresponding dibromonickel complexes (D1–D5). Both L1–L5 and D1–D5 were fully characterized by FT-IR and elemental analysis as well as NMR measurements in the case of ligands L1–L5. The molecular structure of the representative complex D5 was confirmed by single crystal X-ray diffraction revealing a distorted trigonal bipyramidal geometry around the nickel center. On activation with either ethylaluminium sesquichloride (Et₃Al₂Cl₃, EASC) or methylaluminoxane (MAO), all nickel complexes exhibited high activities up to 9.82 × 10⁶ g of PE (mol of Ni)⁻¹ h⁻¹ for ethylene polymerization. In comparison with the polyethylenes obtained with related Ni pre-catalysts, the polyethylenes obtained in this work possessed relatively higher molecular weights and lower levels of branching, highlighting the significant influence of the remote fluorenyl substituent.     

Stereoselective and versatile approach for the synthesis of gossyplure and its components

Efficient synthetic routes to gossyplure and its components (1a and 1b) were formulated. The three key units viz the alkynol 3, the bromide 5, and the alkanal 13 were derived from easily accessible starting materials. Alkylation of 3 with 5, and subsequent semihydrogenation followed by oxidation, provided the C₁₁-alkenal 8 which was subjected to a stereocontrolled Wittig reaction with a C₅-phosphonium salt, to yield directly the desired pheromone (1a + 1b). The synthesis of its individual components involved the manipulation via an acetylenic intermediate, viz the alkynol 14 which was obtained through alkylation of 3. A sequence of well-established reactions on 14, then provided the corresponding (E)- and (Z)-alkenylphosphonium salts which upon a (Z)-specific Wittig olefination with the C₇-aldehyde (13), led to the stereoselective synthesis of 1a and 1b.     

The synthesis of octavalene (tricyclo[5.1.0.02,8]octa-3,5-diene) and several substituted octavalenes

The first synthesis of octavalene (1a) is reported. The starting material is homobenzvalene (5), to which monobromocarbene is added. The resulting compound 3a takes up bromine across the central bicyclo[1.1.0]butane bond to form the tribromide 7a which undergoes a cyclopropyl bromide-allyl bromide rearrangement on heating. From the product (1Oa) HBr is eliminated to give a 1,3-dibromocyclobutane with a 1,3-butadiene bridge across its 2- and 4-position (11a). Finally, t-butyllithium removes the two Br atoms from 11a and converts it into a 4:1 mixture of 1a and cyclooctatetraene. This reaction sequence represents the first application of protective group strategy in bicyclo[1.1.0]butane chemistry. Octavalene (1a) is shown to rearrange to cyclooctatetraene at 50°. Deuterium-labeled 1a ([1,8-D₂] 1a) is used to prove that a [1,5]-sigmatropic shift does not occur in 1a. Utilizing the above methodology 4-bromooctavalene (1b) and 3-phenyl-5-bromooctavalene (1c) are synthesized from the dibromocarbene adducts 3b and c of homobenzvalene (5) and 5-phenylhomobenzvalene (6), respectively. Surprisingly, 1c was accompanied by a small quantity of 3-bromo-1-phenyloctavalene (1d). Possible mechanisms for the addition of bomine to the bicyclo[1.1.0]butane system of compounds 3 and for the formation of the octavalenes 1 are discussed. In the ¹³C-NMR spectra of 1 and 11 chemical shifts at unexpectedly high field are observed for C-6 of the 1,3-cycloheptadiene moieties.     

Incorporation of 5-substituted uracil derivatives into nucleic acids—III : Synthesis of 5-substituted uracils derived from 5-acetyluracil

5-Acetyluracil (1) has been converted into 5-(bromoacetyl)-uracil (2) by an established procedure. Reduction of 2 with sodium borohydride gave 5-(2-hydroxyethyl)uracil (4) in low yield. Treatment of 5-vinyluracil (7), obtained from 1 by published methods, with 1 molecular proportion of bromine followed by heating to 100°, gave E-5-(2-bromovinyl)uracil (8). Reaction of 8 with potassium t-butoxide gave 5(7)H-furanol[2,3,d]pyrimidin-6-one (10) and upon reduction with sodium in liquid ammonia, 8 gave 5-ethyluracil (11). Compound 2 showed low antibacterial activity against Staphylocuccus aureus, Streptococcus faecalis and Escherichia coli in nutrient broth and in a medium containing only inorganic salts, glucose and thymine, appreciable activity (～ 6 μg/ml) against E. coli. Compound 2 was not incorporated into the DNA of E. coli.