5,0-Acetals, activation, dimethyl

The latter reaction could be repeated ten times without loss of activity of Yb-XN-1010. Similar results were obtained with ytterbium(III) loaded Amberlyst 15W resin in a two-step one-pot procedure first involving the formation of the active dimethyl acetal from a benzaldehyde derivative which was followed by in situ protection of sucrose (Scheme 4.17) [100]. 

The chiral nonracemic bis-benzothiazine ligand 75 has been screened for activity in asymmetric Pd-catalyzed allylic alkylation reactions (Scheme 42) <20010L3321>. The test system chosen for this ligand was the reaction of 1,3-diphenylallyl acetate 301 with dimethyl malonate 302. A stochiometric amount of bis(trimethylsilyl)acetamide (BSA) and a catalytic amount of KOAc were added to the reaction mixture. A catalytic amount of chiral ligand 75 along with a variety of Pd-sources afforded up to 90% yield and 82% ee s of diester 303. Since both enantiomers of the chiral ligand are available, both R- and -configurations of the alkylation product 303 can be obtained. The best results in terms of yield and stereoselectivity were obtained in nonpolar solvents, such as benzene. The allylic alkylation of racemic cyclohexenyl acetate with dimethyl malonate was performed but with lower yields (up to 53%) and only modest enantioselectivity (60% ee). 

Methyl-2-diphenylphosphino-3-(l -isoquinolyl)indole with pallada-cycle derived from dimethyl-1-naphthyl ethylamine and potassium hexa-fluorophosphate yields chelate 310 (97T4035). With [(r)3-PhCH = CH = CHPh)Pd( j.-Cl)]2, allyl 311 follows in the presence of silver tetrafluor-oborate. Addition of ligands 312 (R = R1 = H, Me) to [(r 3-PhCHCHCHPh)Pd (Cl) ]2 under conditions of allylic alkylation of 1,3-diphenylprop-2-enyl acetate with dimethyl malonate leads to the formation of P,N-chelates 313 (R = R1 = H, Me), the active species of the catalytic reaction (00T(A)4753). 

The specific activity for both methyl acetate and dimethyl ether as a function of rhodium level on the catalyst was measured and is shown in Fig. 19. Clearly, there is a marked decrease in specific activity for both products with increasing rhodium level in the range 0.5-1 wt.% Rh. The optimum in terms of catalyst efficiency was considered to occur in the range 0.25-0.5 wt.% Rh. The reaction rate was found to be zero order in both CO and CH3OH partial pressures, as has also been found for the homogeneous catalyst system (196). 

Addition of anionic nucleophiles to alkenes and to heteronuclear double bond systems (C=0, C=S) also lies within the scope of this Section. Chloride and cyanide ions are effieient initiators of the polymerization and copolymerization of acrylonitrile in dipolar non-HBD solvents, as reported by Parker [6], Even some 1,3-dipolar cycloaddition reactions leading to heterocyclic compounds are often better carried out in dipolar non-HBD solvents in order to increase rates and yields [311], The rate of alkaline hydrolysis of ethyl and 4-nitrophenyl acetate in dimethyl sulfoxide/water mixtures increases with increasing dimethyl sulfoxide concentration due to the increased activity of the hydroxide ion. This is presumably caused by its reduced solvation in the dipolar non-HBD solvent [312, 313]. Dimethyl sulfoxide greatly accelerates the formation of oximes from carbonyl compounds and hydroxylamine, as shown for substituted 9-oxofluorenes [314]. Nucleophilic attack on carbon disulfide by cyanide ion is possible only in A,A-dimethylformamide [315]. The fluoride ion, dissolved as tetraalkylammo-nium fluoride in dipolar difluoromethane, even reacts with carbon dioxide to yield the fluorocarbonate ion, F-C02 [840]. 

Attempted use of chlorosuccinimide or A(-bromosucciiiiinide to activate dimethyl sulfoxide is limited, owing to the preferential foimation of methylene acetals in good yields, as illustrated in the preparation of die acetal (28 equation 13). 

An in-depth study of platinum allyhc alkylation and subsequent comparison to ligand-identical palladium catalysts was done by Blacker et al. The aUylic alkylation of diphenyl-2-enyl acetate with dimethyl malonate, (equation 73), reveals activity for a variety of complexes with activity restricted by the source of zerovalent platinum (Table 1). Nonactive complexes are thought to be less prone to dissociation into coordinatively unsaturated catalytical active species. 

Transition Metal-Cataijrzed Reactions. Application of this ligand to the Pd-catalyzed ally lie alkylation of l,3-diphenyl-2-propenyl acetate with dimethyl malonate provides an alkylated product in >99.5% enantiomeric excess (eq 1). The enantiose-lectivity of the process is dependent on the ligand Pd ratio, the palladium precursor, and the nature of the nucleophile. Optimal conditions employed Pd(dba)s as the Pd precursor and 2 equiv of phosphine ligand, suggesting that two phosphines coordinate to the active Pd catalyst. Replacement of l,3-diphenyl-2-propenyl acetate with pent-3-en-2-yl acetate decreased the ee to 34% due to the reduced sterics of methyl relative to phenyl substituents. It is noteworthy that in contrast to this ligand, most monodentate ligands provide low enantioselectivity in this reaction. ... 

Protection of aldoses at the non-anomeric positions makes it possible to use many of the common procedures in organic chemistry for oxidizing lactols as shown with mannofura-nose 1 and glucopyranose 3 (O Table 1). The reactions can be divided into three main categories oxidations mediated by activated dimethyl sulfoxide (DMSO), oxidations with chromi-um(VI) oxides, and oxidations catalyzed by ruthenium oxides. The DMSO-mediated oxidations of alcohols can be promoted by several activators [27]. With the partially protected aldoses the activation has mainly been achieved with acetic anhydride and oxalyl chloride. Competing /3-elimination does usually not occur unless the eliminating group is an ester, e. g., an acetate or a benzoate [27]. 

Sinou and co-workers [73] studied the influence of different surfactants on the palladium-catalyzed asymmetric alkylation of l,3-diphenyl-2-propenyl acetate with dimethyl malonate in presence of potassium carbonate as base and non-water-soluble chiral ligands. Best results in activity and enatioselectivity (> 90% ee) were observed with 2,2 -bis(diphenylphosphino)-l,l -binaphthyl (BINAP) as ligand and cetyltrimethylammonium hydrogen sulfate as surfactant in aqueous medium. Water-stable Lewis acids as catalysts for aldol reactions were developed by Kobayashi and co-workers [74]. An acceleration of the reaction was indicated in presence of SDS as anionic surfactants. An additional promotion could be observed by combination of Lewis acid and surfactant (LASCs = Lewis acid-surfactant-combined catalysts) as shown in Eq. (3). Surfactant the anion of dodecanesulfonic acid. 

A few years later the Swem laboratory then developed an activator which they claimed to be the most successful in activating dimethyl sulfoxide toward oxidation, namely, oxalyl chloride. Since oxalyl chloride reacted violently and exothermically with dimethyl sulfoxide, successful activation required the use of low temperatures to form the initial intermediate.6 Swem et al. reported the oxidation of long chain primary alcohols to aldehydes which was previously unsuccessful by first converting to the sulfonate ester (either mesylate or tosylate) and then employing the dimethyl sulfoxide-acetic anhydride procedure. They found that long-chain saturated, unsaturated, acetylenic and steroidal alcohols could all be oxidised with dimethyl sulfoxide-oxalyl chloride in high yields under mild conditions. 

The palladium-catalyzed asymmetric alkylation of l,3-diphenyl-2-propenyl acetate with dimethyl malonate could be influenced in activity and enantioselectivity by the surfactant cetyltrimefhylammonium hydrogen sulfate [24],... 

The preparation of high specific activity dimethyl [ HJformamide and acetic [ HJformic... 

Similar activation takes place in the carbonylation of dimethyl ether to methyl acetate in superacidic solution. Whereas acetic acid and acetates are made nearly exclusively using Wilkinson s rhodium catalyst, a sensitive system necessitating carefully controlled conditions and use of large amounts of the expensive rhodium triphenylphosphine complex, ready superacidic carbonylation of dimethyl ether has significant advantages. 

Reduction of 2.4-dimethyl-5-nitrothiazole with activated iron gives a product that after acetylation yields 25% 2.4-dimethyl-5-acetamido-thiazole (58). The reduction of 2-methyl 5-nitrothiazole is also reported (351 to give a mixture of products. The nitro group of 2-acetylhydrazino-5-nitrothiazole is reduced by TiCl in hydrochloric acid or by Zn in acetic acid (591. 

Nearly all uses and appHcations of benzyl chloride are related to reactions of the active haUde substituent. More than two-thirds of benzyl chloride produced is used in the manufacture of benzyl butyl-phthalate, a plasticizer used extensively in vinyl flooring and other flexible poly(vinyl chloride) uses such as food packaging. Other significant uses are the manufacture of benzyl alcohol [100-51-6] and of benzyl chloride-derived quaternary ammonium compounds, each of which consumes more than 10% of the benzyl chloride produced. Smaller volume uses include the manufacture of benzyl cyanide [140-29-4], benzyl esters such as benzyl acetate [140-11-4], butyrate, cinnamate, and saUcylate, benzylamine [100-46-9], and benzyl dimethyl amine [103-83-8], and -benzylphenol [101-53-1]. In the dye industry benzyl chloride is used as an intermediate in the manufacture of triphenylmethane dyes (qv). First generation derivatives of benzyl chloride are processed further to pharmaceutical, perfume, and flavor products. 

As a result of the 7r-deficiency of the pteridine nucleus, alkyl pteridines are activated in the a-positions. The common reactions based on C—H acidity are found with a wide variety of compounds. Bromination of 6- and 7-methyl groups leads to mono- and di-substitution selective formation of the monobromomethyl derivatives has not yet been achieved satisfactorily. 6-Methylisoxanthopterin is claimed to give the 6-bromomethyl derivative with bromine in acetic and sulfuric acids at 100 °C for 2 min (50ZN(B)132) and with 1,7-dimethyl-lumazine a 90% yield of the 7-bromomethyl derivative (60CB2668) is obtained after 4h... 

Most of the pharmacologically active indazole derivatives are useful as antiinflammatory drugs, e.g. bendazac or [(1-benzyl-l J/-indazol-3-yl)oxy]acetic acid (LDso in mice and rats of 355 and 388mgkg i.p., respectively) and benzydamine or l-benzyl-3-[3-(dimethyl-amino)propoxy]-l//-indazole (LDso in mice and rats of 110 and lOOmgkg" i.p., respectively). The last cited compound also has analgesic and antipyretic properties (B-76MI40404). 

Trihydroxy-6,16a-dimethyl-2 -phenyl-2 H-pregna-2,4,6-trieno[3,2-c] -pyrazol-20-one-21-acetate, commonly named cortivazol (696), has been used since 1962 by Merck Co. as a glucocorticoid (B-76MI40404). Tricyclic pyrazoles (697) have been found to possess antiarrhythmic and antiinflammatory activities (76JHC545). 

A solution of cholest-4-en-3-one (139), 1 g, in diethylene glycol dimethyl ether (20 ml) is treated for 1 hr with a large excess of diborane at room temperature under nitrogen and then left for a further 40 min. Acetic anhydride (10 ml) is added and the solution refluxed for 1 hr. The mixture is concentrated to a small volume, diluted with water and extracted with ether. The extracts are washed with 10% sodium hydroxide solution, then with water and dried over sodium sulfate. Removal of the solvent leaves a brown oil (1.06 g) which is purified by chromatography on alumina (activity I). Hexane elutes the title compound (141), 0.68 g mp 76-77°. Successive crystallization from acetone-methanol yields material mp 78-79°, [a]p 66°. 

J mol ). This is additional evidence in favor of rate limitation by inner diffusion. However, the same reaction in the presence of Dowex-50, which has a more open three-dimensional network, gave an activation energy of 44800 J mol , and closely similar values were obtained for the hydrolysis of ethyl acetate [29] and dimethyl seb-acate [30]. The activation energy for the hydrolysis of ethyl acetate on a macroreticular sulphonated cationic exchanger [93] is 3566 J mol . For the hydrolysis of ethyl formate in a binary system, the isocomposition activation energy (Ec) [28,92] tends to decrease as the solvent content increases, while for solutions of the same dielectric constant, the iso-dielectric activation energy (Ed) increases as the dielectric constant of the solvent increases (Table 6). 

Fewer procedures have been explored recently for the synthesis of simple six-membered heterocycles by microwave-assisted MCRs. Libraries of 3,5,6-trisubstituted 2-pyridones have been prepared by the rapid solution phase three-component condensation of CH-acidic carbonyl compounds 44, NJ -dimethylformamide dimethyl acetal 45 and methylene active nitriles 47 imder microwave irradiation [77]. In this one-pot, two-step process for the synthesis of simple pyridones, initial condensation between 44 and 45 under solvent-free conditions was facilitated in 5 -10 min at either ambient temperature or 100 ° C by microwave irradiation, depending upon the CH-acidic carbonyl compound 44 used, to give enamine intermediate 46 (Scheme 19). Addition of the nitrile 47 and catalytic piperidine, and irradiation at 100 °C for 5 min, gave a library of 2-pyridones 48 in reasonable overall yield and high individual purities. 

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