Carbene insertions intermolecular

Owing to the high reactivity of the intermediates involved, intermolecular carbene insertion reactions are not very selective. The distribution of products from the photolysis of diazomethane in heptane, for example, is almost exactly that expected on a statistical basis.211... 

Many of the limitations of C—C bond formation by C —H insertion outlined for intermolecular reactions (Section 1.2.1.) can be overcome by making the reaction intramolecular. Thus, hydrogen atom abstraction followed by intramolecular radical-radical coupling or radical addition to an alkene are increasingly popular processes. Two-electron carbene insertions, either thermal or transition metal catalyzed, have also been used extensively. In either case, ring construction involves net C—C bond formation at a previously unactivated C-H site. 

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... 

This is a major route of decomposition of ethyl 2-furyldiazoacetate (%) (R = H, = C02Et) when heated in dichloromethane or methanol (74JOC2939). The same type of decomposition has been observed with other 2-furylcarbenes which were generated by decomposition of the sodium salts of tosylhydrazones at 3(X)°C (78JA7927). Thermolysis of the diazo compound 96 (R = R = H) in cyclooctane or styrene gave, besides the open-chain acetylene 97, products of intermolecular carbene insertion. This led the authors to favor the carbene mechanism of ring-opening (path A in Scheme 7). 

Usually, carbon-carbon bonds are formed by coupling two carbons each of which are already functionalized in some way, as with the displacement of a C-Br with NaCN to form C-CN. It would be more efficient, and potentially less expensive and less polluting, if one of the partners could be an ordinary C-H bond. Intramolecular processes for carbene insertion into unactivated C-H bonds have been known for years. Practical intermolecular processes for C-C bond formation to a C-H bond are just starting to appear. 

Claisen condensation equivalent, 10, 174 Claisen rearrangement equivalent, 10, 176 enolate alkylation equivalent, 10, 171 Mannich reaction equivalent, 10, 174 as strategic reaction, 10, 171 intermolecular carbene insertion, C-H activation-Cope rearrangement characteristics, 10, 177 as strategic reaction, 10, 178 tandem aldol reaction-siloxy-Cope rearrangement equivalent, 10, 181... 

A transition metal catalyzed synthesis of ethers by carbene insertion into the O—bond has been reported. Not only saturated but also unsaturated alcohols can be utilized in this catalytic process. ° Intermolecular and intramolecular oxirane ring opening reactions by alkoxides and phenoxides also provide efficient and stereospecific preparations of acyclic and cyclic ethers. The procedures have been surveyed in detail. ... 

If a carbene is generated under aqueous conditions or in the presence of an alcohol, e.g. by deamination of (V-nitroso-Ai -cyclopropylurea ° or thermal decomposition of 1-bromo-l-trimethylstannylcyclopropanes, cydopropanols or alkyl cyclopropyl ethers are inevitably formed, sometimes in fairly high yield, by solvent trapping of the carbene. This reaction, formally an intermolecular carbene insertion, is potentially a useful tool in mechanistic... 

Intermolecular carbene-insertion reactions are seldom desirable synthetic reactions. The reason is that most carbenes are not selective, and all types of C-H bonds react at comparable rates, leading to product mixtures. The distribution of insertion product from heptane, for example, is almost exactly what would be calculated on a... 

One important advantage of the intermolecular carbene insertion reactions is that simple starting materials can be employed and accordingly there is no need for the construction of complex substrates in advance. However, the intermolecular process requires a delicate balance between electronic and steric effects for metal carbenoids. On the other hand, there are several obstacles to be overcome, including chemo-, regio-, and enantioselectivity. Fortunately, great efforts have been devoted in the past decade and a series of carbene precursors and chiral Rh catalysts have been developed, so satisfactory yields and ee can be obtained in some catalytic systems. Generally, suitable carbene precursors, such as donor/acceptor diazo compounds, could reduce the chance of side product formation due to carbene dimerization. 

The first ruthenium porphyrin-catalyzed intramolecular carbenoid C - H insertion to afford selectively cis-2,3-disubstituted-2,3-dihydroergocornine using tosylhydrazone salts as the carbene source was reported by Zheng et al. [192]. This general strategy was applied in natural product synthesis to provide a route to the total synthesis of racemic epi-conocarpan. Enantio-selective synthesis of 2,3-dihydrobenzofurans was also achieved by a similar route using chiral ruthenium porphyrins as catalysts for this interesting carbon-carbon bond formation [193]. Recently, it was found that dinuclear fx-oxo osmium porphyrins are able to catalyze intermolecular carbene insertion into C - H bonds in cyclohexene [153]. 

The sixth example in Table 6.6, carbene insertion into an adjacent C-H sigma (a) bond, is representative of the gas-phase reaction of carbenes. Indeed, since this intramolecular reaction effectively competes with the intermolecular addition of carbenes to alkenes seen earlier, the intermolecular process (Scheme 6.47) is best examined when no a-hydrogens are available in the carbene. 

Successful conditions for intermolecular carbene insertions into alkane C-H bonds with diazo esters have been reported under Ag(I) and Ir(III) catalyses. While the argen-tate trinuclear cluster (90) has been shown to catalytically promote such C-H insertion with ethyl diazoacetate, " Ir(III)-based porphyrin catalyst (91) appeared much more efficient using bulky methyl 2-phenyldiazoacetate as an alternative carbene source. Ir(III)-based porphyrin analogue (92) bearing chiral arms promotes carbene insertion with up to 98% yield in an asymmetric manner (up to 98% ee). ... 

The strained bicyclic carbapenem framework of thienamycin is the host of three contiguous stereocenters and several heteroatoms (Scheme 1). Removal of the cysteamine side chain affixed to C-2 furnishes /J-keto ester 2 as a possible precursor. The intermolecular attack upon the keto function in 2 by a suitable thiol nucleophile could result in the formation of the natural product after dehydration of the initial tetrahedral adduct. In a most interesting and productive retrosynthetic maneuver, intermediate 2 could be traced in one step to a-diazo keto ester 4. It is important to recognize that diazo compounds, such as 4, are viable precursors to electron-deficient carbenes. In the synthetic direction, transition metal catalyzed decomposition of diazo keto ester 4 could conceivably furnish electron-deficient carbene 3 the intermediacy of 3 is expected to be brief, for it should readily insert into the proximal N-H bond to... 

One of the most dramatic recent developments in metal carbene chemistry catalyzed by dirhodium(II) has been demonstration of the feasibility and usefulness of intermolecular carbon-hydrogen insertion reactions [38, 91]. These were made possible by recognition of the unusual reactivity and selectivity of aryl- and vinyldiazoacetates [12] and the high level of electronic control that is possible in their reactions. Some of the products that have been formed in these reactions, and their selectivities with catalysis by Rh2(S-DOSP)4, are reported in Scheme 10. 

Interestingly, [Ee(F20-TPP)C(Ph)CO2Et] and [Fe(p2o-TPP)CPh2] can react with cyclohexene, THF, and cumene, leading to C-H insertion products (Table 3) [22]. The carbenoid insertion reactions were found to occur at allylic C-H bond of cyclohexene, benzylic C-H bond of cumene, and ot C-H bond of THF. This is the first example of isolated iron carbene complex to undergo intermolecular carbenoid insertion to saturated C-H bonds. 

These reactions have very low activation energies when the intermediate is a free carbene. Intermolecular insertion reactions are inherently nonselective. The course of intramolecular reactions is frequently controlled by the proximity of the reacting groups.113 Carbene intermediates can also be involved in rearrangement reactions. In the sections that follow we also consider a number of rearrangement reactions that probably do not involve carbene intermediates, but lead to transformations that correspond to those of carbenes. 

There is some increase in selectivity with functionally substituted carbenes, but it is still not high enough to prevent formation of mixtures. Phenylchlorocarbene gives a relative reactivity ratio of 2.1 1 0.09 in insertion reactions with i-propylbenzene, ethylbenzene, and toluene.212 For cycloalkanes, tertiary positions are about 15 times more reactive than secondary positions toward phenylchlorocarbene.213 Carbethoxycarbene inserts at tertiary C—H bonds about three times as fast as at primary C—H bonds in simple alkanes.214 Owing to low selectivity, intermolecular insertion reactions are seldom useful in syntheses. Intramolecular insertion reactions are of considerably more value. Intramolecular insertion reactions usually occur at the C—H bond that is closest to the carbene and good yields can frequently be achieved. Intramolecular insertion reactions can provide routes to highly strained structures that would be difficult to obtain in other ways. 

The most common rearrangement reaction of alkyl carbenes is the shift of hydrogen, generating an alkene. This mode of stabilization predominates to the exclusion of most intermolecular reactions of aliphatic carbenes and often competes with intramolecular insertion reactions. For example, the carbene generated by decomposition of the tosylhydrazone of 2-methylcyclohexanone gives mainly 1- and 3-methylcyclohexene rather than the intramolecular insertion product. 

Chapter 10 considers the role of reactive intermediates—carbocations, carbenes, and radicals—in synthesis. The carbocation reactions covered include the carbonyl-ene reaction, polyolefin cyclization, and carbocation rearrangements. In the carbene section, addition (cyclopropanation) and insertion reactions are emphasized. Recent development of catalysts that provide both selectivity and enantioselectivity are discussed, and both intermolecular and intramolecular (cyclization) addition reactions of radicals are dealt with. The use of atom transfer steps and tandem sequences in synthesis is also illustrated. 

Similar to the intramolecular insertion into an unactivated C—H bond, the intermolecular version of this reaction meets with greatly improved yields when rhodium carbenes are involved. For the insertion of an alkoxycarbonylcarbene fragment into C—H bonds of acyclic alkanes and cycloalkanes, rhodium(II) perfluorocarb-oxylates 286), rhodium(II) pivalate or some other carboxylates 287,288 and rhodium-(III) porphyrins 287 > proved to be well suited (Tables 19 and 20). In the era of copper catalysts, this reaction type ranked as a quite uncommon process 14), mainly because the yields were low, even in the absence of other functional groups in the substrate which would be more susceptible to carbenoid attack. For example, CuS04(CuCl)-catalyzed decomposition of ethyl diazoacetate in a large excess of cyclohexane was reported to give 24% (15%) of C/H insertion, but 40% (61 %) of the two carbene dimers 289). 

Rh2(OAc)4 has become the catalyst of choice for insertion of carbene moieties into the N—H bond of (3-lactams. Two cases of intermolecular reaction have been reported. The carbene unit derived from alkyl aryldiazoacetates 322 seems to be inserted only into the ring N—H bond of 323 246). Similarly, N-malonyl- 3-lactams 327 are available from diazomalonic esters 325 and (3-lactams 326 297). If, however, the acetate function in 326 is replaced by an alkylthio or arylthio group, C/S insertion rather than N/H insertion takes place (see Sect. 7.2). Reaction of ethyl diazoacetoacetate 57b with 328 also yields an N/H insertion product (329) 298>, rather than ethyl l-aza-4-oxa-3-methyl-7-oxabicyclo[3.2.0]hex-2-ene-2-earboxylate, as had been claimed before 299). 

Accordingly, a re-examination of the benzylchlorocarbene system was performed, with close attention paid to the products formed at low temperature.71 Carbene 10a was photolytically generated from diazirine 9a in isooctane, methylcyclohexane, and tetrachloroethane at temperatures ranging from 30 to —75°C. At —70°C in isooctane, the products included 47% of P-chlorostyrenes 11a and 12a, 2.4% of a-chlorostyrene (49), 2% of dichloride 50, 5.5% of a C-H insertion product of 10a and isooctane, 4% of the dimers of 10a, and 30% of azine 48.71 The sum of the intermolecular products at —70°C was thus 41.5%, of which azine was the principal component. 

The fruitful relationship between experiment and theory has pushed carbene chemistry further toward the direction of reaction control that is, regio- and stereoselectivity in intra- and intermolecular addition and insertion reactions. The interplay between experiment and modem spectroscopy has led to the characterization of many carbenes that are crucial to both an understanding and further development of this held. 

An alternative strategy for selective intermolecular G-H insertions has been the use of rhodium carbenoid systems that are more stable than the conventional carbenoids derived from ethyl diazoacetate. Garbenoids derived from aryldiazoacetates and vinyldiazoacetates, so-called donor/acceptor-substituted carbenoids, have been found to display a very different reactivity profile compared to the traditional carbenoids.44 A clear example of this effect is the rhodium pivalate-catalyzed G-H insertion into cyclohexane.77 The reaction with ethyl diazoacetate gave the product only in 10% yield, while the parallel reaction with ethyl phenyldiazoacetate gave the product in 94% yield (Equation (10)). In the first case, carbene dimerization was the dominant reaction, while this was not observed with the donor/acceptor-substituted carbenoids. 

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