Cyclohexanone ring rearrangement

The second stage of the synthesis of all-czs-fenestrindane 9 begins by contraction of the cyclohexanone ring of 227 by two-fold bromination followed by Favorskii rearrangement [93] (Scheme 46). Subsequent decarboxylation of the acrylic acid furnishes the all-czs-tribenzo[5.5.5.5]fenestrene 233 in moderate overall yield. This compound as well as the precursors 225 and 227 have been converted into a number of related fenestranes including all-ds-tribenzo-... 

Good examples of Type I dyotropic rearrangements involving C—C bond as the stationary surface are provided by the interconversion of vicinal dibromides in cyclohexane and cyclohexanone ring systems (Scheme 6.7). 

Caprolactam [105-60-2] (2-oxohexamethyleiiiiriiQe, liexaliydro-2J -a2epin-2-one) is one of the most widely used chemical intermediates. However, almost all of the aimual production of 3.0 x 10 t is consumed as the monomer for nylon-6 fibers and plastics (see Fibers survey Polyamides, plastics). Cyclohexanone, which is the most common organic precursor of caprolactam, is made from benzene by either phenol hydrogenation or cyclohexane oxidation (see Cyclohexanoland cyclohexanone). Reaction with ammonia-derived hydroxjlamine forms cyclohexanone oxime, which undergoes molecular rearrangement to the seven-membered ring S-caprolactam. 

The reaction of methyl propiolate (82) with acyclic enamines produces acyclic dienamines (100), as was the case with dimethyl acetylenedicarboxylate, and the treatment of the pyrrolidine enamines of cycloheptanone, cyclooctanone, cycloundecanone, and cyclododecanone with methyl propiolate results in ring enlargement products (100,101). When the enamines of cyclohexanone are allowed to react with methyl propiolate, rather anomalous products are formed (100). The pyrrolidine enamine of cyclopentanone forms stable 1,2-cycloaddition adduct 83 with methyl propiolate (82). Adduct 83 rearranges to the simple alkylation product 84 upon standing at room temperature, and heating 83 to about 90° causes ring expansion to 85 (97,100). 

With cyclic a-halo ketones, e.g. 2-chloro cyclohexanone 6, the Favorskii rearrangement leads to a ring contraction by one carbon atom. This type of reaction has for example found application as a key step in the synthesis of cubane by Eaton and Cole for the construction of the cubic carbon skeleton ... 

With cyclic a-diazo ketones, e.g. a-diazo cyclohexanone 9, the rearrangement results in a ring contraction by one carbon " ... 

Fusion of an all cyclic ring onto the piperidine so as to form a perhydroisoquinoline is apparently consistent with analgesic activity. Synthesis of this agent, ciprefadol (68), starts with the Michael addition of the anion from cyclohexanone 56 onto acrylonitrile (57). Saponification of the nitrile to the corresponding acid ( ) followed by Curtius rearrangement leads to isocyanate Acid... 

The trimethylsilyl ethers 212 of four-membered 1-alkenyl-1-cyclobutanols rearrange to the ring-expanded 0-mercuriocyclopentanones 213. These can be converted into the a-methylenecyclopentanones 214 through elimination or further expanded by one-carbon atom into cyclohexanones 215 via the Bu3SnH-mediated free radical chain reactions [116]. A similar radical intermediate is suggested to be involved in the ring expansion of a-bromomethyl-fi-keto esters [117]. (Scheme 84)... 

Aliphatic c a -dibromo ketones, such as 2,4-dibromopentan-3-one (262), react with primary amines RNH2 (R = Me, Et, Pr, /-Pr or t-Bu) to give mixtures of imines 263 and lesser amounts of diimines 264. l,3-Dibromo-l-phenylpropan-2-one yields only the amide 265, the product of a Favorskii rearrangement. The nature of the products from aliphatic amines and cyclic a,a -dibromo ketones depends on ring size the cyclohexanone derivative 266 gave Favorskii amides 267 (R = Pr, /-Pr or t-Bu), while trans-2,5-dibromocyclopentanone afforded the enamines 268 (R = /-Pr or t-Bu) (equation 95)296. 

Oxidative ring cleavage of cyclohexanones is achieved in ethanol at a platinum anode. Cleavage of the carbon-carbonyl bond occurs and the carbonyl centee is trapped as the carboxylic acid. The radical centre formed after bond cleavage is oxidised to the carbocation. This rearranges to the most stable centre and is then trapped by the carboxyl group to form a lactone [4, 5], An identical process is... 

Triethyloxonium tetrafluoroborate in dichloromethane was used to convert the trimethylsilyl ether of a dioxopyrrolidine derived vinylcyclobutanol into a cyclohexanone 6 or a cyclo-hexenone 7.23 Rearrangement to five-membered rings competes with this ring enlargement and becomes the main reaction course on treatment with hydrochloric acid or boron trifluoride.23... 

Trimethylsilyl-protected 1-isopropenylcyclobutanols were rearranged to cyclohexanones via a two-step reaction sequence.114 The vinylcyclobutanes 1 were first treated with mercury(II) trifluoroacetate. The crude products were then converted into chlorides (which can be isolated) and finally reduced with tributyltin hydride to give 2. Sometimes small amounts of five-mem-bered ring compounds, which are intermediates of this two-step ring enlargement, are formed as side products. 

The formation of 5-hexenal (reaction 18) is believed to be an intramolecular rearrangement since the addition of oxygen does not cause its suppression. At least in a methyl substituted cyclohexanone the analogous process has been shown to occur by the transfer of a hydrogen atom from the beta position to the carbonyl group before the fission of the six-membered carbocyclic ring (29) as only one of the two possible isomeric heptenals is formed. 

Another useful route to cyclopentanes is the ring contraction of 2-bromo-cyclohexanones by a Favorskii rearrangement to give cyclopentanecarboxylic acids. If a,fi-dibromoketones are used, ring opening of the intermediate cyclopropanone leads selectively to /J,y-unsaturated carboxylic acids (S.A. Achmad, 1963, 1965 J. Wolinsky, 1965). 

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