Diazoketones, carbene reactions with

These reactions are not necessarily carbene reactions, although this may well be the case with diazoketones. Their common feature... 

The ambident nucleophilic character of enaminones is again demonstrated by the reaction with keto carbenes, produced in situ from diazoketones. Acyclic enaminones react via the -position to directly yield pyrroles (equation 11). Cyclic enaminones are shown to react at the nitrogen to give adducts which can be cyclized with KOH to... 

Polymer-supported benzenesulfonyl azides have been developed as a safe diazotransfer reagent. ° These compounds, including CH2N2 and other diazoalkanes, react with metals or metal salts (copper, paUadium, and rhodium are most commonly used) to give the carbene complexes that add CRR to double bonds. Diazoketones and diazoesters with alkenes to give the cyclopropane derivative, usually with a transition-metal catalyst, such as a copper complex. The ruthenium catalyst reaction of diazoesters with an alkyne give a cyclopropene. An X-ray structure of an osmium catalyst intermediate has been determined. Electron-rich alkenes react faster than simple alkenes. ... 

The ease of insertion of an acylmethylene group (derived as the carbene from a diazoketone) is dependent on the nature of the bonding at tetracoordinate quinquevalent phosphorus. Thus, insertion is accompanied by rearrangement during reactions with... 

This carbene insertion reaction has been used in a variety of syntheses, and is especially attractive when coupled with other synthetic techniques. Taber et al. used carbene cyclopropanation in several synthetic endeavors. In one example, the diazoketone was treated with bis-A-tert-butylsalicylaldiminato copper(II) [Cu(TBS)2, 388] to induce the carbene cyclopropanation reaction. The diazoketone was prepared by treating 386 with mesyl azide to give 387 in 82% yield, which was followed by treatment with the Cu(TBS)2 reagent to produce 389 in 80% yield in Taber and co-workers synthesis of (-i-)-isoneonepatelactone.308... 

Some other electrophiles that convert alkenes to cyclopropanes are not free carbenes but have metals coordinated with their electrophihc site. These are called carbenoids and include the Simmons-Smith reaction and the copper-, rhodium-, or palladium-catalyzed decomposition of diazoketones and esters (Section 7.3). That the metal atom is present in the electrophile is shown by the variation of the stereoselectivity of the reaction with changes in the other ligands on metal. 

Diazoalkanes are u.seful is precursors to ruthenium and osmium alkylidene porphyrin complexes, and have also been investigated in iron porphyrin chemistry. In an attempt to prepare iron porphyrin carbene complexes containing an oxygen atom on the /(-carbon atom of the carbene, the reaction of the diazoketone PhC(0)C(Ni)CH3 with Fe(TpCIPP) was undertaken. A low spin, diamagnetic carbene complex formulated as Fe(TpCIPP)(=C(CH3)C(0)Ph) was identified by U V-visible and fI NMR spectroscopy and elemental analysis. Addition of CF3CO2H to this rapidly produced the protonated N-alkyl porphyrin, and Bit oxidation in the presence of sodium dithionitc gave the iron(II) N-alkyl porphyrin, both reactions evidence for Fe-to-N migration processes. ... 

Palladium(II) acetate was found to be a good catalyst for such cyclopropanations with ethyl diazoacetate (Scheme 19) by analogy with the same transformation using diazomethane (see Sect. 2.1). The best yields were obtained with monosubstituted alkenes such as acrylic esters and methyl vinyl ketone (64-85 %), whereas they dropped to 10-30% for a,p-unsaturated carbonyl compounds bearing alkyl groups in a- or p-position such as ethyl crotonate, isophorone and methyl methacrylate 141). In none of these reactions was formation of carbene dimers observed. 7>ms-benzalaceto-phenone was cyclopropanated stereospecifically in about 50% yield PdCl2 and palladium(II) acetylacetonate were less efficient catalysts 34 >. Diazoketones may be used instead of diazoesters, as the cyclopropanation of acrylonitrile by diazoacenaph-thenone/Pd(OAc)2 (75 % yield) shows142). 

The dominant role of the traditional copper catalysts, generally used under heterogeneous conditions, has not been challenged as yet. Only a few reports shed light on the efficiency of alternative catalysts. Copper(II) triflate allows high-yield intramolecular cyclopropanation of y,8-unsaturated diazoketone 182160) it is superior to CuS04 (53 % yield 192 ) or Rh2(OAc)4160). The solvent is crucial for an efficient conversion If the reaction is carried out in ether, the solvent competes with the double bond for the electrophilic metal carbene to give 184, presumably via an oxonium ylide intermediate. 

Products of a so-called vinylogous Wolff rearrangement (see Sect. 9) rather than products of intramolecular cyclopropanation are generally obtained from P,y-unsaturated diazoketones I93), the formation of tricyclo[2,1.0.02 5]pentan-3-ones from 2-diazo-l-(cyclopropene-3-yl)-l-ethanones being a notable exception (see Table 10 and reference 12)). The use of Cu(OTf), does not change this situation for diazoketone 185 in the presence of an alcoholl93). With Cu(OTf)2 in nitromethane, on the other hand, A3-hydrinden-2-one 186 is formed 160). As 186 also results from the BF3 Et20-catalyzed reaction in similar yield, proton catalysis in the Cu(OTf)2-catalyzed reaction cannot be excluded, but electrophilic attack of the metal carbene on the double bond (Scheme 26) is also possible. That Rh2(OAc)4 is less efficient for the production of 186, would support the latter explanation, as the rhodium carbenes rank as less electrophilic than copper carbenes. 

Rhodium(II) acetate was found to be much more superior to copper catalysts in catalyzing reactions between thiophenes and diazoesters or diazoketones 246 K The outcome of the reaction depends on the particular diazo compound 246> With /-butyl diazoacetate, high-yield cydopropanation takes place, yielding 6-eco-substituted thiabicyclohexene 262. Dimethyl or diethyl diazomalonate, upon Rh2(OAc)4-catalysis at room temperature, furnish stable thiophenium bis(alkoxycarbonyl)methanides 263, but exclusively the corresponding carbene dimer upon heating. In contrast, only 2-thienylmalonate (36 %) and carbene dimer were obtained upon heating the reactants for 8 days in the presence of Cul P(OEt)3. The Rh(II)-promoted ylide formation... 

The reaction of ADC compounds with carbenes and their precursors has already been discussed in Section IV,A- In general, the heterocyclic products are not the result of 1,2-addition but of 1,4-addition of the carbene to the —N=N—C=0 system.1 Thus the ADC compound reacts as a 4n unit in a cheletropic reaction leading to the formation of 1,3,4-oxadiazolines. Recent applications include the preparation of spiro-1,3,4-oxadiazolines from cyclic diazoketones and DEAZD as shown in Eq. (14),133 and the synthesis of the acyl derivatives 85 from the pyridinium salts 86.134 The acyl derivatives 85 are readily converted into a-hydroxyketones by a sequence of hydrolysis and reduction reactions. 

The signature application for the G-H insertion in synthesis is probably the total synthesis of (—)-tetrodotoxin 126 by Du Bois and Hinman.233 Two stereospecific G-H activation steps, rhodium-catalyzed carbene G-H insertion and carbamate-based nitrene C-H insertion, have been used to install the two tetrasubstituted centers C6 and C8a (Scheme 12). Diazoketone 122 was treated with 1.5mol% Rh2(HNCOCPh3)4, and cyclic ketone 123 was selectively formed in high yield without purification. The reaction of carbamate 124 with 10mol% Rh2(HNCOCF3)4, PhI(OAc)4, and MgO in C6H6 solvent furnished the insertion product 125 in 77% yield. 

Transition metal-catalyzed reactions of ct-diazocarbonyl compounds proceed via electrophilic Fischer-type carbene complexes. Consequently, when cr-diazoketone 341 was treated, at room temperature, with catalytic amounts of [ RhiOAcbh, it gave the formation of a single NH insertion product, which was assigned to the enol stmcture 342. At room temperature, in both solid state and in solution, 342 tautomerizes to give the expected 1-oxoperhydropyr-rolo[l,2-c]oxazole derivative 343 (Scheme 50) <1997TA2001>. 

There are several reports in the literature dealing with the bimolecular [3 + 2] cycloaddition reactions of alkynyl-substituted diazo compounds. Propargyl diazoacetate 212, when stored for 2 weeks at 0 °C, was transformed into an oligomer to which the constitution 213 was assigned (273) (Scheme 8.50). The alkynyl-diazoketone 214 requires a much higher temperature and is transformed into pyrazole 215, which probably arises from intermolecular cycloaddition, pyrazole tautomerization, and carbenic N/H insertion (274). The inter-intramolecular... 

The diverse chemistry of carbenes is beyond the scope of this account, but a few typical reactions are shown here to illustrate the usefulness of the photochemical generation of these reactive species. A carbene can insert into a C—H bond, and this finds application in the reaction of an a-diazoamide to produce a P-lactam (5.29). Carbenes derived from o-diazoketones can rearrange to ketenes, and thus a route is opened up to ring-contraction for making more highly strained systems <5.301. Carbenes also react with alkenes, often by cycloaddition to yield cyclopropanes in a process that can be very efficient (5.31) and highly stereoselective (5.321. 

In addition to the preparations of ethanoadamantane via Lewis acid catalyzed rearrangement of various polycyclic hydrocarbons described above (Section II. A.1), a ring closure reaction of a substituted adamantane has also been developed. Treatment of 2-adamantyl diazoketone with copper results in the intramolecular carbene insertion illustrated in Eq. (48) 14°1. 

In contrast, in the photolysis of3,6-diphenylpyridazine-N-oxide 28 (R1 = R2 = Ph), a mixture of 3-benzoyl-5-phenylpyrazole 31 and 2,5-diphenylfuran 32 is formed. Diazoketone 29 (R1 = R2 = Ph) undergoes two competing reactions (i) thermal internal cyclization into the pyrazole 31 or (ii) photoinduced formation of a carbene leading to the final furan 32 (Scheme 12.9) therefore, the product distribution depends heavily on the reaction conditions. Thus, the formation of pyrazole 31 (75%) is favored over that of furan 32 (3%) by irradiation in acetone in a Rayonet reactor equipped with lamps irradiating at 350 nm. On the other hand, by irradiation with a Hanovia immersion lamp the yield of 31 decreases to 27%, whereas the yield of 32 increases to 67%. Moreover, the exclusive formation of the furan derivative 32 (43%) was observed by irradiation in the Rayonet reactor at low temperatures (—65 °C) [27]. 

This ester is one carbon atom short of the full side chain of grandisol, so an Arndt-Eistert reaction was used to lengthen the chain by one atom. First, the ester was converted into the diazoketone with diazomethane and, then, the Wolff rearrangement was initiated by formation of the carbene with a Amdt-Eistert chain extension of ester silver compound at the Ag(II) oxidation state. 

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