Diazoketones decomposition

Cyclohexanediones in heterocyclic synthesis 74KGS1011. a-Diazoimines in synthesis of heterocycles 81BSB615. a-Diazoketone decomposition, heterocycle formation by 81T2407. Dichloromaleimide, synthesis of heterocycles from 81ZC19. 

A third synthesis of thujopsene (120, R = Me) has been recorded, in which the diazoketone decomposition of (121) once again proved to be the crucial step in the synthetic route. Photosensitised oxygenation of thujopsene and thujopsenol... 

Diazoketone decomposition. Cyclopropanation of a proximal electron-rich double bond, for example, of an indole nucleus, is inescapable once carbenoid generation is initiated. By placing a moderately nucleophilic chain that is stericaUy interactable with the emerging cyclopropane, skeletal reorganization is feasible. Such transformation based on careful design is conducive to synthetic purposes. ... 

The photolytic decomposition of a-diazoketones, accompanied by rearrangement to ketene (photolytic Wolff rearrangement), has been used successfully in the preparation of A-nor- and C-norsteroids. The method is reviewed in chapter 15 by R. M. Scribner. ... 

Diazocarbonyl compounds are especially useful in these reactions because of their ease of formation, relative stability, and controlled reactivity in catalytic reactions [ 1,11 ]. As outlined in Scheme 1, a wide diversity of methodologies are available for this synthesis, with access dependent on the nature of Z. Vinyl- and aryldiazoacetates are accessible by other pathways [2]. The order of reactivity toward diazo decomposition has diazoketones and diazoacetates much more reactive than diazoacetoacetates or diazomalonates. However, the influence of electronic effects on reactivities is more pronounced with phenyl- and vinyl-diazoacetates than with diazoacetoacetates and, especially, diazoacetates [12]. 

The role of Lewis acids in the formation of oxazoles from diazocarbonyl compounds and nitriles has primarily been studied independently by two groups. Doyle et al. first reported the use of aluminium(III) chloride as a catalyst for the decomposition of diazoketones.<78TL2247> In a more detailed study, a range of Lewis acids was screened for catalytic activity, using diazoacetophenone la and acetonitrile as the test reaction.<80JOC3657> Of the catalysts employed, boron trifluoride etherate was found to be the catalyst of choice, due to the low yield of the 1-halogenated side-product 17 (X = Cl or F) compared to 2-methyI-5-phenyloxazole 18. Unfortunately, it was found that in the case of boron trifluoride etherate, the nitrile had to be used in a ten-fold excess, however the use of antimony(V) fluoride allowed the use of the nitrile in only a three fold excess (Table 1). 

Whereas metal-catalyzed decomposition of simple diazoketones in the presence of ketene acetals yields dihydrofurans 121,124,134), cyclopropanes usually result from reaction with enol ethers, enol acetates and silyl enol ethers, just as with unactivated alkenes 13). l-Acyl-2-alkoxycyclopropanes were thus obtained by copper-catalyzed reactions between diazoacetone and enol ethers 79 105,135), enol acetates 79,135 and... 

Considering the above-mentioned facts, according to which simple diazoketones yield dihydrofurans with ketene acetals but cyclopropanes with enol ethers, one exports an interlink between these clear-cut alternatives to exist, i.e. substrates from which both cyclopropanes and dihydrofurans result. In fact, providing an enol ether with a cation-stabilizing substituent in the a-position creates such a situation The Rh2(OAc)4-catalyzed decomposition of -diazoacetophenone in the presence of ethyl vinyl ether produces mainly cyclopropane 82 (R=H), but a small amount of dihydro-... 

Nickel(II) acetylaeetonate has been recommended as a very efficient homogeneous catalyst for intramolecular cyclopropanations for unsaturated diazoketones 171 The yields were better than with activated CuO as catalyst (see Table 10 for examples). The authors of this study seem to combine routinely thermocatalytic with photochemical (tungsten lamp) decomposition of the diazoketones. The benefit of this procedure (higher yields, shorter reaction times) has been communicated in the CuO case, but not for the Ni(acac)2-eatalyzed reaction. 

The distinction between Pd and Rh catalysts was also verified for diazoketone 190. In this case, the carbonyl ylide was trapped by intramolecular [3+2] cycloaddition to the C=C bond195. Decomposition of bis-diazoketone 191 in the presence of CuCl P(OEt)3 or Rh2(OAc)4 led to the pentacyclic ketone 192 most remarkably, one diazoketone unit reacted by cyclopropanation, the second one by carbonyl ylide formation 194). With [(r 3-C3H5)PdCl]2, a non-separable mixture containing mostly polymers was obtained, although bis-diazoketones with one or two allyl side chains instead of the butenyl groups underwent successful twofold cyclopropanation 196). 

Rh2(OAc)4-catalyzed decomposition of m-methoxy-substituted diazoketones 244 furnishes 6-methoxy-2-tetralones rather than the expected bicyclo[5.3.0]decatrienones. This demonstrates that the direction of ring opening in the norcaradienone intermediate 245 may well be influenced by the nature and position of a substituent. 

Intramolecular carbonyl ylide formation was also invoked to explain the formation of the AH-1,3-oxazin-5(6//)-ones 291a, b upon copper-catalyzed decomposition of diazoketones 290a, b 270 >. Oxapenam 292, obtained from 290b as a minor product, originates from an intermediary attack of the carbenic carbon at the sulfur atom. In fact, this pathway is followed exclusively if the C(Me, COOMe) group in 290b is replaced by a CH2 function (see Sect. 7.2). 

The reaction, formally speaking a [3 + 2] cycloaddition between the aldehyde and a ketocarbene, resembles the dihydrofuran formation from 57 a or similar a-diazoketones and alkenes (see Sect. 2.3.1). For that reaction type, 2-diazo-l,3-dicarbonyl compounds and ethyl diazopyruvate 56 were found to be suited equally well. This similarity pertains also to the reactivity towards carbonyl functions 1,3-dioxole-4-carboxylates are also obtained by copper chelate catalyzed decomposition of 56 in the presence of aliphatic and aromatic aldehydes as well as enolizable ketones 276). No such products were reported for the catalyzed decomposition of ethyl diazoacetate in the presence of the same ketones 271,272). The reasons for the different reactivity of ethoxycarbonylcarbene and a-ketocarbenes (or the respective metal carbenes) have only been speculated upon so far 276). 

Intramolecular C/H insertion by copper-catalyzed decomposition of a-diazoketones provides a convenient cyclization procedure which is limited, however, to diazo compounds which allow energetically favorable realization of the transition state leading to the cyclized product. 

C—H bond 174-280,28i por comparison, only trace amounts of cyclopentane resulted from the CuS04-catalyzed decomposition of 1 -diazo-2-octanone or l-diazo-4,4-dimethyl-2-pentanone 277). It is obvious that the use of Rh2(OAc)4 considerably extends the scope of transition-metal catalyzed intramolecular C/H insertion, as it allows for the first time, efficient cyelization of ketocarbenoids derived from freely rotating, acyclic diazoketones. This cyelization reaction can also be highly diastereo-selective, as the exclusive formation of a m is-2,3-disubstituted cyclopentane carboxylate from 307 shows281 a). The stereoselection has been rationalized by... 

Efforts to realize an intramolecular version of the above reactions met with limited success when monocyclic 4-thio-substituted (3-lactams were used. Cu(acac)2-catalyzed decomposition of diazoketone 358 produced the epimeric carbapenams 359 a, b together with the oxapenam derivative 360 341 these compounds correspond to the C4/S insertion products obtained in intermolecular reactions. Oxapenams were obtained exclusively when the acrylate residue in 359 was replaced by an aryl or heteroaryl substituent 275 342). The different reaction mode of diazoketones 290a, b, which furnish mainly or exclusively carbonyl ylide rather than sulfur ylide derived products, has already been mentioned (Sect. 5.2). 

The CJS insertion reaction was suppressed completely upon catalytic decomposition of diazoketones 361, where the sulfur substituent was alkyl, acyl or thioacyl. It is presumed that sulfonium ylides occur as intermediates which give cepham (or cephem) derivatives in all cases270,343) rather than products of a Stevens rearrangement. 

The Cu(acac)2-promoted transformation 368 - 369 represents an intramolecular carbenoid insertion into the penicillin C5—S bond 347). The original report did not mention the low-yield formation of a second product to which the tricyclic structure 370 was assigned 348,349 >. In both 369 and 370, the original stereochemistry at C-5 of 368 has been inverted this is seen as a consequence of intramolecular nucleophilic a-face attack in a presumed azetidinium enolate intermediate. Attempts to realize a more flexible intermediate which then would have a chance to undergo p-face attack centered on the chain-extended diazoketone 371. Its catalytic decomposition led to the tricycle 372 exclusively, however, C7/N rather than C5/S insertion having taken place 349). 

Wolff rearrangement of a-diazoketones to give ketenes or subsequent products is an often used synthetic procedure the scope and limitations of which are well established 13 390), so that only a few new features of this reaction need to be considered here. Concerning its catalytic version, one knows that copper, rhodium and palladium catalysts tend to suppress the rearrangement390). A recent case to the contrary is provided by the Rh2(OAc)4-catalyzed decomposition of ethyl -2-diazo-3-oxopent-4-enoates 404 from which the p,y-unsaturated esters 405 are ultimately obtained via a Wolff rearrangement 236). The Z-5-aryl-2-diazo-3-oxopent-4-enoates undergo intramolecular insertion into an aromatic C—H bond instead (see Sect. 4.1). 

Metal-catalyzed decomposition of p,y-unsaturated a -diazoketones 400 in the presence of an alcohol affords rearranged y,8-unsaturated esters 407 this process has been termed the vinylogous Wolff rearrangement193 . Full accounts dealing with the... 

Two type la syntheses of (3-hydroxypyrroles have appeared. An aza-Nazarov cyclization of l-azapenta-l,4-dien-3-ones produced (3-hydroxypyrroles including 2,2 -bipyrroles <06EJO5339>. A second approach to a (3-hydroxypyrrole involved an intramolecular N-H insertion into a rhodium carbene derived from the decomposition of a diazoketone <06JOC5560>. On the other hand, the photochemical decomposition of the diazoketone led to pyrrolidin-2-ones. 

In 2001, Linder and Podlech studied the microwave-assisted decomposition of diazoketones derived from a-amino acids [340]. In the presence of imines, the initially formed ketene intermediates reacted spontaneously by [2+2] cydoaddition to form /3-lactams with a trans substitution pattern at positions C-3 and C-4 (Scheme 6.179) [340], In order to avoid the use of the high-boiling solvent 1,2-dichlorobenzene, most transformations were carried out in 1,2-dimethoxyethane under sealed-vessel conditions. Solvent-free protocols, in which the substrates were adsorbed onto an inorganic alumina support, led only to the corresponding homologated /3-amino acids. Evidently, traces of water present on the support trapped the intermediate ketene. 

Reactions that have led to other deoxyhalogeno sugars do not necessarily lead to deoxyfluoro sugars, as, for example, in the attempted decomposition of fluoroformates, the treatment of diazoketones and of 2-deoxy-2-diazohexonates with hydrogen fluoride, and the reaction of benzoxonium ions with halide ions. The reaction2281229 by which fluoroformates are thermally or catalytically decarbonylated to give alkyl fluorides has been applied to carbohydrates. Both thermal and catalytic treatment of 6-0-(fluoroformyl)-l,2 3,4-di-0-isopropylidene-... 

Sebacid acid dinitrile, 50, 20 SELECTIVE o-BROMINATION OF AN ARALKYL KETONE WITH PHENYL-TRIMETHYL AMMONIUM TRIBROMIDE 2-BRQM0ACETYL-6-METH-OXYNAPHTHALENE AND 2,2-DI-BROMOACETYL-6-METHOXYNAPH-THALENE, 53, 111 Shikimic acid, 50, 27 Silver benzoate, as catalyst in decomposition of diazoketones, 50, 78... 

A density functional study has been made of the competition between Wolff rearrangement and [1,2]-H shift in /S-oxy-a-diazocarbonyl compounds. Silver-catalysed decomposition of a-diazoketones (88 n = 0), derived from A-tosyl a-amino acids in methanol, gave rise to mixtures of products of Wolff rearrangement (89) and direct insertion of the carbene into the NH bond (90). The -amino acid derived species (88 n = 1) gave rise to products of Wolff rearrangement. 

Decomposition of diazoketone 110 with rhodium acetate produced the highly electrophilic rhodium stabilized metallocarbenoid that suffers attack by the Lewis basic oxygen of the pendant ketone, producing cyclic carbonyl ylide 111. This ylide was trapped by the addition of an activated acetylene such as DMAD to furnish... 

Decomposition of diazoketone 113 with rhodium acetate led to the formation of a tethered cyclic carbonyl ylide 114 that was poised to undergo an intramolecular cycloaddition, preparing 115 in 60% yield. Interestingly, if DMAD was added to the reaction mixture, the only product arose from intermolecular cycloaddition. 

The cyclic ammonium ylide/[l,2]-shift approach has been successfully applied by West and Naidu to a key step in the total synthesis of (—)-epilupinine, one of the biologically active lupin alkaloids. Cu(acac)2-catalyzed diazo decomposition of enantiomeric pure diazoketone 160 in refluxing toluene generates a spiro ammonium ylide 161 and 162, which then undergoes [l,2]-shift to give rise to a quinolizidine skeleton as a mixture of diastereomers (95 5) (Scheme Major diastereomer 164 has enantiomeric purity of 75% ee. The partial retention of stereo-... 

Sulfonyl azides react rapidly (at room temperature) with enamines, and here, too, no triazolines are isolated. The reaction products nevertheless can be easily explained when an intermediate triazoline is postulated. The hypothetic triazoline can then decompose in three different ways leading either to amidines and nitrogen, or to amidines and diazoketones, or to triazoles and sulfonamines.226-241-270-272 A typical example of each mode of decomposition is given in Scheme IX. 

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