Cyclobutanones from -cycloadditions

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. 

The use of alkenes with chiral auxiliary groups leads to chiral cyclobutanones 4. Reaction yields of 50 67% and diastereomeric excesses of 86-97% were obtained for the 3-amidocy-clobutanones which were obtained from cycloaddition of the chromium carbene complexes with chiral ene carbamates (see also Section 1.3.4.3.3.).11... 

Cyclobutanones are obtained from cycloaddition of ketenes to enamines (see Section IV.A and Chapter 18)266. Such cycloadditions may be concerted or step-wise depending upon the amine moiety and the experimental conditions. Vinylketenes are especially interesting since these may undergo [2 + 2] or [4 + 2] cycloadditions to give after oxidation a vinylcyclobutanone or a cyclohexenone, respectively267,268. 

In contrast with the photochemical cycloaddition reaction of two alkenes, the [2+2] cycloaddition of a ketene and an alkene occurs under thermal conditions. The ketene is formed typically from an acid chloride and a mild base such as EtsN, or from an a-halo-acid chloride and zinc. Cycloaddition with an alkene occurs stereospecifically, such that the geometry of the alkene is maintained in the cyclobutanone product. The regioselectivity is governed by the polarization of the alkene, with the more electron-rich end of the alkene forming a bond to the electron-deficient central carbon atom of the ketene. Thus, the product from cycloaddition of dimethylketene with the enol ether Z-171 is the cyclobutanone m-172, whereas with -171, the isomer trans-lll is formed (3.116). ... 

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. ... 

An improved experimental procedure for the synthesis of cyclobutanones via cycloaddition of dichloroketen gives good yields, even with hindered olefins. Hassner and Dillon have applied their method for in situ generation of dichloroketen to the conversion of acetylenes [e.g. (35)] into dichlorocyclo-butenones [e.g. (36)]. The 2-exomethylenecyclobutanone (39) is readily prepared from (38), the adduct of the 2-thiophenylketen (37) with cyclo-pentadiene. ... 

An efficient one-pot synthesis of cyclobutanones from chiral enol ethers, which uses Zn/Cu in diethyl ether to achieve the dechlorination, affords the cyclobutanones in >90 % yield and 100 % stereoselectivity. The [2-1-2] cycloaddition of dichloroketene with chiral enol ethers is the key step in the synthesis of natural pyrrolizidines. ... 

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. 

Enantioselective [2 + 2 cycloaddition.2 The chiral allylic ether (1), prepared from (lS,2R)-( + )-2-phenylcyclohexanol, undergoes enantioselective cycloaddition with dichloroketene to furnish, after one crystallization, optically pure (-)-2. This cyclobutanone after ring expansion and exposure to chromium(II) perchlorate gives... 

Spirocyclic 2-alkylidenecyclobutanones can be prepared from vinylidenecycloalkane additions with dimethylketene (see Tabic 1). Alternatively, cycloaddition of cycloalkylidenemethanone to allenes permits synthesis of spirocyclic cyclobutanones. This latter route is more attractive because of the greater availability of simple allcnes as compared with the alkylidenecycloalka-nes. The in situ generation of cyclohexylidenemethanone in the presence of excess tetramethyl-allcnc produced the spirocyclic ketone 9 in reasonable yield.5... 

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 first recorded cyclopropyl acyl silane (69) was generated by vapour phase pyrolysis of a pyrazoline derived from a,/)-unsaturated acyl silane by 1,3-dipolar cycloaddition of diazomethane (vide supra, Section DTE)141. Exposure of 69 to titanium tetrachloride induced ring expansion to give the cyclobutanone in 75% yield (Scheme 113). 

Others are not so obvious. Cyclobutanone 22 might come from diphenylketene and the diene 21 (disconnection 22a) or from ketene itself and the diene 23 (disconnection 22b). No doubt both dienes could be made but the regioselectivity of both cycloadditions looks in doubt. 

P Volume 1,1991,283 pp. 109.50/ 69.50 ISBN 1-55938-180-9 CONTENTS Introduction to the Series An Editor s Foreword, Albert Padwa. Preface, Brian Halton. Strain in Organic Chemistry A Perspective, Brian Halton. Gem-Dihalocyclopropanes in Chemical Synthesis, Martin G. Banwell and Monica E. Re-um. 1-Halo- and 1, 2-Dihalocyclopropenes Useful Synthetic Intermediates, Mark S. Baird. Cyciization and Cycloaddition Reactions of Cyclopropenes, Albert Padwa and Glen E. Fryx-ell. New Synthetic Pathways From Cyclobutanones, Edward Lee-Ruff. Cyclic Alkynes, Enynes and Dienynes A Synthetic Challenge, Herbert Meier. Index. 

The most general methods for preparing seven- or eight-membered rings from enamines are by ring expansion of the cyclobutene, cyclobutanone or chlorocyclopro-pane adducts formed by cycloaddition of acetylene carboxylates, ketenes or chlor-ocarbenes, respectively, to enamines of cyclopentanone or cyclohexanone. These are two-carbon or one-carbon ring expansions. Three-carbon ring expansions can also be carried out by cycloaddition of activated cyclopropenes or cyclopropenones. 

Ketene Cycloadditions. As we saw earlier [see (Section 6.3.2.8) pages 211 and 212], ketenes undergo cycloadditions to double bonds 6.118 (repeated below) to give cyclobutanones. In practice, the reaction is faster and cleaner when the ketene has electron-withdrawing groups on it, as in dichloroketene, and when the alkene is relatively electron-rich, as in cyclopentadiene. The product from this pair of reagents is the cyclobutanone 6.249. 

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). 

Cyeloaddition to silyl enol ethers. As expected, dichloroketene, generated from trichloroacetyl chloride and activated zinc, reacts with silyl enol ethers to form 3-silyloxy-2,2-dichlorocyclobutanones, usually in good yield. Cycloaddition does not obtain with dichloroketene generated from dichloroacetyl chloride and triethylamine. In some cases only acyclic products are formed, but these may arise by ring opening of intermediate cyclobutanones. ... 

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