Cyclohexanone, 4-substituted selectivity

In the acylation of enamines derived from 3-substituted cyclohexanones, 6-acylated products were favored over 2-acylated products (398), thus revealing another selective enamine reaction sequence. The use of oxalyl bromide for the acylation of enamines has also been described (399). 

Recendy, Darzens reaction was investigated for its synthetic applicability to the condensation of substituted cyclohexanes and optically active a-chloroesters (derived from (-)-phenylmenthol). In this report, it was found that reaction between chloroester 44 and cyclohexanone 43 provided an 84% yield with 78 22 selectivity for the axial glycidic ester 45 over equatorial glycidic ester 46 both having the R configuration at the epoxide stereocenter. 

Using 3-substituted cyclohexanones the /rans-diastereoselective synthesis of decalones and octahydro-1 //-indenones may be achieved 164 169. This method has been applied, for instance, in the synthesis of 19-norsteroids. In a related Michael addition the lithium enolate of (R)-5-trimethylsilyl-2-cyclohexenone reacts with methyl 2-propenoate selectively tram to the trimethylsilyl substituent. Subsequent intramolecular ring closure provides a single enantiomer of the bicyclo[2.2.2]octane170 (see also Section 1.5.2.4.4.). 

The Michael additions of chiral cycloalkanone imines or enamines, derived from (FV l-l-phcnyl-ethanamine or (5)-2-(methoxymethyl)pyrrolidine, are highly diastereofacially selective reactions providing excellent routes to 2-substituted cycloalkanones. This is illustrated by the addition of the enamine of (S)-2-(methoxymethyl)pyrrolidine and cyclohexanone to 2-(aryl-methylene)-l,3-propanedioates to give, after hydrolysis, the (2 5,a.S )-oxodicstcrs in 35-76% yield with d.r. (2 S,aS)/(2 S,a/ ) 94 6- > 97 3 and 80-95% ee214. 

As the WT CHMO was known to react (S) selectively with simple four-substituted cyclohexanone derivatives [84—87], it was logical to test mutant 1-K2-F5 as a catalyst in the BV reaction of other ketones. For example, when 4-methoxycyclohexanone (38) was subjected to the BV reaction catalyzed by mutant 1-K2-F5, almost complete enantioselectivity was observed in favor of the (S)-lactone (39) (98.5% ee), in contrast to the WT, which is considerably less selective (78% ee) (see Scheme 2.11) [89]. 

Such enantioselective deprotonations depend upon kinetic selection between prochiral or enantiomeric hydrogens and the chiral base, resulting from differences in diastere-omeric TSs.27 For example, transition structure E has been proposed for deprotonation of 4-substituted cyclohexanones by base D.28 This structure includes a chloride generated from trimethylsilyl chloride. 

Owing to the predominance of the less-substituted enamine, alkylations occur primarily at the less-substituted a-carbon. Synthetic advantage can be taken of this selectivity to prepare 2,6-disubstituted cyclohexanones. The iminium ions resulting from C-alkylation are hydrolyzed in the workup procedure. 

As observed in runs 3-5 (Table 6) the reaction shows poor diastereofa-cial selectivity. For example, the reaction with 4-substituted cyclohexanone provides a mixture of an equatorial approach product 52eq and an axial approach product 52ax in a ration of ca. 6 1, irrespective of the steric size of the substituents... 

When a nucleophilic reagent, Nu X+ (or Nu—X), is reacted with a ketone, com-plexation of oxygen by X+ may precede attack at carbon. Geometric changes associated with such complexation have been calculated for a series of 4-substituted cyclohexanones. The results allow the facial selectivity of the subsequent nucleophilic attack to be predicted, and without the need to calculate the transition-state geometry. 

Ab initio calculations at the HF/6-31G level have been used to explore energy changes, structural variation, and electron density shifts during jr-face selective addition of substituted acetylide ions to cyclohexanone and cyclohexanethione. Charge polarization of the jr-bond on approach of the nucleophile is such that the carbonyl carbon becomes considerably electron deficient for most of the reaction path (and may... 

This process (also known as the Ferrier II Reaction ) has proved to be of considerable value for the efficient, one-step conversion of 5,6-unsaturated hexopyranose derivatives into functionalized cyclohexanones useful for the preparation of such enantiomerically pure compounds as inositols and their amino, deoxy, unsaturated and selectively O-substituted derivatives, notably phosphate esters. In addition, the products of the carbocyclization have been incorporated into many complex compounds of interest in biological and medicinal chemistry. ... 

Recently, Corma et al. have patented a process of oxidizing cycloalkane with molecular oxygen to produce cycloalkanol and/or cycloalkanone in the presence of hydrotalcite-intercalated heteropoly anion [Co MnCo (H20)039] (M = W or Mo), which comprised one cobalt as a central atom and another as a substitute of a W=0 fragment in the Keggin structure [98]. At 130 °C and 0.5 MPa, 64 and 24% selectivity to cyclohexanone and cyclohexanol, respectively, was achieved at cyclohexane conversion about 5%. This catalytic system could be of practical importance provided a true heterogeneous nature of catalysis and good catalyst recyclability had been proved. Unfortunately, this information was lacking in [98]. 

The final synthetic analogues we consider are the trioxolanes prepared by Vennerstrom and coworkers. These are prepared by a very efficient co-ozonolysis procedure from oxime 90 and a carbonyl compound 91 (Scheme 37A). This provides the 1,2,4-trioxolane in yields of greater than 50%. Further studies on 4-substituted cyclohexanones (e.g. 92) revealed that this reaction proceeds with very good cisitrans selectivity to produce the ester 93, which was derivatized to produce a clinical candidate OZ 277 (6) as shown. The chemistry for the synthesis of this compound has been scaled up beyond 30 kg (Scheme 37B). 

Magnesium amides have also found good utility in enantioselective deprotonation processes. A range of chiral amines has been prepared by Henderson and coworkers and it was found after conversion to their Mg-bisamide derivatives that it react with 4- and 2,6-substituted cyclohexanones with good to excellent selectivities (see Section m). Structures of some chiral magnesium amides are given in Chart 1. 

These alkoxytitanium homoenolates show high propensity for equatorial attack in their ir reactions with substituted cyclohexanones (Table 6). The basic trend of their chemical behavior is similar to that of simple titanium alkyls [35]. Chemo-selectivity of the reagent 19 is also noteworthy. The alkoxytitanium homoenolate reacts preferentially with an aldehyde even in the presence of a ketone Eq. (32). A notable difference of rate between the reaction with cyclohexanone and that with 2-methylcyclohexanone was also observed, the latter being far less reactive toward the homoenolate. 

In 1987, the successful startup of a new process was announced for the production of 10,000 tons/year of catechol and hydroquinone by the selective oxidation of phenol with H202 catalyzed by TS-1 at the Enichem plant in Ravenna, Italy (Notari, 1988). Soon thereafter, it was disclosed that another new process for the production of cyclohexanone oxime from cyclohexanone, H202, and NH3 with TS-1 as the catalyst was being developed (Roffia et al., 1990).The fact that a material with unusual catalytic properties had been obtained was then finally recognized, and the interest in titanium-containing catalysts spread rapidly in the scientific community, especially in industrial research laboratories. In the meantime, the synthesis method was studied and described in more detail and when all the necessary precautions were taken, TS-1 was reproduced in other laboratories, as were the highly selective catalytic reactions. The subsequent work confirmed that Ti v can assume the tetrahedral coordination necessary for isomorphous substitution of SiIV and added valuable information about the structure, properties and catalytic performance of the material. New reactions catalyzed by TS-1 have been discovered, and new synthetic methods... 

Homolytic liquid-phase processes are generally well suited to the synthesis of carboxylic acids, viz. acetic, benzoic or terephthalic acids which are resistant to further oxidation. These processes operate at high temperature (150-250°C) and generally use soluble cobalt or manganese salts as the main catalyst components. High conversions and selectivities are usually obtained with methyl-substituted aromatic hydrocarbons such as toluene and xylenes.95,96 The cobalt-catalyzed oxidation of cyclohexane by air to a cyclohexanol-cyclohexanone mixture is a very important industrial process since these products are intermediates in the manufacture of adipic acid (for nylon 6,6) and caprolactam (nylon 6). However, the conversion is limited to ca. 10% in order to prevent consecutive oxidations, with roughly 70% selectivity.97... 

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