Ketenes, cyclobutanone from

Staudinger observed that the cycloaddition of ketenes with 1,3-dienes afforded cyclobutanones from a formal [2+2] cycloaddition [52] prior to the discovery of the Diels-Alder reaction. The 2+2 cycloadditions were classified into the symmetry-allowed 2+2 cycloaddition reactions [6, 7], It was quite momentous when Machiguchi and Yamabe reported that [4+2] cycloadducts are initial products in the reactions of diphenylketene with cyclic dienes such as cyclopentadiene (Scheme 11) [53, 54], The cyclobutanones arise by a [3, 3]-sigmatropic (Claisen) rearrangement of the initial products. 

Table 13 a. Cyclobutanones from ketene-diazomethane reactions 96>... 

Irradiation of alkoxycarbene complexes in the presence of aUcenes and carbon monoxide produces cyclobutanones. A variety of inter- and intramolecular [2 + 2]cycloadditions have been reported. The regioselectivity is comparable with those obtained in reactions of ketenes generated from carboxylic acid derivatives. Cyclobutanones can be obtained with a high degree of diastereoselectivity upon reaction of alkoxy carbenes with chiral A-vinyloxazolidinones. For example, photolysis of (19) in the presence of (20) gives cyclobutanone (21) (Scheme 31). In addition to aUcoxycarbenes, carbenes having a thioether or pyrrole substituent can also be employed. Related intramolecular cycloadditions of y,5-unsaturated chromimn carbenes afford bicyclo[2.1. IJhexanones (Scheme 32). 

DicWoroketene is particularly reactive, and reductive dechlorination of the product with zinc and acetic acid allows access to the cyclobutanone from formal addition of ketene itself. Thus, cycloaddition of dichloroketene with cyclopentadiene, followed by dechlorination and Baeyer-Villiger oxidation gave the lactone 173, a usehil precursor to various oxygenated cyclopentane products (3.117). Intramolecular cycloaddition reactions of ketenes can allow the formation of bicyclic and polycyclic products using otherwise unstable ketene intermediates. ... 

Fused and spirocyclic ring systems are present in many natural products and drug molecules. An approach to these systems was developed by [2 + 2] cycloaddition between 2,3-dihydrofurans and ketenes generated from ali-cyclic acid chlorides (14TL7240).This approach allows the construction of complex-fused, spirocyclic cyclobutanone frameworks in simple operations, even on a large scale (20 mol). 

Figure 1 - Cyclobutanones from olefins and ketenes or keteniminiums...

Very high stereoselectivity caused by the chiral tether is observed when the ketene derived from FVP of diazo ester 428 followed by a Wolff rearrangement adds intramolecularly to give dioxepane-containing cyclobutanone 429 (Scheme 91 2003TL3115). 

This method for the preparation of cyclobutanone via oxaspiropentane is an adaptation of that described by Salaiin and Conia. The previously known large-scale preparations of cyclobutanone consist of the reaction of the hazardous diazomethane with ketene, the oxidative degradation or the ozonization in presence of pjrridine of methylenecyclobutane prepared from pentaerythritol, or the recently reported dithiane method of Corey and Seebach, which has the disadvantage of producing an aqueous solution of the highly water-soluble cyclobutanone. A procedure involving the solvolytic cyclization of 3-butyn-l-yl trifluoro-methanesulfonate is described in Org. Syn., 54, 84 (1974). 

The photochemistry of cyclobutanones differs from that of less strained larger cycloalkanones. Fragmentation to ethylene and ketene (derivatives), decarbonylation and rearrangement to oxacarbenes predominate here. The oxacarbene formation, which occurs with retention of the configuration of the... 

Ketenes are especially reactive in [2 + 2] cycloadditions and an important reason is that they offer a low degree of steric interaction in the TS. Another reason is the electrophilic character of the ketene LUMO. As discussed in Section 10.4 of Part A, there is a large net charge transfer from the alkene to the ketene, with bond formation at the ketene sp carbon mnning ahead of that at the sp2 carbon. The stereoselectivity of ketene cycloadditions is the result of steric effects in the TS. Minimization of interaction between the substituents R and R leads to a cyclobutanone in which these substituents are cis, which is the stereochemistry usually observed in these reactions. 

The best large-scale preparation of cyclobutanone is the reaction of diazomethane with ketene.2 It requires a ketene generator and implies handling of large quantities of the potentially hazardous diazo compound. A more frequently used method for the preparation of cyclobutanone starts from pentaerythritol, the final step being the oxidative degradation of methylenecyclobutane,3,4 which can also be prepared from other precursors.5 A general survey of all methods used to obtain cyclobutanone has been published.6,7... 

Steroids represent rigid chiral systems which are convenient substrates for mechanistic studies of geometric details. Early studies on the difacial selectivity of ketene to steroidal alkene cycloadditions led to the preparation of optically pure cyclobutanones. The addition of dichloroketene to 2- or 3-methyl-5a-cholcst-2-ene (1) generates the cyclobutanones 2 and 3 with regio- and stereoselectivity. The cycloadditions proceed to give the adducts resulting from ketene approach to the a-face.4... 

Ketene itself and simple alkylketenes are inert towards nonactivated alkenes. F or the preparation of cyclobutanones formally derived from ketene or an alkylketene and nonactivated alkenes, the more reactive dichloroketene or alkylchloroketenes can be used. The corresponding a,a-dichloro- or oc-chlorocyclobutanones can readily be dechlorinated by treatment with zinc in acetic acid, or tributyltin hydride in near quantitative yields. F or example cycloaddition of substituted cyclohexene to dichloroketene gave dichlorocyclobutanone 1 which was dechlorinated to 2 with zinc.13,18 Likewise cycloaddition of cycloalkcnes to chloro(methyl)ketene gave 3 which was dechlorinated to 4.14... 

The regiochemistry of ketene iminium salt cycloadditions can also differ from ketene cycloadditions. Whereas reaction of styrene with a series of ketene iminium salts gave 3-phenyI-cyclobutanones7 (60-70% yield) similar to the regiochemistry of ketene cycloadditions, reaction with a series of acrylates and a,/J-unsaturated ketones gave cyclobutanones 5 with regiochemistry opposite to what would be expected from electrostatic considerations of ketene cycloadditions.s... 

The use of a chiral auxiliary group on the ketene iminium salt permits the enantioselective synthesis of cyclobutanones. These salts offer a wider scope for asymmetric induction than ketenes since there are two substituents on the nitrogen of these salts which are not present on the oxygen of ketenes. Use of a chiral amide 8 or a geminal ehloroenaminc 10 permits the enantioselective synthesis of cyclobutanones 9 and 11. respectively, with enantiomeric excesses ranging from 55-97%. ... 

Derivatives other than cyclobutanones can be obtained from the ketene iminium salt by way of reduction with hydride ion of the cyclobutaneiminium salt to give cyclobutylamines. Although some stereoselectivity is observed, mixtures of stereoisomers are usually obtained, e.g. formation of 12.13... 

Cyclobutanone has been prepared by (1) reaction of diazomethane with ketene,4 (2) treatment of methylenecyclobutane with performic acid, followed by cleavage of the resulting glycol with lead tetraacetate,5 (3) ozonolysis of methylenecyclobutane, (4) epoxidalion of methylene-cyclopropane followed by acid-catalyzed ring expansion,7 and (5) oxidative cleavage of cyclobutane trimethylene thioketal, which in turn is prepared from 2-(cu-chloropropyl)-l,3-dithiane.8... 

C(R)=NR group with a nitrilium salt RCssNR .222 The acylation of the enamine can take place by the same mechanism as alkylation, but another mechanism is also possible, if the acyl halide has an a hydrogen and if a tertiary amine is present, as it often is (it is added to neutralize the HX given off). In this mechanism, the acyl halide is dehydrohalogenated by the tertiary amine, producing a ketene (7-14) which adds to the enamine to give a cyclobutanone (5-49). This compound can be cleaved in the solution to form the same acylated imine salt (27) that would form by the more direct mechanism, or it can be isolated (in the case of enamines derived from aldehydes), or it may cleave in other ways.223... 

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