Prochiral carbonyls

Reductive alkylation with chiral substrates may afford new chiral centers. The reaction has been of interest for the preparation of optically active amino acids where the chirality of the amine function is induced in the prochiral carbonyl moiety 34,35). The degree of induced asymmetry is influenced by substrate, solvent, and temperature 26,27,28,29,48,51,65). Asymmetry also has been obtained by reduction of prochiral imines, using a chiral catalyst 44). Prediction of the major configurational isomer arising from a reductive alkylation can be made usually by the assumption that amine formation comes via an imine, not the hydroxyamino addition compound, and that the catalyst approaches the least hindered side (57). 

Reaction of optically active a-sulphinyl acetate 298a with prochiral carbonyl compounds proceeds with a high asymmetric induction - , the degree of which depends on the nature of substituents at the carbonyl group (equation 252 Table 22) . The jS-hydroxy sulphoxides 422 formed may be transformed to optically active p-hydroxycarboxylic esters 423 (equation 253) and optically active long-chain lactones 424 99 (equation 254). Corey and coworkers have used this method to introduce a chiral centre at C-3 in their synthesis of maytansin °°, and Papageorgiou and Benezra for the synthesis of chiral a-hydroxyalkyl acrylates 425 ° (equation 255). 

One approach to enantioselective reduction of prochiral carbonyl compounds is to utilize chiral ligand-modified metal hydride reagents. In these reagents, the number of reactive hydride species is minimized in order to get high chemo-selectivity. Enantiofacial differentiation is due to the introduced chiral ligand. 

In recent years, extensive attention has been focused on finding cultured plant cells that can be used as catalysts for organic functional group transformations. A number of transformations employing freely suspended or immobilized plant cell cultures have been reported.24 For example, Akakabe et al.25 report that immobilized cells of Daucus carota from carrot can be used to reduce prochiral carbonyl substrates such as keto esters, aromatic ketones, and heterocyclic ketones to the corresponding secondary alcohols in ( -configuration with enantiomeric excess of 52-99% and chemical yields of 30 63%). 

Chiral 4-chloro-3-hydroxybutanoate esters are important chiral C4-building blocks [43-53]. For example, (i )- and (S)-isomers can be converted to L-car-nitine and the hydroxymethyl glutaryl-CoA reductase inhibitor. Since these compounds are used as pharmaceuticals, a high optical purity is required. A practical enzymatic method for the production of chiral 4-chloro-3-hydroxy-butanoate esters from prochiral carbonyl compounds, i.e.,4-chloroacetoacetate esters, or racemic 4-chloro-3-hydroxybutanoate esters is described. 

The reaction shown in Scheme 39 was also performed starting from a chiral carbamoyl chloride (91, Y = O) derived from (f )-iV-methyl-iV-(l-phenylethyl)amine, in order to study the possible asymmetric induction using prochiral carbonyl compounds. Thus, with pivalaldehyde or benzaldehyde the mixture of diastereomers obtained was ca 1 1. This behavior was also observed with other chiral functionalized organolithium compounds ". ... 

Principles. How shall we proceed toward catalytic asymmetric induction Scheme 5 illustrates a possible way to achieve enantioselective alkylation by using a small amount of chiral source. Under certain conditions, the presence of a protic chiral auxiliary HX can catalyze the addition of organometallic reagent, R2M, to a prochiral carbonyl substrate by way of RMX. To obtain sufficient chiral efficiency, the anionic ligand X must have a three-dimensional structure that allows differentiation between the diastereomeric transition states of the alkyl transfer step. In addition, unlike in stoichiometric reactions, the rate of... 

Electroenzymatic reactions are not only important in the development of ampero-metric biosensors. They can also be very valuable for organic synthesis. The enantio- and diasteroselectivity of the redox enzymes can be used effectively for the synthesis of enantiomerically pure compounds, as, for example, in the enantioselective reduction of prochiral carbonyl compounds, or in the enantio-selective, distereoselective, or enantiomer differentiating oxidation of chiral, achiral, or mes< -polyols. The introduction of hydroxy groups into aliphatic and aromatic compounds can be just as interesting. In addition, the regioselectivity of the oxidation of a certain hydroxy function in a polyol by an enzymatic oxidation can be extremely valuable, thus avoiding a sometimes complicated protection-deprotection strategy. 

Asymmetric hydrosilylation of prochiral carbonyl compounds, imines, alkenes and 1,3-dienes has been extensively studied and continues to be one of the most important subjects in the hydrosilylation reactions. This topic has been reviewed at each stage of its development as a useful synthetic method based on asymmetric catalytic processes1,3,187-189. In the last decade, however, substantial progress has been made in the efficiency of this reaction. Accordingly, this section summarizes the recent advances in this reaction. 

Calculations have shown that nucleophiles with groups attached, such as a methyl anion, take up a staggered arrangement with respect to the sp2 centre they are attacking42. Based on such an approach of the nucleophile, Bassindale, Taylor and collaborators have proposed an empirical model (Scheme 10) for the nucleophilic addition of prochiral car-banions to prochiral carbonyls in the absence of chelation control57. 

Reaction of achiral and chiral bis(oxazolines) (BOX) with catecholborane (CATBH) provides boron-BOXate complexes that can be used as catalysts in the enantioselective reduction of ketones. It has been shown that asymmetric transfer of the hydride ion from the boron atom of CATBH to the prochiral carbonyl is the rate-determining step of the catalytic reaction.314... 

A nucleophilic addition to a prochiral carbonyl compound R -CO-R gives a racemic mixture of alcohols. If the substituent R is chiral, the two faces of the carbonyl become... 

At the very start of Chapter 17, we introduced stereochemistry by thinking about the reactions of two sorts of carbonyl compounds. They are shown again here the first has a prochiral carbonyl group. The second, on the other hand, is not prochiral because no stereo genic centre is created when the compound reacts. 

Exactly the same things are true for the faces of a prochiral carbonyl group or double bond. 

Asymmetric reduction of prochiral carbonyl compounds for the production of chiral alcohols D-pantoyl lactone production by... 

Bottlenecks for bioreduction of prochiral carbonyl compounds by microbial cells for industrial use production... 

ASYMMETRIC REDUCTION OF PROCHIRAL CARBONYL COMPOUNDS FOR THE PRODUCTION OF CHIRAL ALCOHOLS D-PANTOYL LACTONE PRODUCTION BY ASYMMETRIC REDUCTION... 

Chiral alcohols are some of the most important chiral building blocks for the production of pharmaceuticals. The creation of chiral alcohols through the asymmetric reduction of prochiral carbonyl compounds using biocatalysts, such as microbial cells and commercially available oxidoreductases, has been... 

Bottlenecks for Bioreduction of Prochiral Carbonyl Compounds by Microbial Cells for Industrial Use Production of (fl)-4-Chloro-3-Hydroxybutanoate Ethyl Ester... 

For the syn substrate 8, the approach of the organometallic nucleophile is controlled by the steric bias imposed by the bulky DiTOX ring (Fig. 2). The nucleophile approaches the prochiral carbonyl group from the direction of the... 

In 1951 Bothner-By first attempted asymmetric reductions based on the conversion of lithium aluminum hydride (LAH) into a chiral alkoxy derivative by reaction with (+)-camphor. Since this pioneering work, the use of chirally modified LAH reagents has been the focus of much attention. In 1979, the first virtually complete enantiofacial recognition of prochiral carbonyl compounds was accomplished by using LAH modified with optically pure 2,2 -dihydroxy-1,1 -binaphthyl and a simple alcohol (BINAL-H). Asymmetric reduction with chiral 2,5-dimethylborolane also gave alcohols in high optical yields." Recently, excellent results have been obtained using a chirally modified sodium borohydride... 

The most important feature of the BINAL-H asymmetric reduction is the empirical rule for the orientation observed with simple prochiral carbonyl substrates of type (43) (Un = phenyl, alkenyl, alkynyl R =... 

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