Cycloaddition intramolecular, with ketene

The reaction course is shown in Scheme 4. Enyne 12 reacts with 2 to give vinyl carbene complex 17, which is in a state of equilibrium with vinyl ketene complex 21. [2+2] Cycloaddition of the ketene moiety and alkene part in 21 gives cyclob-utanone 22. On the other hand, the vinyl carbene complex 17 reacts with the alkene intramolecularly to produce metalacyclobutane 18. From metalacyclob-utane 18, reductive elimination occurs to give cyclopropane derivative 23. Ret-... 

Snider, B. B. Intramolecular cycloaddition reactions of ketenes and keteniminium salts with alkenes. Chem. Rev. 1988, 88, 793-811. 

The majority of reported solid-phase combinatorial syntheses of the lactam core utilize a [2-i-2] cycloaddition reaction of ketenes with resin-bound imines [33-41]. A further development of the Staudinger reaction was reported by Mata and coworkers using Mukaiyama s reagent [42]. In addition, a stereoselective synthesis of chi-rally pure P-lactams has been performed as a first utilization of polymer-supported oxazolidine aldehydes [43]. Other strategies include an ester enolate-imine condensation [44], an Hg(OCOCF3)2-mediated intramolecular cydization [45], and Miller hydroxamate synthesis [46]. Because of the variability derived from the scaffold synthesis, not many attempts have been made to derivatize the resin-bound lactam template [47]. One of the most detailed descriptions of a versatile (3-lactam synthesis on a resin employed amino acids tethered as esters on Sasrin resin [48]. 

Malonyl chloride enolizes and cyclizes to form a pyranone (325) which combines with dialkyl-cyanamides to yield pyrano[4,3- ][l,3]oxazinediones (328), as well as pyranoazetediones (329). Presumably, the first step is the formation of adducts (326), which undergo rearrangement to the ureas (327) and elimination of hydrogen chloride to yield ketenes. Alternate intramolecular cycloadditions of the ketenes afford the final products (Scheme 93) <85CB4707>. 

The impact of (2 + 2)-cycloaddition and (2 + 2)-cycloreversion reactions of heterocyclic compounds on organic chemistry over the last 10 years is clearly illustrated by several examples. Various members of the important /Hactam antibiotics, penicillin and cephalosporin C, as well as structurally related heterobicyclic compounds have been obtained by (2+ 2)-cycloaddition of heterocycles with ketenes (Section II,D,l).n Intramolecular photochemical (2 + 2)-cycloadditions of 2-pyrones yield 2-oxabicyclo 2.2.01hex-5-en-3-ones, which upon further irradiation afford cyclobutadienes (Section III,D,2).12 Intermolecular (2 + 2)-cyclo-additions of vinylene carbonates with olefins and with acetylenes offer a simple route to cyclobutanes and cyclobutenes, respectively (Sections III,B,3 and 5).13 (2 + 2)-Cycloaddition and (2 + 2)-cycloreversion reactions have contributed substantially to the development of the chemistry... 

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. ... 

As a matter of fact, the above preparative reaction to obtain the framework of bicyclo[ 3.2.0 ]heptenone is already in hand. Indeed, the ring closure step after electrocyclic ring opening of 4-hydroxy-2-cyclobutenone is not limited to fully conjugated systems synthetic variants are realizable with other prox-imally placed ketenophUes. When an allyl group was located at C-4, the ketene underwent an intramolecular [2 + 2] cycloaddition reaction with this double bond to give the bicyclo[3.2.0]heptenone derivatives [111, 112[. 

Georg and coworkers reported a C=C bond cycloaddition with a ketene to provide six-membered enaminones, under mild conditions (Scheme 92) (2010JA15512). From this intramolecular cycloaddition of a ketene created from diazoketone 289, employing a silver-catalyzed Wolff rearrangement, a six-membered enaminones such as 290 was obtained. 

Picryl azide and sulfonyl azides react with ketene AtA -acetals to give switter ionic linear adducts. The intramolecular cycloaddition reaction of azides to ketene S,S-acetals at 130 °C proceeds with loss of nitrogen to produce cyclic imines . ... 

The addition of dichloroketen to cycloalkenes has been used as a first stage in the synthesis of bicyclo[n,2,0]alkane-l,n-diols and a cyclobutanone has been invoked as an intermediate in the addition of diphenylketen to (193). Intramolecular cycloaddition of a keten with an alkene has been shown to be possible in an unconstrained system, but in order to obtain reasonable yields of (195) from (194X solutions had to be very dilute (0.2%). Presumably this is to minimize unwanted oligomerization. 

The intramolecular 2 + 2-cycloaddition reaction of ketenes and ketene-iminiums with alkenes yielded cyclobutanones that could be converted to the tricyclic lactone core of (+)-GR-24, a synthetic analogue of stigolactone plant hormones ... 

Snider has documented a series of investigations of intramolecular cycloaddition reactions of ketenes with olefins. High diastereoselectivity was observed with substrates that incorporate a stereocenter on the tether linking the reaction partners. Treatment of 166 with oxalyl chloride and base, for example, led to the generation of a ketene intermediate that underwent cycloaddition to afford 167 (dr=90 10. Equation 13) [120]. 

The hetero Diels-Alder [4+2] cycloaddition (HDA reaction) is a very efficient methodology to perform pyrimidine-to-pyridine transformations. Normal (NHDA) and Inverse (IHDA) cycloaddition reactions, intramolecular as well as intermolecular, are reported, although the IHDA cycloadditions are more frequently observed. The NHDA reactions require an electron-rich heterocycle, which reacts with an electron-poor dienophile, while in the IHDA cycloadditions a n-electron-deficient heterocycle reacts with electron-rich dienophiles, such as 0,0- and 0,S-ketene acetals, S,S-ketene thioacetals, N,N-ketene acetals, enamines, enol ethers, ynamines, etc. 

Alkoxycarbene complexes with unsaturation in the alkyl side chain rather than the alkoxy chain underwent similar intramolecular photoreactions (Eqs. 10 and 11) [60]. Cyclopropyl carbene complexes underwent a facile vinyl-cyclopropane rearrangement, presumably from the metal-bound ketene intermediate (Eqs. 12 and 13) [61]. A cycloheptatriene carbene complex underwent a related [6+2] cycloaddition (Eq. 14) [62]. 

Scheme 6.8 gives some examples of ketene-alkene cycloadditions. In Entry 1, dimethylketene was generated by pyrolysis of the dimer, 2,2,4,4-tetramethylcyclobutane-l,3-dione and passed into a solution of the alkene maintained at 70° C. Entries 2 and 3 involve generation of chloromethylketene by dehydrohalo-genation of a-chloropropanoyl chloride. Entry 4 involves formation of dichloroketene. Entry 5 is an intramolecular addition, with the ketene being generated from a 2-pyridyl ester. Entries 6, 7, and 8 are other examples of intramolecular ketene additions. 

Scheme 29 describes a plausible mechanism for the formation of the products which fit the observed coulometric (n 0.45 F/mol) and preparative results. The intramolecular cyclization process involves a dimerization between a radical cation 52a and the ketene imine 52 to form the intermediate radical cation 52b which then cyclizes to the radical 52c which can abstract a hydrogen atom leading to 54 or can be further oxidized and transformed through a cyclization and deprotonation reaction to 53 which involves 1 F/mol. However, it seems that the [2 -1- 3]-cycloaddition between the parent compound 52 and the cation 52d giving rise to 55 is the fastest reaction as compared with the intramolecular cyclization of 52d to 53. This can also explain the low consumption of electricity. 

Density functional theory calculations (B3LYP/6-31G level) have provided an explanation for the stereodivergent outcome of the Staudinger reaction between acyl chlorides and imines to form 2-azetidinones (/3-lactams). When ketene is formed prior to cycloaddition, preferential or exclusive formation of ct5-j6-lactam (50) is predicted. If, however, the imine reacts directly with the acid chloride, the step that determines the stereochemical outcome is an intramolecular 5n2 displacement, and preferential or exclusive formation of trans isomer (51) is predicted. These predictions agree well with the experimental evidence regarding the stereochemical outcome for various reactants and reaction conditions. 

The Cj - and 54-symmetric tetraesters of tricyclo[3.3.0.0 ]octane (430 and 431) have been prepared by oxidation of diene 429 To access the parent hydrocarbon (435), acid chloride 432 was transformed to the derived ketene which undergoes intramolecular [2+2] cycloaddition The resulting cyclobutanone (433) serves as precursor to perester 434 whose thermal decomposition proceeds with chain transfer in competition with cleavage The unique arrangement of the carbon atoms in 435 is such that the smallest rings are all five-membered. The highly symmetric structure may be viewed as a constrained cisoid bicyclo[3.3.0]octane (as well as the symbol of NATO). 

In addition to the alkylations discussed above, some special reactions have been reported that enable the solid-phase synthesis of cycloalkanes. These include the intramolecular ene reaction and the cyclopropanation of alkenes (Figure 5.5 see also [44]). Cyclobutanes have been prepared by the reaction of polystyrene-bound carbanions with epichlorohydrin, and by [2 + 2] cycloadditions of ketenes to resin-bound alkenes. 

Intramolecular [2 + 2]cycloadditions benzofurans. On dehydrochlorination with triethylamine in refluxing C6H6, these acid chlorides are converted into (o-acylphenoxy)ketenes, which undergo a [2 + 2]cycloaddition reaction to form p-lactones, which are converted to benzofurans by spontaneous decarboxylation in 53-82% yield.1... 

Ab initio calculations indicate that in the gas phase the reaction of ketene inline and formaldehyde is concerted but asynchronous whereas in dichloromethane it is a two-step zwitterionic reaction.38 The 2 + 2-cycloadditions of keteniminium triflates with imines yields 2-azetidiniminium salts with cis stereoselectivity.39 The intramolecular 2 + 2-cycloaddition of ketenimines with imines (24) provides a novel synthesis of azeto[2,l-Z>]quinazolines (25) (Scheme 9).40... 

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