Chiral ketone

Synthesis of OC- and P-Ghiral Ketones, Esters, and Nitriles. Chiral boronic esters are convenient precursors of a-chiral ketones (R COR ), which can be prepared via the dialkylborinic ester or dialkylthexyl route (524,525). 

The conversion of chiral boronic esters iato optically pure B-aIkyl-9-BBN derivatives followed by reaction with a-bromoketones, a-bromoesters, or a-bromonitriles leads to the homologated P-chiral ketones, esters, and nitriles, respectively (526). 

The use of chiral ketones for the protection of diols serves two purposes first, diol protection is accomplished, and second, symmetrical intermediates are converted to chiral derivatives that can be elaborated further, so that when the diol is deprotected, the molecule retains chirality. ... 

The past thirty years have witnessed great advances in the selective synthesis of epoxides, and numerous regio-, chemo-, enantio-, and diastereoselective methods have been developed. Discovered in 1980, the Katsuki-Sharpless catalytic asymmetric epoxidation of allylic alcohols, in which a catalyst for the first time demonstrated both high selectivity and substrate promiscuity, was the first practical entry into the world of chiral 2,3-epoxy alcohols [10, 11]. Asymmetric catalysis of the epoxidation of unfunctionalized olefins through the use of Jacobsen s chiral [(sale-i i) Mi iln] [12] or Shi s chiral ketones [13] as oxidants is also well established. Catalytic asymmetric epoxidations have been comprehensively reviewed [14, 15]. 

In accord with the Felkin-Anh model, a-chiral ketones react more diastereoselectively than the corresponding aldehydes. Increasing steric demand of the acyl substituent increases the Cram selectivity. Due to the size of the acyl substituent, the incoming nucleophile is pushed towards the stereogenic center and therefore the diastereoface selection becomes more effective (see also Section 1.3.1.1.). Thus, addition of methyllithium to 4-methyl-4-phenyl-3-hexanonc (15) proceeds with higher diastercoselectivity than the addition of ethyllithium to 3-methyl-3-phenyl-2-pen-tanone (14)32. 

Trimethylsilyl)-2-propenyl]zinc chloride in four-fold excess, generated in situ from the lithium compound by addition of anhydrous zinc chloride, reacts with chiral ketones, e.g., 2-bor-nanonc, to form the ( )-vinylsilanes with high y-regio- and induced diastcreoselectivity44,45. 

Addition of Chiral Etiolates to Achiral Carbonyl Compounds 1.3.4.2.1. Chiral Ketone Enolates 1.3.4.2.L1. yi H-Sclectivc Ketone Enolates... 

Very high levels of induced diastereoselectivity are also achieved in the reaction of aldehydes with the titanium enolate of (5)-l-rerr-butyldimethylsiloxy-1-cyclohexyl-2-butanone47. This chiral ketone reagent is deprotonated with lithium diisopropylamide, transmetalated by the addition of triisopropyloxytitunium chloride, and finally added to an aldehyde. High diastereoselectivities are obtained when excess of the titanium reagent (> 2 mol equiv) is used which prevents interference by the lithium salt formed in the transmetalation procedure. Under carefully optimized conditions, diastereomeric ratios of the adducts range from 70 1 to >100 1. 

A combination of substrate-induced and auxiliary-induced stereoselectivity is provided by the diisopinocampheylborinates 11a and lib derived from the chiral ketone (S)-l-benzyloxy-2-mcthyl-3-pentanone52. Whereas this ketone provides no significant diastereoselectivity when converted into the dibutylboron enolate and, subsequently, added to aldehydes, use of the diisopinocampheyl reagents 11a and lib leads to the jS-hydroxy ketones 12 and 13 in a stereoselective manner. The chiral information which is located in the carbon chain of the starting ketone 10 is incorporated into the products ... 

Due to their tendency to form (Z)-enolates, ketones usually provide syn-aldols, and anti-se ec-tive chiral ketone enolates are rare. When, however, (S)-5,5-dimethyl-4-trimethylsiloxy-3-hex-anone is deprotonated with (V-(bromomagnesio)-2,2,6,6-tetramethylpiperidine, the (E)-enolate la is assumed to be formed. Subsequent addition to aldehydes delivers anh-aldols 2a and 3a in ratios of between 92 8 and 95 5 and yields of 75-85%53b. 

In a chiral aldehyde or a chiral ketone, the carbonyl faces are diastereotopic. Thus, the addition of an enolate leads to the formation of at least one stereogenic center. An effective transfer of chirality from the stereogenic center to the diastereoface is highly desirable. In most cases of diastereoface selection of this type, the chiral aldehyde or ketone was used in the racemic form, especially in early investigations. However, from the point of view of an HPC synthesis, it is indispensable to use enantiomerically pure carbonyl compounds. Therefore, this section emphasizes those aldol reactions which are performed with enantiomerically pure aldehydes. 

The asymmetric Michael addition of chiral nonracemic ketone enolates has most frequently been used as part of the Robinson annulation methodology in the synthesis of natural products171-172. The enolates are then derived from carbocyclic chiral ketones such as (+)-nopinone, (-)-dihydrocarvone, or (-)-3-methylsabinaketone. 

Several methods for asymmetric C —C bond formation have been developed based on the 1,4-addition of chiral nonracemic azaenolates derived from optically active imines or enamines. These methods are closely related to the Enders and Schollkopf procedures. A notable advantage of all these methods is the ready removal of the auxiliary group. Two types of auxiliaries were generally used to prepare the Michael donor chiral ketones, such as camphor or 2-hydroxy-3-pinanone chiral amines, in particular 1-phenylethanamine, and amino alcohol and amino acid derivatives. 

Enantioselective enolate formation can also be achieved by kinetic resolution through preferential reaction of one of the enantiomers of a racemic chiral ketone such as 2-(f-butyl)cyclohcxanone (see Section 2.1.8 of Part A to review the principles of kinetic resolution). 

The trialkylborane can be transformed to a dialkyl(ethoxy)borane by heating with acetaldehyde, which releases the original chiral a-pinene. Finally application of one of the carbonylation procedures outlined in Scheme 9.1 gives a chiral ketone.17 The enantiomeric excess observed for ketones prepared in this way ranges from 60-90%. 

A number of chiral ketones have been developed that are capable of enantiose-lective epoxidation via dioxirane intermediates.104 Scheme 12.13 shows the structures of some chiral ketones that have been used as catalysts for enantioselective epoxidation. The BINAP-derived ketone shown in Entry 1, as well as its halogenated derivatives, have shown good enantioselectivity toward di- and trisubstituted alkenes. 

Scheme 12.13. Chiral Ketones Used for Enantioselective Epoxidation...

A jy -diastereoselective aldol reaction based on titanium enolates from (A)-l-benzyloxy-2-methyl-3-pentanone was developed by Solsona et al. (Equation (12)).64 The titanium enolate of this chiral ketone afforded the corresponding syn-syn aldol adducts in high yields and diastereomeric ratios with a broad range of aldehydes. 

It has been reported that the cleavage of SAMP hydrazones can proceed smoothly with a saturated aqueous oxalic acid, and this allows the efficient recovery of the expensive and acid-sensitive chiral auxiliaries SAMP and RAMP. No racemization of the chiral ketones occurs during the weak acid oxalic acid treatment, so this method is essential for compounds sensitive to oxidative cleavage.393... 

In studies of the asymmetric epoxidation of olefins, chiral peroxycarboxylic acid induced epoxidation seldom gives enantiomeric excess over 20%.1 Presumably, this is due to the fact that the controlling stereocenters in peroxycarboxylic acids are too remote from the reaction site. An enantiomeric excess of over 90% has been reported for the poly-(Y)-alanine-catalyzcd epoxidation of chalcone.2 The most successful nonmetallic reagents for asymmetric epoxidation have been the chiral TV-sulfonyloxaziridincs3 until asymmetric epoxidation reactions mediated by chiral ketones were reported. Today, the... 

Chiral Ketone-Catalyzed Asymmetric Oxidation of Unfunctionalized Olefins... 

Chiral Ketone from Carbohydrate. Tu et al.100 reported a dioxir-ane-mediated asymmetric epoxidation based on the ketones derived from the low cost material D-fructose (Scheme 4-47). 

Subsequently, high chemoselectivity and enantioselectivity have been observed in the asymmetric epoxidation of a variety of conjugated enynes using fructose-derived chiral ketone as the catalyst and Oxone as the oxidant. Reported enantioselectivities range from 89% to 97%, and epoxidation occurs chemoselectively at the olefins. In contrast to certain isolated trisubstituted olefins, high enantioselectivity for trisubstituted enynes is noticeable. This may indicate that the alkyne group is beneficial for these substrates due to both electronic and steric effects. 

Mechanistic studies103 revealed that chiral ketone-mediated asymmetric epoxidation of hydroxyl alkenes is highly pH dependent. Lower enantioselectivity is obtained at lower pH values at high pH, epoxidation mediated by chiral ketone out-competes the racemic epoxidation, leading to higher enantioselectivity. (For another mechanistic study on ketone-mediated epoxidation of C=C bonds, see Miaskiewicz and Smith.104)... 

S.3.2 A C2 Symmetric Chiral Ketone for Catalytic Asymmetric Epox-idation of Unfunctionalized Olefins. Yang et al.105 reported the use of... 

Following their success with chiral ketone-mediated asymmetric epoxidation of unfunctionalized olefins, Zhu et al.113 further extended this chemistry to prochiral enol silyl ethers or prochiral enol esters. As the resultant compounds can easily be converted to the corresponding a-hydroxyl ketones, this method may also be regarded as a kind of a-hydroxylation method for carbonyl substrates. Thus, as shown in Scheme 4-58, the asymmetric epoxidation of enol silyl... 

The epoxidation of nonfunctionalized alkenes may also be effected by chiral dioxiranes. These species, formed in situ using the appropriate ketone and potassium caroate (Oxone), can be formed from C-2 symmetric chiral ketones (29)[93], functionalized carbohydrates (30)[94] or alkaloid derivatives (31)[95]. One example from the laboratories of Shi and co-workers is given in Scheme 19. 

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