Catalysts aldol addition stereoselective

Butyraldehyde undergoes stereoselective crossed aldol addition with diethyl ketone [96-22-0] ia the presence of a staimous triflate catalyst (14) to give a predominantiy erythro product (3). Other stereoselective crossed aldol reactions of //-butyraldehyde have been reported (15). 

Summary of Facial Stereoselectivity in Aldol and Mukaiyama Reactions. The examples provided in this section show that there are several approaches to controlling the facial selectivity of aldol additions and related reactions. The E- or Z-configuration of the enolate and the open, cyclic, or chelated nature of the TS are the departure points for prediction and analysis of stereoselectivity. The Lewis acid catalyst and the donor strength of potentially chelating ligands affect the structure of the TS. Whereas dialkyl boron enolates and BF3 complexes are tetracoordinate, titanium and tin can be... 

As is the case for aldol addition, chiral auxiliaries and catalysts can be used to control stereoselectivity in conjugate addition reactions. Oxazolidinone chiral auxiliaries have been used in both the nucleophilic and electrophilic components under Lewis acid-catalyzed conditions. (V-Acyloxazolidinones can be converted to nucleophilic titanium enolates with TiCl3(0-/-Pr).320... 

The hydrophobicity-driven association of reactant molecules in aqueous solution has even been found in aldol reactions. The trimethylsilyl ether of cyclohexanone adds to benzaldehyde in aqueous solution at 20 °C in the absence of a catalyst to give aldol addition products with a synlanti stereoselectivity opposite to that of the acid-catalyzed reaction carried out in dichloromethane [746]. 

Ester Enolate Aldol Additions to Aldehydes. Among the first examples of aldol additions employing chiral Lewis bases as catalysts were the additions of trichlorosilyl ketene acetals to aldehydes. Silyl ketene acetal 7 could be generated by metathesis of methyl tributylstannylacetate with SiCL. Treatment of 7 with benzaldehyde and 10 mol % of a phosphoramide in CH2CI2 at —78°C afforded aldol products in good to high yields with moderate enantioselectivities for all phosphoramides employed. Reaction of 7 with pivalaldehyde provided aldol products in similar yields and with slightly improved enantioselectivities. The increase in stereoselection is presumably attributed to a less com-... 

Aldol condensation of the tin enolates with aldehydes often takes place spontaneously at room temperature, but Lewis acids (e.g. TiCL, BF3.OEt2, ZnCl2, CuCl2) or PdCl2[(o-C6H4)3P]2 can be used as catalysts, and enantioselective addition can be achieved with an (/ )-BINAP-AgOTf catalyst.101 The stereoselectivity is dependent on the reaction conditions, and the high threo selectivity at low temperature is ascribed to the presence of a cyclic transition state 14-20.104... 

Evans has recently reported the use of structurally well-defined Sn(II) Lewis acids 119 and 120 (Fig. 9)for the enantioselective aldol addition reactions of a-heterosubstituted substrates [83]. These complexes are easily assembled from Sn(OTf)2 and C2-symmetric bisoxazoline Hgands 124 and 126 (Fig. 10). The facile synthesis of these ligands commences with optically active 1,2-amino alcohols 122, which are themselves readily available from the corresponding a-amino acids 121 [84, 85]. The Sn(II) bis(oxazoHne) complexes were shown to function optimally as catalysts for enantioselective aldol addition reactions with aldehydes and ketone substrates that are suited to putatively chelate the Lewis acid. For example, using 10 mol % of 119, thioacetate and thiopropionate derived silyl ketene acetals add at -78 °C in CH2CI2 to glyoxaldehyde to give hydroxy diesters 130 in superb yields and enantioselectivities as well as diastereo-selectivities (Eq. 12). The process represents an unusual example wherein 2,3-anti-aldol adducts are obtained in a stereoselective manner. 

In 2008 Brimble and coworkers examined the effect of a-substitution in proline-based catalysts for the asymmetric aldol addition of acetone to aromatic aldehydes. In the benchmark aldol reaction between acetone and p-nitro-benzaldehyde they observed a remarkable improvement of stereoselectivity using (5 )-a-methyl-tetrazole 9, albeit with longer reaction times caused by the a-geminal disubstitution. Surprisingly 7a afforded a completely racemic product (Scheme 11.7). Using 9 the scope of this reaction was extended efficiently to several other aromatic aldehydes with excellent enantioselectivities (enantiomeric excess — 70-91%). 

Aldol additions of acetone (1) as a nucleophile to ketones without a-acidic protons are feasible. The proline-catalyzed aldol reaction between acetone (1) and 1-aryl-2,2,2-trifluoroethanone (128) led to tertiary alcohol 129 in good yield but with low stereoselectivity [146]. A proline-derived sulfonamide 130 performs much better (Table 3.10, entry 2). Kokotos prepared a prolinamide-thiourea catalyst 131, which under optimum conditions can be used in 2 mol%, even at 0°C (entry 3) [ 147], With proline, the reaction was completed within hours, while more stereoselective catalysts 130 and 131 required 2 days. So far, these are the catalysts of choice for this tran ormation [146-148]. 

Control of Enantioselectivity. In the previous sections, the most important factors in determining the syn or anti stereoselectivity of aldol and Mukaiyana reactions were identified as the nature of the transition state (cyclic versus acyclic) and the configuration (E or Z) of the enolate. Additional factors affect the enantioselectivity of aldol additions and related reactions. Nearby chiral centers in either the carbonyl compound or the enolate can impose facial selectivity. Chiral auxiliaries can achieve the same effect. Finally, use of chiral Lewis acids as catalysts can also achieve enantioselectivity. Although the general principles of control of the stereochemistry of aldol addition reactions have been developed for simple molecules, the application of the principles to more complex molecules and the selection of the optimum enolate system requires analysis of the individual cases.Not infrequently, one of the enolate systems proves to... 

The aldol reaction is one of the most useful carbon-carbon bond forming reactions in which one or two stereogenic centers are constructed simultaneously. Diastereo-and enantioselective aldol reactions have been performed with excellent chemical yield and stereoselectivity using chiral catalysts [142]. Most cases, however, required the preconversion of donor substrates into more reactive species, such as enol silyl ethers or ketene silyl acetals (Scheme 13.45, Mukaiyama-type aldol addition reaction), using no less than stoichiometric amounts of silicon atoms and bases (Scheme 13.45a). From an atom-economic point of view [143], such stoichiometric amounts of reagents, which afford wastes such as salts, should be excluded from the process. Thus, direct catalytic asymmetric aldol reaction is desirable, which utilizes unmodified ketone or ester as a nucleophile (Scheme 13.45b). Many researchers have directed considerable attention to this field, which is reflected in the increasing... 

This concept has been further applied to the development of various stereoselective bond-forming reactions using chiral bis-phosphoramides as catalysts. The most well-explored system is the aldol addition of silyl ketene acetals to aldehydes [6). In general, combination of a catalytic amount of 2 and a stoichiometric quantity of SiCl, was very effective for the reactions of methyl acetate-derived silyl ketene acetal with various aldehydes (Scheme 7.5). 

The synthesis of iminocyclitols was also accomplished using aldol additions of the unphosphorylated analogs of DHAP, dihydroxyacetone (DHA). As mentioned before, RhuA ° and RhuA wild type/borate buffers proved their utility with examples reported in the literature [113, 128, 129]. High conversions, for example 90-99%, were accomplished with RhuA/borate buffer, which are comparable to those achieved under different optimized conditions using DHAP donors. Importantly, the full equivalence of the stereochemical outcome with the additions of DHAP indicated the unbiased orientation of DHA in the active site of RhuA catalyst. Remarkably, the additions of DHA-borate to (R)-N-Cbz-aminoaldehydes furnished exclusively the anti (3R,4R) configured adducts, whereas the (S)-N-Cbz-aminoaldehydes always yielded the syn (3R,4S) adducts. This high stereoselectivity toward the R enantiomers of N-Cbz-aminoaldehydes at 25 °C contrasted with the different syn/anti mixtures of aldol adduct obtained using DHAP [24]. 

The reactions proceeded efficiently under mild conditions in short time. The silyl enol ethers reacted with the activated acetals or aldehydes at -78 °C to give predominant erythro- or threo-products [136, 137] respectively. In the same manner, the aldol reaction of thioacetals, catalyzed by an equimolar amount of catalyst, resulted in <-ketosulfides [139] with high diastereoselectivity. In the course of this investigation, the interaction of silyl enol ethers with a,]3-unsaturated ketones, promoted by the trityl perchlorate, was shown to proceed regioselec-tively through 1,2- [141] or 1,4-addition [138]. The application of the trityl salt as a Lewis acid catalyst was spread to the synthesis of ]3-aminoesters [142] from the ketene silyl acetals and imines resulting in high stereoselective outcome. 

Recently it has been found that high stereoselectivity in the asymmetric aldol reaction of an isocyanoacetate is also obtainable with the silver catalyst containing ferrocenylphosphine ligands 2e, by keeping the isocyanoacetate concentration low throughout the reaction by the slow addition of 3a over a period of 1 h (Scheme 8B1.7, Table 8B1.8) [25]. 

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