Intramolecular carbon-hydrogen insertion

Intramolecular carbon-hydrogen insertion reactions have well known to be elTectively promoted by dirhodium(ll) catalysts [19-23]. Insertion into the y-position to form five-membered ring compounds is virtually exclusive, and in competitive experiments the expected reactivity for electrophilic carbene insertion (3°>2° 1°) is observed [49], as is heteroatom activation [50]. A recent theoretical treatment [51] confirmed the mechanistic proposal (Scheme 15.4) that C-C and C-H bond formation with the carbene carbon proceeds in a concerted fashion as the ligated metal dissociates [52]. Chemoselectivity is dependent on the catalyst ligands [53]. 

Intramolecular Carbon-Hydrogen Insertion. The advantages of rhodium(II) catalysts for carbenoid transformations are nowhere more evident than with carbon-hydrogen insertion reactions. Exceptional regio- and diastereocontrol has been observed for Rh2(OAc)4 catalyzed transformations of a broad selection of diazoketones, a-diazo-p-ketoesters, a-diazo-P-keto-sulfones and -phosphonates which yield cyclopentanone derivatives in moderate to good yields (57-54). In contrast, poor yields and low regioselectivities characterize the corresponding copper catalyzed reactions. Applications of dirhodium(II) catalysts for C-H insertion reactions have even been extended to the synthesis of y-lactones (55), 3(2//)-furanones (56,57), P-laetones (58), and P-lactams (59,60). 

Enantioselective Intramolecular Carbon-Hydrogen Insertion Reactions. The suitability of Rh2(55-MEPY)4 and Rh2(5R-MEPY)4 for enantioselective intramolecular C-H insertion reactions is evident in results with 2-alkoxyethyl diazoacetates (eq 4). Both lactone enantiomers are available from a single diazo ester. Other examples have also been reported, especially those with highly branched diazo substrate structures. ... 

Diazoalkanes 1 form a versatile class of functionalized organic compounds [1]. Their undisputed significance in organic synthesis is manifested in a number of organometallic and other metal-induced reactions [2], some of which have entered catalytic applications. Cyclopropanation is one of them (cf. Section 3.1.7) but intramolecular carbon-hydrogen insertion appears of much potential in synthesis, too. This type of reaction relates to the easily available, normally nonexplosive a-diazocarbonyl compounds (a-diazoketones. Structure 2). 

Rhodium(II)-MEPY and rhodium(II)-MACIM (methyl 1-acetylimidazolidin-2-one-4-carboxylate) complexes are efficient chiral catalysts for intramolecular carbon-hydrogen insertion reactions of diazoacetates (224) and metal carbene transformations (225). Dirhodium(II) carboxylates of similar structure (eg, piperidinonate complexes of the Rh2(ligand)4 type) have been found efficient catalysts for asymmetric cyclopropanation of olefins (226). 

Tomioka, H., Kitagawa, H., and Izawa, Y., Photolysis of N,N-Diethyldiazoacetamide. Participation of a Noncarbenic Process in Intramolecular Carbon-Hydrogen Insertion, /. Org. Chem., 44, 3072,1979. 

Stang etal. (94JA93) have developed another alkynyliodonium salt mediated approach for the synthesis of y-lactams including bicyclic systems containing the pyrrole moiety. This method is based on the formation of 2-cyclopentenones 114 via intramolecular 1,5-carbon-hydrogen insertion reactions of [/3-(p-toluenesulfonyl)alkylidene]carbenes 113 derived from Michael addition of sodium p-toluenesulfinate to /3-ketoethynyl(phenyl) iodonium triflates 112 (Scheme 32). Replacing 112 by j8-amidoethynyl (phenyl)iodonium triflates 115-119 provides various y-lactams as outlined in Eqs. (26)-(30). 

Frey), as there was no known example of an intermolecular carbon-carbon insertion. The ensuing decades have not revealed such a reaction, despite some hard searching. " Why should the intramolecular version of carbon-carbon insertion compete so favorably with carbon-hydrogen insertion It doesn t. Two alternative... 

Most reactions of this category involve the base-induced generation of alkylidene-carbenes (R2C = C ) which undergo an intramolecular 1,5-carbon-hydrogen insertion providing a useful route for the construction of substituted cyclopentenes a competing intramolecular pathway is rearrangement to alkynes. 

Addition of a rhodium carbenoid to an alkyne leads to a cyclopropene derivative. In an intramolecular context, the fused cyclopropene moiety is unstable and undergoes ring opening to generate a rhodium vinyl carbenoid entity, which can then undergo cyclopropanation or cyclopropena-tion, carbon hydrogen insertion, and ylide generation. This is illustrated... 

Dirhodium(ll) tetrakis[methyl 2-pyrrolidone-5(R)-oarboxylate], Rh2(5R-MEPV)4, and its enantiomer, Rh2(5S-MEPY)4, which is prepared by the same procedure, are highly enantioselective catalysts for intramolecular cyclopropanation of allylic diazoacetates (65->94% ee) and homoallylic diazoacetates (71-90% ee),7 8 intermolecular carbon-hydrogen insertion reactions of 2-alkoxyethyl diazoacetates (57-91% ee)9 and N-alkyl-N-(tert-butyl)diazoacetamides (58-73% ee),10 Intermolecular cyclopropenation ot alkynes with ethyl diazoacetate (54-69% ee) or menthyl diazoacetates (77-98% diastereomeric excess, de),11 and intermolecular cyclopropanation of alkenes with menthyl diazoacetate (60-91% de for the cis isomer, 47-65% de for the trans isomer).12 Their use in <1.0 mol % in dichloromethane solvent effects complete reaction of the diazo ester and provides the carbenoid product in 43-88% yield. The same general method used for the preparation of Rh2(5R-MEPY)4 was employed for the synthesis of their isopropyl7 and neopentyl9 ester analogs. 

Metal Carbene TVansformations. The effectiveness of Rh2(55 -MEPY)4 and its 5R-form, Rh2 5R-MEPY)4, is exceptional for highly enantioselective intramolecular cyclopropanation and carbon-hydrogen insertion reactions. Intermolecular cyclopropanation occurs with lower enantiomeric excesses than with alternative chiral copper salicylaldimine or C2-symmetric semicorrin or bis-oxazoline copper catalysts, but intermolecular cyclopropenation exhibits higher enantio-control with Rh2(MEPY)4 catalysts. The methyl carboxylate attachment of Rh2(55-MEPY)4 is far more effective than steri-cally similar benzyl or isopropyl attachments for enantioselective metal carbene transformations. The significant enhancement in enantiocontrol is believed to be due to carboxylate carbonyl stabilization of the intermediate metal carbene and/or to dipolar influences on substrate approach to the carbene center. 

In the laboratory of G.A. Sulikowski, an enantioselective synthesis of a 1,2-aziridinomitosene, a key substructure of the mitomycin antitumor antibiotics, was developed. Key transformations in the synthesis involved the Buchwald-Hartwig cross-coupling and chemoselective intramolecular carbon-hydrogen metal-carbenoid insertion reaction. 

Keywords Rhodium, Carbon-Hydrogen Insertion, Cyclopropanation, Chiral, Asymmetric, Enantioselective, Intermolecular, Intramolecular, Diazocarbonyl Compounds... 

Several cyclic enol ethers are intramolccularly cyclopropanated using rhodium(II) acetate as a highly effective catalyst 1 7. When the connecting chain becomes too long (n = 2, 3, 4), carbon-hydrogen insertion of the carbenoid competes with the intramolecular [2 + 1] cycloaddition. However, when R is methyl and n is 2 or 3, cyclopropane formation is again the dominant... 

Intramolecular carbo-hydrogen insertion of carbenes generated by catalytic diazo decomposition is a facile method for carbon-carbon bond formation. Furans and derivatives thereof can be prepared by... 

Doyle MP, Ratnikav M, Liu Y. Intramolecular catalytic asymmetric carbon-hydrogen insertion reactions. Synthetic advantages in total synthesis in comparison with alternative approach. Org. Biomol. Chem. 2011 9 4007-4016. 

Like carbene insertions into carbon-hydrogen bonds, metal nitrene insertions occur in both intermolecular and intramolecular reactions.For intermole-cular reactions, a manganese(III) meio-tetrakis(pentafluorophenyl)porphyrm complex gives high product yields and turnovers up to 2600 amidations could be effected directly with amides using PhI(OAc)2 (Eq. 51). The most exciting development in intramolecular C—H reactions thus far has been the oxidative cychzation of sulfamate esters (e.g., Eq. 52), as well as carbamates (to oxazolidin-2-ones), ° and one can expect further developments that are of synthetic... 

The other type of carbamoyllithiums IIIc can also be prepared by reaction of CO with (V-lithioketimines, resulting from the addition of rert-butyllithium to aryl cyanides 10477,102. These intermediates 105 underwent selective cyclization to give 177-isoindole derivatives 10677 and six- (107)102 or seven-membered (108)102 cyclic products (Scheme 27). Compounds 107 result either by insertion of the carbene structure into the benzylic carbon-hydrogen bond, as in the case of carbamoyllithiums96, or by intramolecular protonation. 

Since the observation that Rh(II) carboxylates are superior catalysts for the generation of transient electrophilic metal carbenoids from a-diazocar-bonyls compounds, intramolecular carbenoid insertion reactions have assumed strategic importance for C-C bond construction in organic synthesis [1]. Rhodium(ll) compounds catalyze the remote functionalization of carbon-hydrogen bonds to form carbon-carbon bonds with good yield and selectivity. These reactions have been particularly useful in the intramolecular sense to produce preferentially five-membered rings. 

Intramolecular C-H insertion reactions of ( -cyclo-pentadienyl)dicarbonyliron carbene complexes can be used to prepare complex polycyclic compounds. Carbon-hydrogen bond insertion using an iron carbene was used as a key step in the synthesis of sterpurene andpentalene (Scheme 81). ... 

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