Of diazoketone

A mixture of 4 g of diazoketone (94) and 2.2 g of sodium bicarbonate in 200 ml of tetrahydrofuran and 180 ml of water is irradiated with a Hanovia 200 W mercury vapor lamp (using a Corex filter) until the starting material has been consumed. After addition of 500 ml of water, followed by extraction of nonacidic products, the solution is acidified, cooled to 0° and filtered to yield 2.95 g (76%) of white crystals of crude acid (95) mp 170-176°. An analytical sample has mp 188°. ° ... 

In contrast to molecular fluorine, trifluoromethyl hypofluonte has limited synthetic value for geminal fluorination of diazoketones owing to formation of complex mixtures [97]... 

Tandem cyclization-cycloaddition of diazoketones in the synthesis of some alkaloids 97F303. 

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). 

The Arndt-Eistert reaction (Scheme 2.1) which involves the Wolff rearrangement of diazoketones 13 (prepared from the corresponding commercially available N-protected-a-amino acids 12 by reaction of their mixed anhydrides with diazomethane a cautionary note is warranted here the generation and handling of diazomethane require special precautions) has been used extensively by Seebach and coworkers for the preparation of N-protected /9 -amino acids 14 and /9 -amino acid esters 15 and 16. 

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). 

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 semicorrin complex (68a) has been successfully used as the catalyst for cyclization of alkenyl diazoketones, though the reactions of some substrates showed modest enantioselectivity (Scheme 74).276 Shibasaki et al. have successfully used the cyclization of diazoketone with Cu bis(oxazoline) (101) for the construction of the CD ring skeleton of phorbol.277... 

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. 

Finally, Podlech has recently reported [125] the transformation of diazoketones 227, derived from a-amino acids, to ketenes that can react further with imines to afford /1-lactams 228 (Scheme 9.74). It was found that this route proceeds not only by... 

Although the Wolf rearrangement of diazoketones in the presence of silver benzoate and triethylamine in methanol could involve rearrangement of an intermediate diradical or carbonium ion conjugate... 

Several reviews of P-lactam chemistry have appeared including a general survey with 407 references <99MI335>. Other reviews include discussions of thioester enolate-imine reactions , enantio- and diastereo-selective routes to azetidinones <99MI221>, the use of diazoketones in diastereoselective synthesis <99MI43>, and solid-phase and combinatorial syntheses of p-lactams <99MI955>. 

In the list of diazoketones studied by us95 mostly derivatives were included which have in solution no or only a small tendency for a Wolff rearrangement. Nevertheless we found not a single diazoketone 71 which enabled us to identify a ketocarbene 72, only the corresponding ketenes 73 could be detected. The same observation was made when we studied in collaboration with Yannoni et al." the photochemically induced deazotation of l-diazo-2-propanone in an organic matrix at 77 K, using 13C CPMAS NMR spectroscopy as the analytical tool. 

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... 

Triethylaluminum, apparatus and procedures for handling, 52, 90, 96, 100 Triethylamine, in synthesis of diazoketones, 50, 77 Triflates, vinyl-, 54, 82... 

With acyl and alkoxycarbonyl azides, 2 -triazoles are isolated, although the l.ff-isomers are detected as intermediates. The reaction is not very general it fails with the corresponding sulfonium ylids, and fairly minor changes in substituents on the phosphorus ylid result in the formation of diazoketones rather than triazoles. ... 

Scheme 12 shows synthesis of 1,2,3-thiadiazoles by the Wolff, Hurd-Mori and Pechmann-Nold methods. Pechmann s and Wolffs are the oldest of the methods. The Pechmann-Nold synthesis involves the [3 + 2] cycloaddition of diazo-compounds to isothiocyanates or thiocarbonyl compounds (modified Pechmann synthesis). The use of thiocarbonyl compounds in the [3 + 2] cycloaddition step has broadened the scope of this reaction and made the starting materials more readily accessible. Wolffs method requires the synthesis of diazoketones that are treated with a thionating reagent to produce 1,2,3-thiadiazoles. With the development of new methods of diazotransfer reactions, the diazoketone precursors have become easily attainable and with further attention to the thionating reagents, this reaction is also useful for the synthesis of 1,2,3-thiadiazoles. 

The reactions of A -BOC-protected a-amino acids 424 and diazomethane in the presence of iV-methylmorpholine-polystyrene and isobutyl chloroformate resulted in formation of diazoketones 425, which, on treatment with indium(lll) triflate, were cyclized to 4-substituted-tetrahydro-l,3-oxazine-2,5-diones 426 in high overall yields (Scheme 82) <2006TL7969>. 

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. 

Padwa et al. (48) examined the behavior of diazoketone 127 under rhodium catalysis and found that the ligands associated with rhodium had a dramatic effect on the distribution of products 128 (from the carbonyl ylide) and 129 (from intramolecular C—H insertion). When rhodium acetate was employed there was a... 

Beyond these systems, challenges in stereocontrol remain for both inter- and intramolecular cyclopropanation reactions with diazoketones, diazoketoesters (18), diazomalonates, and diazomethane. Although some progress has been made in intramolecular reactions of diazoketones, with selected examples having high % ee values,enantiocontrol is generally low to moderate for these systems. 

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