Arylation active methylene compound

Classical Aldol. Aldol reaction is an important reaction for creating carbon-carbon bonds. The condensation reactions of active methylene compounds such as acetophenone or cyclohexanone with aryl aldehydes under basic or acidic conditions gave good yields of aldols along with the dehydration compounds in water.237 The presence of surfactants led mainly to the dehydration reactions. The most common solvents for aldol reactions are ethanol, aqueous ethanol, and water.238 The two-phase system, aqueous sodium hydroxide-ether, has been found to be excellent for the condensation reactions of reactive aliphatic aldehydes.239... 

Condensation of aryl halides with various active methylene compounds is readily promoted by catalytic action of palladium to give the corresponding arene derivatives containing a functionalized ethyl group [7]. Yamanaka et al. extended this chemistry to haloazoles including oxazoles, thiazoles and imidazoles [8]. Thus, in the presence of Pd(Ph3P)4,2-chlorooxazole was refluxed with phenylsulfonylacetonitrile and NaH to form 4,5-diphenyl-a-phenylsulfonyl-2-oxazoloacetonitrile, which existed predominantly as its enamine tautomer. In a similar fashion, 4-bromooxazole and 5-bromooxazole also were condensed with phenylsulfonylacetonitrile under the same conditions. 

The electrogenerated Mn(lll)-assisted coupling of various olefins with active methylene compounds proceeds by indirect electrooxidation with a small amount of Mn(OAc)2 in the presence or absence of Cu(OAc)2 [196]. The Mn(Ill)-assisted carboxymethylation of styrenes (142) affords y-aryl-y-lactones (143) in good current yields (Scheme 57) [194, 195, 206, 207], (Table 9). 

The base-catalyzed condensation of azides with activated methylene compounds is a well-established route to IJT-triazoles. In particular, it is the best route to triazoles bearing a 5-amino or hydroxy substituent and an aryl or carbonyl-containing function in the 4-position. The addition is regiospecific. The reaction is a stepwise one, since anomerism of glycosyl azides has been observed in their reaction with activated methylene compounds, indicating the presence of an intermediate. The mechanism can be envisaged as a nucleophilic attack by the car-banion on the terminal nitrogen of the azide, followed by cyclization to a... 

It is well established that metallic copper or copper salts efficiently catalyze N- and O-arylation reaction using pentavalent and trivalent organobismuth compounds [5-9, 24]. The C-arylation reaction of phenols and active methylene compounds using pentavalent organobismuth compounds are usually mediated by a base. However, in some cases, copper catalysts mediate C-arylation using pentavalent organobismuth compounds. 

Thermolysis of the thiadiazole (164) leads to elimination of isocyanate and sulfur giving the triazine derivative (167). If the thermolysis is carried out in the presence of phenols 2-aryl-benzimidazoles (168) are produced <85JCS(P1)1007>. The S—N bond of (157) is readily cleaved with both N- and C-nucleophiles. Thus, treatment of (157) with an excess of amine gives the sulfenamide (169) (Scheme 39) and reaction of (157) with active methylene compounds leads to derivatives of type (170) (Scheme 39) which on heating furnish (171). Cyanide ion inserts into the S—N bond of (164), probably via the intermediate (172) which immediately recyclizes to give the thiadiazinone (173) (Scheme 40) <85JCS(P1)1007>. 

Active methylene compounds have more than one activating group such as carbonyl, cyano, sulfonyl, or aryl bound to a methylene carbon. Bases such as hydroxide ion easily remove a proton to form a reactive carbanion. The most widely studied example is the alkylation of phenylacetonitrile (Scheme 1). The abstraction of the proton is generally the rate limiting step. 

Coupling of aryl bromides with diethyl sodiomalonate. CuBr is the most effective Cu(I) catalyst for effecting coupling of aryl iodides or bromides with the sodium salts of active methylene compounds such as diethyl sodiomalonate. Coupling is facilitated by ori/io-substituents in the halide, particularly nitro, carbomethoxy, and methoxy groups.1 This reaction has been adapted to synthesis of benzofurane-2-ones.2... 

Although arylation or alkenylation of active methylene compounds can be carried out using a Cu catalyst, the reaction is sluggish. However, the arylation of malononitrile (390) or cyanoacetate proceeds smoothly in the presence of a base and Pd catalysts [189], Tetracyanoquinodimethane (392) is prepared by the coupling of / -diiodoben-zene with malononitrile (390) to give 391, followed by oxidation [190], Presence of the cyano group seems to be essential for intermolecular reactions. However, the intramolecular arylation of malonates, / -keto esters and /i-diketones proceeds smoothly [191]. The bromoxazole 393 reacts with phenylsulphonylacetonitrile (394)... 

The direct alkenylation of arylamines at the ortho position has been reported in reactions of o -chloroalkenylmagnesium chloride with N-lithioarylamines.22 Use of the CuI-L-proline catalyst system in DMSO has been found to be successful in promoting reactions of aryl iodides and bromides with activated methylene compounds, such as ethyl acetoacetate and diethyl malonate.23 The same catalyst in dioxane has been used in intramolecular cyclization of ene-carbamates leading to indoles or pyrrolo[2,3-cjpyridines.24... 

The coupling of aryl halides with active methylene compounds, such as mal-onitriles and cyanoacetates, is of increasing interest due to its inherent difficulty and the interest of the resulting products as synthetic intermediates in the preparation of bio active [36,37], heterocyclic [38,39] or conducting compounds [40]. Bulky NHCs have been found to be excellent ligands in the coupling of aryl halides with malonitrile [41] in hot pyridine using NaH as base (Scheme 7). 

Keywords C-H bond activation Silylation Arylation Hydroacylation Active methylene compounds... 

The use of C-H bonds is obviously one of the simplest and most straightforward methods in organic synthesis. From the synthetic point of view, the alkylation, alkenylation, arylation, and silylation of C-H bonds are regarded as practical tools since these reactions exhibit high selectivity, high efficiency, and are widely applicable, all of which are essential for practical organic synthesis. The hydroacylation of olefins provides unsymmetrical ketones, which are highly versatile synthetic intermediates. Transition-metal-catalyzed aldol and Michael addition reactions of active methylene compounds are now widely used for enantioselective and di-astereoselective C-C bond formation reactions under neutral conditions. 

Chloro-9-phenylpurine reacts with a variety of nucleophiles including 0-alkyl, 0-aryl, SR, and NHR to produce the 2-substituted purines. The compound also reacts with benzylcyanide and ethyl cyanoacetate to give the corresponding purine-2-CHR(CN) derivative but failed to react with other active methylene derivatives, ketones, or potassium cyanide. In contrast, 9-phenyl-2-methyl-sulfonylpurine reacted readily with active methylene compounds, ketones, and potassium cyanide <87CPB4972>. 

Among common carbon-carbon bond formation reactions involving carbanionic species, the nucleophilic substitution of alkyl halides with active methylene compounds in the presence of a base, e. g., malonic and acetoacetic ester syntheses, is one of the most well documented important methods in organic synthesis. Ketone enolates and protected ones such as vinyl silyl ethers are also versatile nucleophiles for the reaction with various electrophiles including alkyl halides. On the other hand, for the reaction of aryl halides with such nucleophiles to proceed, photostimulation or addition of transition metal catalysts or promoters is usually required, unless the halides are activated by strong electron-withdrawing substituents [7]. Of the metal species, palladium has proved to be especially useful, while copper may also be used in some reactions [81. Thus, aryl halides can react with a variety of substrates having acidic C-H bonds under palladium catalysis. 

Sonochemistry has been applied to acceleration of the Reformatsky reaction, Diels-Alder reactions, the arylation of active methylene compounds nucleophilic aromatic substitution of haloarenes, and to hydrostannation and tin hydride reduction. " Other sonochemical applications involve the reaction of benzyl chloride and nitrobenzene, a Sr I reaction in liquid ammonia at room temperature, and Knoevenagel condensation of aromatic aldehydes. lodination of aliphatic hydrocarbons can be accelerated, and oxyallyl cations have been prepared from ot,ot -diiodoketones using sonochemistry. Sonochemistry has been applied to the preparation of carbohydrate compounds.When sonochemistry is an important feature of a chemical reaction, this fact will be noted in the reactions presented in Chapters 10-19. 

H2O2 in methanol. Aryl methyl ketones can be dibrominated (ArCOCHa ArCOCHBr2) in high yields with benzyltrimethylammonium tribromide. Active methylene compounds are chlorinated with NCS and Mg(C104)2. " Similar chlorination in the presence of a chiral copper catalyst led to cx-chlorination with modest enantioselectivity. 

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