Diazoacetic acid methyl ester

Diazoacetic Acid, Methyl Ester or Methyldiazo-acetate (called Diazoessigsaure-methylester in Ger), N2CH.CO2.CH3 mw 100.08, N 27.99% It-yel expl liq, bp 31° at 12mm Hg distillation, even under reduced pressure, is extremely dangerous, since heat causes the compd to detonate violently d 1,158 at 25°, nQ 1.4515 1,4676 at 20.6° was... 

Copper(ll) acetylacetonate Copper, bis(2,4-pentanedionato-0,0 )- (9) (46369-53-3) Methyl diazoacetate Acetic acid, diazo-, methyl ester (8,9) (6832-16-2) Triethylammonium fluoride Triethylamine hydrofluoride (8) Elhanamine, N,N-diethyl-, hydrofluoride (9) (29585-72-6)... 

The best known example of the treatment of a primary aliphatic amine with nitrous acid involves the reaction of esters of glycine hydrochloride with sodium nitrite to form esters of diazoacetic acid. This reaction is carried out at low temperatures and under such reaction conditions that any IV-nitroso primary amine which might have been formed is immediately converted to the diazoacetate [15, 16]. Treatment of 1-methyl-2,2,2-trifluoroethylamine hydrochloride, another primary amine, with sodium nitrite in an aqueous system also evidently leads to the corresponding diazoalkane [17]. 

Intermolecular cyclopropanation reactions with ethyl diazoacetate have been employed for the construction of the cyclopropane-containing amino acid 7 (equation 25) Thus, rhodium(II) acetate catalysed decomposition of ethyl diazoacetate in the presence of d-cbz-vinylglycine methyl ester 5 afforded cyclopropyl ester 6 in 85% yield. Removal of the protecting group completed the synthesis of 7. Another example illustrating intermolecular cyclopropanation can be found in Piers and Moss synthesis of ( )-quadrone 8" (equation 26). Intermolecular cyclopropanation of enamide or vinyl ether functions using ethyl diazoacetate has also been used in the synthesis of eburnamonine 9", pentalenolactone E ester 10" and ( )-dicranenone A11" (equations 27-29). 

Diazoacetic acid ester reacts with benzene and homologs to give the corresponding esters of non-caradienic acid, transformed at high temperatures to derivatives of cycloheptatriene, phenylacetic acid, and (i-phenylpropionic acid (when one or more methyl groups are present in the initial hydrocarbon). 

The carbenoid reaction between alkyl diazoacetates and enol ethers, enol acetates and silyl enol ethers furnishes P-oxycyclopropane carboxylates (see Tables 2, 4, 5, 6, 7 and Scheme 5). The recently recognized synthetic versatility of these donor/acceptor-substituted cyclopropanes i 2,io3) (precursors of 1,4-dicarbonyl and P, 7-unsaturated carbonyl compounds, 4-oxocarboxylic acids and esters, among others) gave rise to the synthesis of a large number of such systems with a broad variation of substituents p-acetoxycyclopropanecarboxylates , p-alkoxy- or p-aryloxysubstituted cyclopropanecarboxylates 2-alkoxy-1-methyl-1-cy-... 

The reaction of methyl stearolate (1) with diazoacetic ester in the presence of copper bronze produces a diester, which is hydrolyzed to the diacid (2). This is converted into the diacid chloride (3). Treatment with zinc chloride or other Lewis acid effects selective decarbonylation to give the cyclopropenium ion (4). Methanol is then added to convert the acid chloride grouping into the methyl ester (5). Finally reduction with sodium borohydride gives methyl sterculate (6). 

Follow-up chemistry of azetidyl ylide 94, which was obtained by hydrolysis of ylide 84, led to various pyrrolidines and pyrazoles [68]. The reaction with methyl oxalyl chloride gave a 4-triphenylphosphoranyhdene-pyrrolidine-2,3,5-trione 95, while treatment with ethyl diazoacetate afforded 4-anilido-3-triphenylphosphoran-ylidene-pyrazole-5-carboxylic acid ethyl ester 96 (Scheme 20). 

For the synthesis of permethric acid esters 16 from l,l-dichloro-4-methyl-l,3-pentadiene and of chrysanthemic acid esters from 2,5-dimethyl-2,4-hexadienes, it seems that the yields are less sensitive to the choice of the catalyst 72 77). It is evident, however, that Rh2(OOCCF3)4 is again less efficient than other rhodium acetates. The influence of the alkyl group of the diazoacetate on the yields is only marginal for the chrysanthemic acid esters, but the yield of permethric acid esters 16 varies in a catalyst-dependent non-predictable way when methyl, ethyl, n-butyl or f-butyl diazoacetate are used77). 

The change in selectivity is not credited to the catalyst alone In general, the bulkier the alkyl residue of the diazoacetate is, the more of the m-permethric acid ester results 77). Alternatively, cyclopropanation of 2,5-dimethyl-2,4-hexadiene instead of l,l-dichloro-4-methyl-l,3-pentadiene leads to a preference for the thermodynamically favored trans-chrysanthemic add ester for most eatalyst/alkyl diazoacetate combinations77 . The reasons for these discrepandes are not yet clear, the interplay between steric, electronic and lipophilic factors is considered to determine the stereochemical outcome of an individual reaction77 . This seems to be true also for the cyclopropanation of isoprene with different combinations of alkyl diazoacetates and rhodium catalysts77 . 

A study of the regioselectivity of the 1,3-dipolar cycloaddition of aliphatic nitrile oxides with cinnamic acid esters has been published. AMI MO studies on the gas-phase 1,3-dipolar cycloaddition of 1,2,4-triazepine and formonitrile oxide show that the mechanism leading to the most stable adduct is concerted. An ab initio study of the regiochemistry of 1,3-dipolar cycloadditions of diazomethane and formonitrile oxide with ethene, propene, and methyl vinyl ether has been presented. The 1,3-dipolar cycloaddition of mesitonitrile oxide with 4,7-phenanthroline yields both mono-and bis-adducts. Alkynyl(phenyl)iodonium triflates undergo 2 - - 3-cycloaddition with ethyl diazoacetate, Ai-f-butyl-a-phenyl nitrone and f-butyl nitrile oxide to produce substituted pyrroles, dihydroisoxazoles, and isoxazoles respectively." 2/3-Vinyl-franwoctahydro-l,3-benzoxazine (43) undergoes 1,3-dipolar cycloaddition with nitrile oxides with high diastereoselectivity (90% de) (Scheme IS)." " ... 

Much effort this year has been expended on chrysanthemic acid syntheses. Aratani et al. have extended earlier work on asymmetric synthesis (Vol. 6, p. 21) by decomposing various alkyl diazoacetates in 2,5-dimethylhexa-2,4-diene in the presence of chiral copper complexes to yield up to 92% of rrans-chrysanthemic acid in 88% dextrorotatory enantiomeric excess. Mitra has used ozonolysis of (+)-a-pinene to obtain, stereospecifically, the bromo-ketone (104) which undergoes Favorskii rearrangement to yield the anticipated ester (105) from which (+)-trans-chrysanthemic acid is readily obtained a second paper reports another route from (+)-car-3-ene initially to methyl (—)-c/s-chrysanthemate or to (—)-dihydro-chrysanthemolactone (106), both of which are convertible into (+)-rra s-chrysan-... 

Photochemical Fe(CO)5-induced rearrangement of silylated allyl amine 9 gave N-silylated enamine 1015, which on subsequent Cu-catalyzed cyclopropanation by methyl diazoacetate afforded cyclopropane derivative 11. The use of an optically active catalyst gave an asymmetric induction of 56% ee for the cis isomer and 20% ee for the trans isomer. Further acid-induced ring cleavage afforded the -formyl ester 12, whereas reduction and desilylation produced aminocyclopropane carboxylic acid 13 (equation 2). 

In a mechanistic study on the Lewis acid catalyzed addition of ethyl diazoacetate to ketones a similar profile of rearrangement to the 3-keto esters was observed (Scheme 9). In the same reaction with acetophenones, substitution on the benzene ring was found to only slightly affect the otherwise 90 10 preference for migration of aryl versus methyl. ... 

Decarbonylation of cyclopropene acids. In a study of the synthesis of methyl sterculate (6) from methyl stearolate (1), Gensler et al.1 were unable to repeat the apparently straightforward synthesis based on addition of the Simmons-Smith reagent described in 1, 1021-1022. They were also unable to eifect addition of methylene generated by cuprous bromide decomposition of diazomethane. However, the reaction of (1) with diazoacetic ester in the presence of copper bronze, followed by hydrolysis, gives the cyclopropene diacid (2) in 70-90% yield. 

Latterly, attention has been turned to the alkylation of the hydrogenphosphonates themselves under essentially neutral conditions, thus obviating the several possible side reactions. The formation (in 38% yield) of triethyl phosphonoacetate from diethyl hydro-genphosphonate and ethyl diazoacetate has been known for some time, and the synthetically useful methyl (di-tcrt-butoxyphosphinoyl)acetate (in 40% yield) has been similarly and more recently obtained Steps have been to tiy to improve yields under photoinitiation in the presence of copper salts or complexes ", or through catalysis by trifluoromethanesulphonic acid Such procedures allow the ready synthesis of the esters 411 (R = alkyl or RO). 

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