Enantioselective 1,2-reduction

COREY Enalioselaclive borane reduction Enantioselective reduction ol ketones by borane or catecholborane catalyzed by oxazaborolldine 3... 

It was discovered by J. C. Saddler and co-workers at Upjohn that for reproducible results it was necessary to reflux the mixture of binaphthol, UiAIH4, and EtOH before performing the reduction. Enantioselective reduction of the acyl stannane can also be effected with Chirald, albeit with slightly diminished enantioselectivity.2... 

Corey-Bakshi-Shibata reduction Enantioselective reduction of ketones with BH3 using oxazaborolidines as catalysts. 100... 

Midland Alpine borane reduction Enantioselective reduction of ketones using Alpine borane. 288... 

Enantioselective Reductions. Enantioselective reductions utilizing NaBH4 premodified with alcohols such as tetrahydro-furfuryl alcohol, methanol, or ethanol in the presence of catalytic amounts (1-5 mol%) of enantiopure -ketoiminato Co complexes could be applied to aromatic ketones ... 

Chemical Reductions Enantioselective reduction of unsymmetric ketones to optically active alcohols is very important in organic synthesis. In the foreword to this section, we will summarize the best practical and useful methods and reagents. 

Pybox)Fe(CH2SiMe3)2 and (5,5)-( Box)Fe(CH2SiMe3)2 (Scheme 4-328) each activated with B(C6F5)3 in diethyl ether using phenylsilane as the stoichiometric reductant. Enantioselectivities are, however, only low to moderate. ... 

Also the arene-arene interactions, as encountered in Chapter 3, are partly due to hydrophobic effects, which can be ranked among enforced hydrophobic interactions. Simultaneous coordination of an aromatic oc amino acid ligand and the dienophile to the central copper(II) ion offers the possibility of a reduction of the number of water molecules involved in hydrophobic hydration, leading to a strengthening of the arene-arene interaction. Hence, hydrophobic effects can have a beneficial influence on the enantioselectivity of organic reactions. This effect is anticipated to extend well beyond the Diels-Alder reaction. 

The enantioselective introduction of chiral centres into an achiral molecule can nowadays be achieved most easily using chiral reductants or oxidants. 

Use of Qi-acetamidoacrylate esters in the Heck reaction allows for the introduction of a dehydroalanine side-chain. The dehydrotryptophans can be reduced catalytically, and this reduction can be done enantioselectively[17]. 

The most common oxidatiou states and corresponding electronic configurations of rhodium are +1 which is usually square planar although some five coordinate complexes are known, and +3 (t7 ) which is usually octahedral. Dimeric rhodium carboxylates are +2 (t/) complexes. Compounds iu oxidatiou states —1 to +6 (t5 ) exist. Significant iudustrial appHcatious iuclude rhodium-catalyzed carbouylatiou of methanol to acetic acid and acetic anhydride, and hydroformylation of propene to -butyraldehyde. Enantioselective catalytic reduction has also been demonstrated. 

Because the Corey synthesis has been extensively used in prostaglandin research, improvements on the various steps in the procedure have been made. These variations include improved procedures for the preparation of norbomenone (24), alternative methods for the resolution of acid (26), stereoselective preparations of (26), improved procedures for the deiodination of iodolactone (27), alternative methods for the synthesis of Corey aldehyde (29) or its equivalent, and improved procedures for the stereoselective reduction of enone (30) (108—168). For example, a catalytic enantioselective Diels-Alder reaction has been used in a highly efficient synthesis of key intermediate (24) in 92% ee (169). 

In a first step, JS ocardia asteroides selectively oxidizes only (3)-pantolactone to ketopantolactone (19), whereas the (R)-pantolactone remains unaffected (47). The accumulated ketopantolactone is stereospecificaHy reduced to (R)-pantolactone in a second step with Candidaparapsilosis (product concentration 72 g/L, 90% molar yield and 100% ee) (48). Racemic pantolactone can also be converted to (R)-pantolactone by one single microbe, ie, Jiodococcus erythropolis by enantioselective oxidation to (3)-pantolactone and subsequent stereospecific reduction in 90% yield and 94% ee (product concentration 18 g/L) (40). 

Despite the progress made in the stereoselective synthesis of (R)-pantothenic acid since the mid-1980s, the commercial chemical synthesis still involves resolution of racemic pantolactone. Recent (ca 1997) synthetic efforts have been directed toward developing a method for enantioselective synthesis of (R)-pantolactone by either chemical or microbial reduction of ketopantolactone. Microbial reduction of ketopantolactone is a promising area for future research. 

Optically Active Acids and Esters. Enantioselective hydrolysis of esters of simple alcohols is a common method for the production of pure enantiomers of esters or the corresponding acids. Several representative examples are summarized ia Table 4. Lipases, esterases, and proteases accept a wide variety of esters and convert them to the corresponding acids, often ia a highly enantioselective manner. For example, the hydrolysis of (R)-methyl hydratropate [34083-55-1] (40) catalyzed by Hpase P from Amano results ia the corresponding acid ia 50% yield and 95% ee (56). Various substituents on the a-carbon (41—44) are readily tolerated by both Upases and proteases without reduction ia selectivity (57—60). The enantioselectivity of many Upases is not significantly affected by changes ia the alcohol component. As a result, activated esters may be used as a means of enhancing the reaction rate. 

Reaction of an achiral reagent with a molecule exhibiting enantiotopic faces will produce equal quantities of enantiomers, and a racemic mixture will result. The achiral reagent sodium borodeuteride, for example, will produce racemic l-deM/eno-ethanol. Chiral reagent can discriminate between the prochiral faces, and the reaction will be enantioselective. Enzymatic reduction of acetaldehyde- -[Pg.106]

Scheme 2.12. Enantioselective Reduction of 2-Acetamidoacrylic Acids by Chiral Phosphine Complexes of Rhodium...

The most successful of the Lewis acid catalysts are oxazaborolidines prepared from chiral amino alcohols and boranes. These compounds lead to enantioselective reduction of acetophenone by an external reductant, usually diborane. The chiral environment established in the complex leads to facial selectivity. The most widely known example of these reagents is derived from the amino acid proline. Several other examples of this type of reagent have been developed, and these will be discussed more completely in Section 5.2 of part B. 

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