Racemic compounds ketones

Synthesis of the common intermediate C (4), and its further conversion to 2 and 3 is illustrated in Scheme 7-3. Two racemic compounds, ( )-7 and ( + )-10, are prepared from readily available starting materials 5 and 8, respectively (Scheme 7-2). Coupling of 7 and 10 gives a mixture of diastereomers 11. An intramolecular aldol reaction of 11 catalyzed by D-proline yields diastereomers 12 and 13 in equal molar ratios (about 36% ee for each diastereomer). Compound 12, the desired ketone, is converted to 14, which is further purified by crystallization to give the compound in the desired stereochemistry in sterically pure form. Reduction of the ketone carbonyl group and subsequent methoxy... 

This Asian species is a major agricultural pest. The pheromone has been proposed to consist of three male-specific compounds, only one of which, (Z)-exo-a-bergamotenal 150, has been reported in the literature [114]. The racemic compound was synthesized starting from farnesoic acid chloride 146 (Scheme 25) [114]. Thus, the vinyl ketene prepared from acid chloride 146 underwent 2+2 cycloaddition to give bicyclic ketone 147. The ketone function was removed by reaction with hydrazine followed by treatment of the resulting hy-... 

Dynamic Resolution of Chirally Labile Racemic Compounds. In ordinary kinetic resolution processes, however, the maximum yield of one enantiomer is 50%, and the ee value is affected by the extent of conversion. On the other hand, racemic compounds with a chirally labile stereogenic center may, under certain conditions, be converted to one major stereoisomer, for which the chemical yield may be 100% and the ee independent of conversion. As shown in Scheme 62, asymmetric hydrogenation of 2-substituted 3-oxo carboxylic esters provides the opportunity to produce one stereoisomer among four possible isomers in a diastereoselective and enantioselective manner. To accomplish this ideal second-order stereoselective synthesis, three conditions must be satisfied (1) racemization of the ketonic substrates must be sufficiently fast with respect to hydrogenation, (2) stereochemical control by chiral metal catalysts must be efficient, and (3) the C(2) stereogenic center must clearly differentiate between the syn and anti transition states. Systematic study has revealed that the efficiency of the dynamic kinetic resolution in the BINAP-Ru(H)-catalyzed hydrogenation is markedly influenced by the structures of the substrates and the reaction conditions, including choice of solvents. 

Several reactions of carbonyl compounds that have one or more a hydrogens proceed through the enol form. Reaction of ketones with chlorine, bromine, and iodine result in substitution of halogen for a hydrogen rates are typically first-order in ketone and independent of halogen concentration and even of which halogen is used. Racemization of ketones with asymmetric centers adjacent to the... 

When a mineral or Lewis acid replaces the carboxylic component in the Passerini reaction, the final products are usually a-hydroxyamides. Also in this case, when chiral carbonyl compounds or isocyanides are employed, the asymmetric induction is, with very few exceptions, scarce [18, 19]. For example, the pyridinium trifluoroacetate-mediated reaction of racemic cyclic ketone 14 with t-butyl isocyanide is reported to afford a single isomer [19] (Scheme 1.7). This example, together with those reported in Schemes 1.3 and 1.4, suggests that high induction may be obtained only by using rigid cyclic or polycyclic substrates. 

In one report, the enantiomers of the racemic compound 73, whose structure resembles ketone 2a, were separated by fractional recrystallization of the optically active mandelic acid salts [43]. Although we tried to optically resolve the optically active mandelic acid salts of the racemic ketone ( )-2a, no satisfying results were obtained. After several trials, the (+)- or (-)-di-p-toluoyl tartrate salt prepared from ketone ( )-2a was effectively fractionally recrystallized and finally provided the optically active ketones (+)-2a and (-)-2a [42]. The chiral ketone (-)-2a was converted to compound 73 via compound 72 by thioacetalization followed by desulfurization using Raney nickel... 

The sex pheromone structure, 10-methyl-2-tridecanone, was synthesized using the carboxyl group as the source of the methyl branch (lA) (Figure 6). Undecylenic acid was a-propylated and resolved via amides. The procedure followed allowed us to obtain the alcohols,(R)- and (S)-2-propyl-10-undecenol (>99.6% ee). The corresponding bromide was reduced with lithium triethylborohydride (15) then the double bond was converted to a methyl ketone by a) oxymercuration, b) reduction of the C-Hg bond with sodium borohy-dride, and c) oxidation with dichromate. The male southern corn rootworm responds only to the (R)-configuration no biological activity was noted for the (S)-enantiomer. Therefore, in this instance the racemic compound would be predicted to monitor this species adequately. 

The ability of yeast to reduce cyclic ketones such as cyclopentanone264 or substituted cyclohexanones265 267 is long known197. There are two possibilities if racemic compounds are reduced ... 

The racemic compound has a green, cheesy, ketonic, weak flavor (Chemisis, 1996). 

The corresponding optically active derivative was prepared from talatisamine. Reductive cleavage of the diacetate (71) of talatisamine followed by Jones oxidation gave the ketone (72). Acetalization by standard methods afforded (70). The synthetic racemic compound and the optically active derivative were indistinguishable by i.r., mass, and n.m.r. spectroscopy. Deacetalization of (70) with aqueous methanolic HCl afforded the ketone (72). Reduction of the latter with sodium borohydride proceeded stereospecifically to yield the alcohol (73). Finally, oxidation of (73) with mecuric acetate furnished talatisamine (63). 

Asymmetric nitro-Michael reactions of methyl vinyl ketone (MVK) in the presence of bicyclic guanidine with a benzhydryl group led, disappointedly, to low asymmetric induction (9-12%) [21a] Trials for the reaction of 0 ,p-unsaturated y- or 8-lactones with pyrrolidine in the presence of the conjugate acids of a bicyclic guanidine [50] or the Murphy s guanidine [24a] (R = Me in Scheme 4.7) resulted in the production of racemic compounds. The latter phase transfer catalyst (PTC) catalyses the nitro-Michael addition of chalcone but with limited range (70% yield, 23% ee) [24c]. 

The industrial method is developed based on the preparation of ketimine TM 9.3b followed by reduction. It should be observed that ketone TM 9.3a and imine TM 9.3b are racemic compounds. By non-stereoselective reduction of imine to methylamine, diastereomeric 1,4-dr and, A-trans racemates are formed. 

Appllca.tlons. MCA is used for the resolution of many classes of chiral dmgs. Polar compounds such as amines, amides, imides, esters, and ketones can be resolved (34). A phenyl or a cycloalkyl group near the chiral center seems to improve chiral selectivity. Nonpolar racemates have also been resolved, but charged or dissociating compounds are not retained on MCA. Mobile phases used with MCA columns include ethanol and methanol. 

Also due to the high barrier of inversion, optically active oxaziridines are stable and were prepared repeatedly. To avoid additional centres of asymmetry in the molecule, symmetrical ketones were used as starting materials and converted to oxaziridines by optically active peroxyacids via their ketimines (69CC1086, 69JCS(C)2648). In optically active oxaziridines, made from benzophenone, cyclohexanone and adamantanone, the order of magnitude of the inversion barriers was determined by racemization experiments and was found to be identical with former results of NMR study. Inversion barriers of 128-132 kJ moF were found in the A-isopropyl compounds of the ketones mentioned inversion barriers of the A-t-butyl compounds lie markedly lower (104-110 kJ moF ). Thus, the A-t-butyloxaziridine derived from adamantanone loses half of its chirality within 2.3 days at 20 C (73JCS(P2)1575). 

Compound A can be resolved to given an enantiomerically pure substance, [a]p = —124°. Oxidation gives the pure ketone B, which is optically active, [aJo — —439°. Heating the alcohol A gives partial conversion (an equilibrium is established) to an isomer with [a]p = +22°. Oxidation of this isomer gives the enantiomer of the ketone B. Heating either enantiomer of the. ketone leads to the racemic mixture. Explain the stereochemical relationships between these compounds. 

No information is available as to whether raceniization of the carbonyl compound takes place under the reaction conditions, since the investigation was performed with the racemates. An extensive study of the addition of these reagents to achiral ketones was published in 1980110. 

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 study of optical isomers has shown a similar development. First it was shown that the reduction potentials of several meso and racemic isomers were different (Elving et al., 1965 Feokstistov, 1968 Zavada et al., 1963) and later, studies have been made of the ratio of dljmeso compound isolated from electrolyses which form products capable of showing optical activity. Thus the conformation of the products from the pinacolization of ketones, the reduction of double bonds, the reduction of onium ions and the oxidation of carboxylic acids have been reported by several workers (reviewed by Feokstistov, 1968). Unfortunately, in many of these studies the electrolysis conditions were not controlled and it is therefore too early to draw definite conclusions about the stereochemistry of electrode processes and the possibilities for asymmetric syntheses. 

To confirm this racemization mechanism, Crawford et al. added 5 mol % of the ketone to the reaction mixture and obtained the product in 78% yield in >98% ee. This DKR is therefore catalyzed by a carbonyl compound, and can be compared to those shown in Section 4.6. 

---