Stereoselectivity in carbonylations

STEREOSELECTIVITY IN CARBONYL ADDITION REACTIONS, p. 234. ADDmON/EUMINATION REACTIONS OF CARBOXYLIC DERIVATIVES,... 

Scheme 3.2 Reversed stereoselectivity in carbonyl additions with MAD.

Analyze the factors which would determine stereoselectivity in the addition of organometallic compoimds to the following carbonyl compounds. Predict the major product. 

The chemical reduction of enamines by hydride again depends upon the prior generation of an imonium salt (111,225). Thus an equivalent of acid, such as perchloric acid, must be added to the enamine in reductions with lithium aluminum hydride. Studies of the steric course (537) of lithium aluminum hydride reductions of imonium salts indicate less stereoselectivity in comparison with the analogous carbonyl compounds, where an equatorial alcohol usually predominates in the reduction products of six-membered ring ketones. 

Stereoselectivity in the condensation reaction of 2-arylethylamines with carbonyl compounds to give 1,2,3,4-tetrahydroisoquinoline derivatives was somewhat dependent on whether acid catalysis or superacid catalysis was invoked. Particularly in the cases of 2-alkyl-N-benzylidene-2-phenethylamines, an enhanced stereoselectivity was observed with trifluorosulfonic acid (TFSA) as compared with the weaker acid, trifluoroacetic acid (TFA). Compound 43 was cyclized in the presence of TFA to give modest to good transicis product ratios. The analogous compound 44 was cyclized in the presence of TFSA to give slightly improved transicis product ratios. 

As well as for metalated epoxides, the trifluoromethyl moiety also proved an effective organyl-stabilizing group for metalated aziridines. Lithiated aziridine 241 reacted stereoselectively with carbonyl-containing electrophiles, and phenyl disulfide and chlorotrimethylsilane were also trapped in good yield (Scheme 5.60) [70b, 85],... 

The complexation of achiral metal enolates by chiral additives, e.g., solvents or complexing agents could, in principle, lead to reagent-induced stereoselectivity. In an early investigation, the Reformatsky reaction of ethyl bromoacetate was performed in the presence of the bidentate ligand (—)-sparteine20. The enantioselectivity of this reaction varies over a wide range and depends on the carbonyl Compound, as shown with bcnzaldehyde and acetophenone. 

Typically, lyases are quite specific for the nucleophilic donor component owing to mechanistic requirements. Usually, approach of the aldol acceptor to the enzyme-bound nucleophile occurs stereospedfically following an overall retention mechanism, while the facial differentiation of the aldehyde carbonyl is responsible for the relative stereoselectivity. In this manner, the stereochemistry of the C—C bond formation is completely controlled by the enzymes, in general irrespective of the constitution or configuration of the substrate, which renders the enzymes highly predictable. On the other hand, most of the lyases allow a reasonably broad variation of the electrophilic acceptor component that is usually an aldehyde. This feature... 

The existence of ketenes was established over a hundred years ago, and, in recent years, asymmetric synthesis based on [2 + 2] cycloadditions of ketenes with carbonyl compounds to form chiral p-lactones has been achieved with high yields and high stereoselectivities. In 1994, Miyano et al. reported the use of Ca-symmetric bis(sulfonamides) as ligands of trialkylaluminum complexes to promote the asymmetric [2 + 2] cycloaddition of ketenes with aldehydes. The corresponding oxetanones were obtained in good yields and enantioselectivities... 

A similar preference for formation of the syn aldol is found for other Z-enolates derived from ketones in which one of the carbonyl substituents is bulky. Ketone enolates with less bulky substituents show a decreasing stereoselectivity in the order r-butyl > i-propyl > ethyl.2c This trend parallels a decreasing preference for stereoselective formation of the Z-enolate. 

Scheme 9.7. Summary of Stereoselectivity of Allylic Reagents in Carbonyl Addition... 

The R,S-family 33, and of course its enantiomer, provide high enantioselectiv-ities and activities for the reductions of itaconic and dehydroamino acid derivatives as well as imines [141], The JosiPhos ligands have found industrial applications for reductions of the carbon-carbon unsaturation within a,/ -unsaturated carbonyl substrates [125, 127, 131, 143-149]. In contrast, the R,R-diastereoisomerof30 does not provide high stereoselection in enantioselective hydrogenations [125, 141]. 

Boranes have opened the door to asymmetric reduction of carbonyl compounds. The first attempt at modifying borane with a chiral ligand was reported by Fiaud and Kagan,75 who used amphetamine borane and desoxyephedrine borane to reduce acetophenone. The ee of the 1-phenyl ethanol obtained was quite low (<5%). A more successful borane-derived reagent, oxazaborolidine, was introduced by Hirao et al.76 in 1981 and was further improved by Itsuno and Corey.77 Today, this system can provide high stereoselectivity in the asymmetric reduction of carbonyl compounds, including alkyl ketones. 

Hermans JJ, Thijssen HH. Properties and stereoselectivity of carbonyl reductases involved in the ketone reduction of warfarin and analogues. Adv Exp Med Biol 1993 328 351-360. 

Other reagents used for the preparation of lactones from acid anhydrides are lithium borohydride [1019], lithium triethylborohydride (Superhydride ) [1019] and lithium tris sec-butyl)borohydride (L-Selectride ) [1019]. Of the three complex borohydrides the last one is most stereoselective in the reduction of 3-methylphthalic anhydride, 3-methoxyphthalic anhydride, and 1-methoxynaphthalene-2,3-dicarboxylic anhydride. It reduces the less sterically hindered carbonyl group with 85-90% stereoselectivity and is 83-91% yield [1019]. 

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