Carbene reactions rhodium-catalyzed

Dilithio-1,3-dienes were found to react with aldehydes to form polysubstituted 2,5-dihydrofurans in a regio- and stereoselective manner <02OL2269>. Like other metal-carbene reactions, rhodium-catalyzed tandem carbonyl ylide formation - cycloaddition with propargyl bromide gave the 2,5-dihydrofuran in good yield <020L1809>. 

Trifluoromethyl-substituted diazonium betaines [176]. Synthetic routes to trifluoromethyl-substituted diazo alkanes, such as 2,2,2-trifluorodiazoethane [ 177, 7 78, 179] and alkyl 3,3,3-trifluoro-2-diazopropionates [24], have been developed Rhodium-catalyzed decomposition of 3,3,3-tnfluoro-2-diazopropionates offers a simple preparative route to highly reactive carbene complexes, which have an enormous synthetic potential [24] [3-1-2] Cycloaddition reactions were observed on reaction with nitnles to give 5-alkoxy-4-tnfluoromethyloxazoles [750] (equation 41)... 

The EfZ ratio of stilbenes obtained in the Rh2(OAc)4-catalyzed reaction was independent of catalyst concentration in the range given in Table 22 357). This fact differs from the copper-catalyzed decomposition of ethyl diazoacetate, where the ratio diethyl fumarate diethyl maleate was found to depend on the concentration of the catalyst, requiring two competing mechanistic pathways to be taken into account 365), The preference for the Z-stilbene upon C ClO -or rhodium-catalyzed decomposition of aryldiazomethanes may be explained by the mechanism given in Scheme 39. Nucleophilic attack of the diazoalkane at the presumed metal carbene leads to two epimeric diazonium intermediates 385, the sterically less encumbered of which yields the Z-stilbene after C/C rotation 357,358). Thus, steric effects, favoring 385a over 385 b, ultimately cause the preferred formation of the thermodynamically less stable cis-stilbene. 

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. 

In addition to palladium catalysts, Co(OAc)2 shows a catalytic activity for the arylation of heterocycles, including thiazole, oxazole, imidazole, benzothiazole, benzoxazole, and benzimidazole.78 As shown in Scheme 6, the catalytic system Co(OAc)2/9/Cs2C03 gives G5 phenylated thiazole, while the bimetallic system Co(OAc)2/CuI/9/Cs2C03 furnishes the G2 phenylated thiazole. The rhodium-catalyzed reaction of heterocycles such as benzimidazoles, benzoxazole, dihydroquinazoline, and oxazoline provides the arylation product with the aid of [RhCl(coe)]2/PCy3 catalyst.79 The intermediacy of an isolable A-heterocyle carbene complex is proposed. 

The first rhodium-catalyzed reductive cyclization of enynes was reported in I992.61,61a As demonstrated by the cyclization of 1,6-enyne 37a to vinylsilane 37b, the rhodium-catalyzed reaction is a hydrosilylative transformation and, hence, complements its palladium-catalyzed counterpart, which is a formal hydrogenative process mediated by silane. Following this seminal report, improved catalyst systems were developed enabling cyclization at progressively lower temperatures and shorter reaction times. For example, it was found that A-heterocyclic carbene complexes of rhodium catalyze the reaction at 40°C,62 and through the use of immobilized cobalt-rhodium bimetallic nanoparticle catalysts, the hydrosilylative cyclization proceeds at ambient temperature.6... 

In consideration of conceivable strategies for the more direct construction of these derivatives, nitriles can be regarded as simple starting materials with which the 3+2 cycloaddition of acylcarbenes would, in a formal sense, provide the desired oxazoles. Oxazoles, in fact, have previously been obtained by the reaction of diazocarbonyl compounds with nitriles through the use of boron trifluoride etherate as a Lewis acid promoter. Other methods for attaining oxazoles involve thermal, photochemical, or metal-catalyzed conditions.12 Several recent studies have indicated that many types of rhodium-catalyzed reactions of diazocarbonyl compounds proceed via formation of electrophilic rhodium carbene complexes as key intermediates rather than free carbenes or other types of reactive intermediates.13 If this postulate holds for the reactions described here, then the mechanism outlined in Scheme 2 may be proposed, in which the carbene complex 3 and the adduct 4 are formed as intermediates.14... 

Photolytic (68CB302) or rhodium-catalyzed decomposition of alkyl 3,3,3-trifluoro-2-diazopropionates gives carbenes and carbene complexes, respectively, which exhibit an enormous synthetic potential. [3 + 2] cycloaddition reactions have been performed, e.g., with nitriles to give 4-trifluoromethyl-substituted oxazoles [90JOC3383 9IJFC(52)149]... 

For the rhodium-catalyzed cyclopropanation of olefin substrates with activated allylic C—H groups, the selectivity between cyclopropanation and C—H insertion is sometimes unsatisfactory. Very recently, Davies and Thompson (128) reported a selective silver-catalyzed cyclopropanation of olefins to give predominately cyclopropane products. Aryldiazoacetates were used as carbene precursors with the aryl groups helping to stabilize the carbene intermediate and facilitate the reaction. Notably, phenallyldiazoacetate with different olefins also gave cyclopropane products (Fig. 26). 

Carbene itself ( CH2) is extremely reactive and gives many side reactions, especially insertion reactions (12-21), which greatly reduce yields. This competition is also true with rhodium-catalyzed diazoalkane cyclopropanations (see below). When it is desired to add CH2 for preparative purposes, free carbene is not used, but the Simmons-Smith procedure (p. 1241) or some other method that does not involve free carbenes is employed instead. Halocarbenes are less active than carbenes, and this reaction proceeds quite well, since insertion reactions do not interfereThe absolute rate constant for addition of selected alkoxychlorocar-bene to butenes has been measured to range from 330 to 1 x 10 A few of the many ways in which halocarbenes or carbenoids are generated for... 

Almost at the same time, Pirrung and Johnson " independently described the rearrangement of oxonium ylides prepared by intramolecular rhodium-catalyzed carbene addition. The reaction appears to have a broad scope and gives an easy entry into complex oxygenated polycycles (Scheme 61). When the possibility arises, high levels of diastereocontrol are exercised (Scheme 62). 

Allyl sulfides and allyl amines. Rhodium-catalyzed decomposition of ethyl diazoacetate in the presence of these allyl compounds generates products 136 and 137, respectively, derived from [2,3] rearrangement of an S- or N-ylide intermediate, besides small amounts of carbene dimers No cyclopropane and no product resulting from the ylide by [1,2] rearrangement were detected. Besides RhjfOAc) and Rhg(CO)i6, the rhodium(I) catalysts [(cod)RhCl]2 and [(CO)2RhCl]2 were found to behave similarly, but yields with the only allyl amine tested, CH =CH—CH NMe, were distinctly lower with the latter two catalysts. Reaction temperatures are higher than usually needed in rhodium-promoted diazoalkane decomposition, which is certainly due to competition between the diazo compound and the allylic hetero-... 

Another way in which dihydrobenzo[c]furans can be produced is through Ni(0)-catalyzed [2+2+2] cocyclotrimerization of arynes with diynes, as depicted in the following scheme <05CC2459>. Similar ruthenium- <05CC4438> and rhodium-catalyzed reactions <05CC3971>, as well as a carbene-Zn catalyzed reaction <050L3065> led to the formation of dihydrobenzo[c]furans. 

Iodorhodium(IIl) porphyrins also efficiently catalyze the reaction of ethyl diazoacetate with simple alkenes. generally providing the cw-isomers as the major product77 79110. The cis( tram ratio increases when bulkier porphyrins, such as tetramesitylporphyrin (TMP), are employed. The mechanism of this rhodium-catalyzed cyclopropanation with diazoacetate is interpreted as proceeding via carbene complexes79 80 111,112. Based on these results, asymmetric cyclopropanation of alkenes with ethyl diazoacetate is achieved if catalyzed by a chiral wall porphyrin81. An earlier described binaphthyl-system of this type82113114, introduced as an iodorhodium(lll) complex, 6, forms an extremely active catalyst and leads to m-cyclopropanes (preferred over the rran.v-products) with moderate to poor enantioselectivities if styrene, 1- and 3-phenylpropene are used as substrates (10-60% ee)81. 

Metal catalyzed enantioselective C-H insertions of carbenes have so far not been studies in great detail. Copper catalysts are of no use for this type of reaction, rhodium(Il) catalysts, however, allow intramolecular C-H insertions, for example, in the alkyl group of diazoacetates with longer chains. The formation of five-membered rings such as y-lac-tones is favored. [Rh2(55-mepy)4] affords... 

As mentioned, rhodium-catalyzed cyclopropanation reaction of diazoketones is quite useful. As we saw in Section 11.12.C, Davies used a carbene insertion reaction in tandem with a Cope rearrangement to prepare... 

Sulfur controlled radical cyclization of A -ethenyl-a-bromo-alkanamides occurs in a A-exo-trig manner to give the trans-3,A-Rhodium catalyzed carbene insertion reactions are very useful for the preparation of bicyclic P-lactams but are little used to form monocyclic p-lactams. High yields and exceptional stereocontrol are achieved when a-diazo-amides are decomposed in the presence of rhodium(II) catalysts to give (63) (93BMC2409). 

Attempts to trap with dimethyl acetylenedicarboxylate (DMAD) a presumed intermediate ylide formed upon rhodium-catalyzed carbene generation led instead to a 33% yield of oxazocine (74), apparently formed by fragmentation of the initial [3 -I- 2] cycloadduct of DMAD with the ylide, followed by acyl migration (Scheme 27). Ylide tautomerization, followed by an analogous sequence of reactions, accounts for a 24% yield of isomer (95) <92TL3273>. 

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