Phase-transfer reactions Michael addition

Keywords caclohexanone derivative, a,/ -unsaturated carbonyl compound, phase transfer reaction, Michael addition, 1,5-dicarbonyl compound... 

Very recently, the Siva group successfully reported a chiral multisite phase-transfer catalytic Michael addition by the use of 2,4,6-(triscincho-niummethyl)phenyl-l,3,5-triazines as new polymeric chiral quaternary ammonium PTC catalysts. Catalyst 12c showed a higher catalytic efficiency than the corresponding monomeric catalyst 8q in terms of chemical yield and enantioselectivity due to the trimeric reaction sites of 12c, which can promote efficient ion-pair interactions between the a-carbon of the diethyl-malonate and trimeric catalysts due to steric factors (Scheme 16.22). ... 

Class (2) reactions are performed in the presence of dilute to concentrated aqueous sodium hydroxide, powdered potassium hydroxide, or, at elevated temperatures, soHd potassium carbonate, depending on the acidity of the substrate. Alkylations are possible in the presence of concentrated NaOH and a PT catalyst for substrates with conventional pX values up to - 23. This includes many C—H acidic compounds such as fiuorene, phenylacetylene, simple ketones, phenylacetonittile. Furthermore, alkylations of N—H, O—H, S—H, and P—H bonds, and ambident anions are weU known. Other basic phase-transfer reactions are hydrolyses, saponifications, isomerizations, H/D exchange, Michael-type additions, aldol, Darzens, and similar... 

Michael-aldol reaction as an alternative to the Morita-Baylis-Hillman reaction 14 recent results in conjugate addition of nitroalkanes to electron-poor alkenes 15 asymmetric cyclopropanation of chiral (l-phosphoryl)vinyl sulfoxides 16 synthetic methodology using tertiary phosphines as nucleophilic catalysts in combination with allenoates or 2-alkynoates 17 recent advances in the transition metal-catalysed asymmetric hydrosilylation of ketones, imines, and electrophilic C=C bonds 18 Michael additions catalysed by transition metals and lanthanide species 19 recent progress in asymmetric organocatalysis, including the aldol reaction, Mannich reaction, Michael addition, cycloadditions, allylation, epoxidation, and phase-transfer catalysis 20 and nucleophilic phosphine organocatalysis.21... 

Diphenyl-l,4-thiodioxane-l-oxide [21] and the corresponding sulfone (1,1-dioxide) [22] have been isolated in 12% and 48% yields respectively from phase transfer reactions containing sodium hydroxide, benzaldehyde, and either dimethyl sulfoxide or dimethyl sulfone. Apparently, an a,j3-unsaturated sulfone is produced in the first condensation step and the jS-hydroxysulfone which results from a second condensation step undergoes an intramolecular Michael addition as shown in equation 13.12. 

The base-catalyzed Michael—type addition of active hydrogen compounds to activated double bonds is generally performed under homogeneous conditions and lays therefore at the borderline of the scope of this paper, even if it has been sometimes carried out under typical phase transfer conditions. However, considering that the catalysts promoting phase transfer reactions, i.e. ammonium salts, amines and crown ethers, are generally active in the Michael addition, the reported reactions will be discussed here in some details also for the reasons mentioned in the introduction. 

Maruoka and coworkers [65] also reported the total synthesis of (+) mono-morine (127) using a phase-transfer-catalyzed conjugate addition of glycine ester 128 to Michael acceptor 129 as an early key step in the synthesis sequence. Monomorine (127) is a bicyclic amine, known to be the trail pheromone of Monomorium pharanois [66]. The conjugate addition product 131 was subjected to an intramolecular reductive amination and acetal hydrolysis in one pot reaction with Hantzsch ester 132 and trifluoroacetic acid in aqueous... 

The formation of cyclopropanes from 7C-deficient alkenes via an initial Michael-type reaction followed by nucleophilic ring closure of the intermediate anion (Scheme 6.26, see also Section 7.3), is catalysed by the addition of quaternary ammonium phase-transfer catalysts [46,47] which affect the stereochemistry of the ring closure (see Chapter 12). For example, equal amounts of (4) and (5) (X1, X2 = CN) are produced in the presence of benzyltriethylammonium chloride, whereas compound (4) predominates in the absence of the catalyst. In contrast, a,p-unsatu-rated ketones or esters and a-chloroacetic esters [e.g. 48] produce the cyclopropanes (6) (Scheme 6.27) stereoselectively under phase-transfer catalysed conditions and in the absence of the catalyst. Phenyl vinyl sulphone reacts with a-chloroacetonitriles to give the non-cyclized Michael adducts (80%) to the almost complete exclusion of the cyclopropanes. 

Acrylonitrile, polymerization, 120 Activity of phase-transfer catalysts Sjj2 reactions, 170-175 weak-nucleophile Sj.Ar reactions, 175-182 Acyltetracarbonyl cobalt compound, cleavage in the carboxyalkylation of alkyl halides, 150 Addition reactions, Michael, catalytic asymmetric, 69,70f... 

Reaction of the regioisomers of tetrahydrophosphinine oxide (51) with Na0H-H20-CHCl3 under phase-transfer conditions was found to afford tetrahydrophosphepine oxides (52) through an unexpected path involving isomerization of (51) and cyclopropanation via Michael addition of CCls. (Scheme 21). 

A chiral phase transfer catalyst was dissolved in ionic liquid media for the enantioselective Michael reaction of dimethyl malonate with l,3-diphenylprop-2-en-l-one with K2CO3 203). The phase-transfer catalyst was a chiral quininium bromide (Scheme 20). The reaction proceeded rapidly with good yield and good enantioselectivity at room temperature in all three ionic liquids investigated, [BMIM]PF6, [BMIM]BF4 and [BPy]BF4. In the asymmetric Michael addition, the enantioselectivity or the reaction in [BPy]Bp4 was the same as in conventional organic solvents. 

The reaction is carried out in vapour phase (250°C) using a flow system (see methods section). This procedure turned out to be essential in order to mantain the hydrogen transfer as the main reaction pathway. A batch experiment carried out in an autoclave actually showed a wide range of condensation products besides some saturated ketone [6]. Reactions of ketones over oxide catalysts can lead to a variety of products due inter alia to aldol condensation, intramolecular dehydration and intermolecular disproportionation [16]. However, the presence of a good hydrogen donor such as a secondary alcohol and vapour phase conditions favour the transfer hydrogenation as the major reaction [16,17]. In our reaction conditions, products attributable to crotonic condensations and subsequent 1,4 Michael addition [18] were observed by g.l.c.-m.s. (Table 1). 

Recently, Maruoka and coworkers addressed the importance of dual-functioning chiral phase-transfer catalysts such as 70a for obtaining a high level of enantio-selectivity in the Michael addition of malonates to chalcone derivatives (Scheme 5.35) [37]. For instance, the reaction of diethyl malonate with chalcone in... 

Arai et al. also reported another BINOL-derived two-center phase-transfer catalyst 31 for an asymmetric Michael reaction (Scheme 6.11) [8b]. Based on the fact that BINOL and its derivatives are versatile chiral catalysts, and that bis-ammonium salts are expected to accelerate the reaction due to the two reaction sites - thus preventing an undesired reaction pathway - catalyst 31 was designed and synthesized from the di-MOM ether of (S)-BINOL in six steps. After optimization of the reaction conditions, the use of 1 mol% of catalyst 31a promoted the asymmetric Michael reaction of glycine Schiff base 8 to various Michael acceptors, with up to 75% ee. When catalyst 31b or 31c was used as a catalyst, a lower chemical yield and selectivity were obtained, indicating the importance of the interaction between tt-electrons of the aromatic rings in the catalyst and substrate. In addition, the amine moiety in catalyst 31 had an important role in enantioselectivity (34d and 34e lower yield and selectivity), while catalyst 31a gave the best results. 

Whilst simple alkylations of enolates and Michael additions have been successfully catalyzed by phase-transfer catalysts, aldol-type processes have proved more problematic. This difficulty is due largely o the reversible nature of the aldol reaction, resulting in the formation of a thermodynamically more stable aldol product rather than the kinetically favored product. However, by trapping the initial aldol product as soon as it is formed, asymmetric aldol-type reactions can be carried out under phase-transfer catalysis. This is the basis of the Darzens condensation (Scheme 8.2), in which the phase-transfer catalyst first induces the deprotonation of an a-halo... 

Taddol has been widely used as a chiral auxiliary or chiral ligand in asymmetric catalysis [17], and in 1997 Belokon first showed that it could also function as an effective solid-liquid phase-transfer catalyst [18]. The initial reaction studied by Belokon was the asymmetric Michael addition of nickel complex 11a to methyl methacrylate to give y-methyl glutamate precursors 12 and 13 (Scheme 8.7). It was found that only the disodium salt of Taddol 14 acted as a catalyst, and both the enantio- and diastereos-electivity were modest [20% ee and 65% diastereomeric excess (de) in favor of 12 when 10 mol % of Taddol was used]. The enantioselectivity could be increased (to 28%) by using a stoichiometric amount of Taddol, but the diastereoselectivity decreased (to 40%) under these conditions due to deprotonation of the remaining acidic proton in products 12 and 13. Nevertheless, diastereomers 12 and 13 could be separated and the ee-value of complex 12 increased to >85% by recrystallization, thus providing enantiomerically enriched (2S, 4i )-y-methyl glutamic add 15. 

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