Enantioselective silyl nitronates

As an extension of this highly enantioselective Michael addition of silyl nitronates with a, p-unsaturated aldehydes, the reactions with cyclic a,p-unsaturated ketones as a Michael acceptor were also tested (Scheme 9.15). Cyclohexenone and cyclohepte-none were employed as a useful Michael acceptor with various silyl nitronates in the presence of catalyst (R,R)-6c, and gave the corresponding enol silyl ethers 28 with excellent stereoselectivities [30]. 

Further applications of the chiral ammonium bifluoride-catalyzed enantioselective Michael addition of silyl nitronates has been shown in the reactions with nitroalkenes as a Michael acceptor (Scheme 9.17). These studies were started by examining the reaction of nitropropane-derived silyl nitronate 23b with P-nitrostyrene, using the chiral quaternary ammonium bifluoride (R,.R)-6d. When P-nitrostyrene was treated with 23b (1.2 equiv.) in the presence of (K,f )-6d (2mol%) in THF at — 78 °C, the... 

Highly enantioselective Michael addition of silyl nitronates (105) to cyclic o /3-unsaturated ketones (106 n = 0-2) has been accomplished by the utilization of N-spiro C2-symmetric chiral quaternary ammonium bifluoride (108) as an organocatalyst, offering a new route to the enol silyl ethers of scalemic y-nitro ketones (107 70-90% ee).156... 

The efficient homogeneous catalysis of chiral ammonium bifluorides of type 15 has been further utilized for achieving an asymmetric Michael addition of silyl nitronates to a,/ -unsaturated aldehydes. Here, chiral ammonium bifluoride 15b bearing a 3,5-di-tert-butylphenyl group was found to be the catalyst of choice, and the reaction of 16a with trans-cinnamaldehyde under the influence of (R,R)- 15b (2 mol%) in THF at —78 °C produced the 1,4-addition product 18 predominantly (18/19 = 24 1) as a diastereomeric mixture (syn/anti = 78 22) with 85% ee of the major syn isomer (Scheme 4.9). Further, use of toluene as solvent led to almost exclusive formation of the 1,4-adduct (18/19 = 32 1) with similar diastereoselec-tivity (syn/anti = 81 19), and critical enhancement of the enantioselectivity was attained (97% ee) [15]. 

The preference of the steric effect was also demonstrated by the 1,4-addition of silyl nitronate (54) to cinnamaldehyde (55) where the sterically bulky substituents CF3 and f-Bu provided higher regio-, stereo- (synlanti), and enantioselectivities (Scheme 5.16, Table 5.6)... 

Table 5.6 Effect of substituents on the regio and enantioselectivity of 1,4-addition of silyl nitronate 54 to 55... 

Silyl nitronates undergo enantioselective addition to aromatic aldehydes in the presence of an enantiomerically pure bifluoride derived from (7.103). In this approach the anti-adduct is the major diastereomer formed. Thus silyl nitronate (7.105) undergoes addition to benzaldehyde to give adduct (7.106) with high ee. Alternately the coupling of silyl nitronates can be achieved with high ee using Lewis acids such as copper bis-oxazoline catalyst (7.107) in combination with a fluoride... 

Scheme 5.29 Enantioselective 106f-catalyzed Michael reaction of silyl nitronates with a,P-unsaturated aldehydes.

Maruoka et al. have developed and used A-spiro C2-symmetric chiral quaternary ammonium bifluorides [151] 102, 103, and more recently 104, to promote the regio- and anti-selective Mukaiyama-Michael addition of silyl nitronates to a, 3-unsaturated aldehydes [152], cyclic a,P-unsaturated ketones [153], and nitroalk-enes [154] with good yields and enantioselectivities (Scheme 2.52). Final chiral silyl enol ethers are easily hydrolyzed to the corresponding carbonyl compounds or functionalized at the a-position by reaction with electrophiles. 

The second most important synthetic application of silyl nitronates in C-C bond-forming reactions is their fluoride-mediated addition to aldehydes. Silyl nitronates from secondary nitroalkanes lead to free nitro aldols such as (4), while those from primary nitro alkanes give silylated products. In contrast to the classical Henry reaction, the silyl variant is highly diastereose-lective with aldehydes, furnishing e yfAro-0-silylated nitro aldols (e.g. 5). It is important that the reaction temperature does not rise above 0 °C, otherwise threo/erythro equilibration takes place. The same erythro-nitio aldol derivatives are available by diastere-oselective protonation of silyloxy nitronates (eq 3) (usually the dr is >20 1), while the nonsilylated fAreo-epimers (R = H, dr = 7 3-20 1) are formed by kinetic protonation of lithioxy lithio nitronates in THF/DMPU (eq 4). Other recent modifications of the nitroaldol addition using titanium nitronates or ClSiRs in situ are less selective. It should also be mentioned that there are recent reports about the enantioselective addition of nitromethane to aldehydes in the presence of rare earth binaphthol complexes. 

Based on the enantioselective Michael addition/ISOC (intramolecular silyl nitronate olefin cycloaddition)/lragmentation sequence previously developed by the group of Rodriguez [33a], Shao and coworkers proposed an extrapolation for the construction of spirooxindoles catalyzed by a bifunctional tertiary amine-thiourea catalyst XV between 4-allyl-substituted oxindoles 63 and nitrostyrenes 64 (Scheme 10.21) [33b]. After the addition of TMSCl and EtgN at -30 C, the Michael adduct underwent an ISCX3 to afford the spiro oxime derivatives 65 in very good yields (85-85%), and excellent diastereo (up to >30 1) and enantioselectivities (94-99% ee) after the treatment with TBAF. 

As mentioned above (66, 393), (see Scheme 3.150) silylation followed by intramolecular enantioselective cycloaddition with five-membered cyclic nitronates, containing the hydroxyl group at C-4, can produce chiral polycyclic structures (293), which are direct precursors of chiral hydroxyamino acids (294) and aminopolyols (295) (Scheme 3.179). 

Highly porous silica gel served as a support for the TADDOL moiety derived from inexpensive and readily available i-tartaric acid, which provided access to htanium-based Lewis acid catalysts (Heckel, 2000). Such entihes are employed successfully for enantioselective reactions. TADDOLs were covalently attached to the trimethyl-silyl-hydrophobized silica gel, controlled-pore glass (CPG) at about 300 m2 g-1, at a loading of 0.3-0.4 mmol gl (Heckel, 2002). In a carefully monitored mulh-step immobilization procedure, the TADDOLs were titanated to yield dichloro-, diisopropyl-, or ditosyl-TADDOLates. These catalysts were employed in dialkylzinc addihon to benzaldehydes and diphenyl nitrone addihon to 3-crotonyloxazolidinone, a [3+2] cycloaddition. 

Examples of the asymmetric functionalization of isoquinoline derivatives were reported in 2002. One example illustrated the enantioselective addition of ketene silyl acetal (82) to cyclic nitrone (81) catalyzed by a chiral titanium complex to prepare 1,2,3,4-tetrahydroisoquinoline (83) in 84% yield with 83% ee <02JA2888>. 

The Mannich reaction and its variants have been reviewed, mainly focussing on asymmetric catalysis thereof. Catalytic, enantioselective, vinylogous Mannich reactions have also been reviewed, covering both direct and silyl dienolate methods. Another review surveys Mannich-type reactions of nitrones, oximes, and hydrazones. A pyrrolidine-thiourea-tertiary amine catalyses asymmetric Mannich reaction of N-Boc-imines (e.g. Ph-Ch=N-Boc) with ethyl-4-chloro-3-oxobutanoate to give highly functionalized product (16). Addition of triethylamine leads to one-pot intramolecular cyclization to give an 0-ethyl tetronic acid derivative (17). ... 

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