Steric effects Mukaiyama reactions

A stereoselective Mukaiyama-type aldol reaction of bis(trimethylsilyl)ketene acetals produces silyl aldols with syn stereoselectivity, predominantly due to steric effects.23... 

In 2014 Phiko, Papai et al. tested a series of (25,55)-2,5-disubstituted pyrrolidines as catalysts for enantioselective Mukaiyama-Michael reactions between 2-silylo qr-furans and a,p-unsaturated aldehydes and found that 33, used in the presence of 4-nitro-benzoic acid as the cocatalyst, was the best catalyst in terms of selectivity (Scheme 11.31). Since 33 is not so sterically hindered, the authors also performed a detailed high-level DPT computational study to rationalise the stereochemical outcome, which was found to be controlled not by steric effects, but by the sum of a number of attractive noncovalent interactions involving the catalyst aromatic rings and the furan system. 

N-Pyrrolylmethyketene (81) generated as an unobserved intermediate by treatment of the carboxylic acid with Mukaiyama s reagent in the presence of benzylideneaniline gives the iram-P-lactam in 53% yield (Eqn (4.43))." ° The preference for iraws-3-lactam formation with more crowded ketenes has been attributed to steric effects in the ring-closing step of the reaction (see Section 4.3.2.2 below). 

Mukaiyama aldol reactions, whereby trimethylsilyl enol ethers react with aldehydes in aqueous solution to form -ketoalcohols, have been promoted by new chiral lanthanide-containing complexes and a chiral Fe(II)-bipyridine complex with 0 outstanding diastereo- and enantio-selectivities. Factors controlling the diastereoselec-tivity of Lewis-acid-catalysed Mukaiyama reactions have been studied using DFT to reveal the transition-state influences of substituents on the enol carbon, the a-carbon of the silyl ether, and the aldehyde. The relative steric effects of the Lewis acid and 0 trimethyl silyl groups and the influence of E/Z isomerism on the aldol transition state were explored. Catalytic asymmetric Mukaiyama aldol reaction of difluoroenoxysilanes with /-unsaturated a-ketoesters has been reported for the first time and studied extensively. ... 

The mechanism of the Mukaiyama aldol reaction largely depends on the reaction conditions, substrates, and Lewis acids. Linder the classical conditions, where TiCl4 is used in equimolar quantities, it was shown that the Lewis acid activates the aldehyde component by coordination followed by rapid carbon-carbon bond formation. Silyl transfer may occur in an intra- or intermolecular fashion. The stereochemical outcome of the reaction is generally explained by the open transition state model, and it is based on steric- and dipolar effects. " For Z-enol silanes, transition states A, D, and F are close in energy. When substituent R is small and R is large, transition state A is the most favored and it leads to the formation of the anf/-diastereomer. In contrast, when R is bulky and R is small, transition state D is favored giving the syn-diastereomer as the major product. When the aldehyde is capable of chelation, the reaction yields the syn product, presumably via transition state h. ... 

Activation of the (f )-binolato-Ti(OiPr)2 (2) by highly acidic and sterically demanding alcohols as achiral rather than chiral activators is also effective to provide higher levels of enantioselectivity than those attained by the parent enantio-pure binolato-Ti(OiPr) catalyst (2) in the Mukaiyama aldol reaction of silyl enol ethers (Eq. (7.22)) [55]. 

The first use of a polymer-supported Mukaiyama reagent for microwave-mediated synthesis of amides was presented in 2004 [125]. To prove its effectiveness, even in difficult coupling reactions, it was used in the microwave-accelerated synthesis of an amide from sterically hindered pivalic acid (Scheme 16.83). The mixture was subjected to microwave irradiation at 100 °C for 10 min and the desired product was obtained in 80% yield. 

The structural features of 11b are noteworthy even in the presence of excess amino acid, only the 1 1 complex of 12 and Co was detected by NMR spectroscopy in sharp contrast to complex 4 (Fignre 4.4). This is probably due to the steric bulk of ligand 12 and explains its increased reactivity and lower stability. Unfortunately, we were unable to obtain reproducible results using complex 11b, as yields (40-70%) and reaction time (8 8 h) were batch-dependent. In many cases, an initiation time was observed before the reaction started. Mukaiyama and co-workers used ferf-butyl hydroperoxide as a cobalt-catalyst for the hydration of certain olefins when initiation of the reaction was difficult. A similar effect was observed in the hydroazidation reaction when using catalyst 11 with ethanesulfonyl azide (7) for the hydroazidation of 4-phenylbut-l-ene (3), complete conversion was observed after 2-8 h using 30% of ferf-butyl hydroperoxide. In situ formation of complex 11b in the reaction mixture leads to reproducible reaction times (2h) and yields (70%). Co(BF4)2-6H20 was the best Co salt for this procedure, as complex formation was faster than with other salts and quick oxidation to the Co(III) complex occurred in the presence of tert-butyl hydroperoxide. 

Jung and coworkers reported AlBr3/Me3Al system as an effective mixed Lewis acid system for Diels-Alder reaction of sterically hindered dienophiles and dienes (Scheme 6.126) [150]. It was proposed that this reaction proceeds via Mukaiyama-Michael addition of silyl enol ether moiety to cyclohexenone followed by intramolecular Michael like process. 

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