Carbenes intramolecular reactions

There are several examples of intramolecular reactions of monocyclic /3-lactams with carbenes or carbenoids most of these involve formation of olivanic acid or clavulanic acid derivatives. Thus treatment of the diazo compound (106) with rhodium(II) acetate in benzene under reflux gives (107), an intermediate in the synthesis of thienamycin (80H(14)1305, 80TL2783). 

An intermolecular carbenoid reaction followed by intramolecular displacement of acetate gives the clavulanic acid derivative (112) in one step from 4-acetoxyazetidin-2-one (91) (80CC1257). Carbene-induced reactions of penicillins and cephalosporins have been reviewed (75S547, 78T1731). 

Acyclic diene molecules are capable of undergoing intramolecular and intermolec-ular reactions in the presence of certain transition metal catalysts molybdenum alkylidene and ruthenium carbene complexes, for example [50, 51]. The intramolecular reaction, called ring-closing olefin metathesis (RCM), affords cyclic compounds, while the intermolecular reaction, called acyclic diene metathesis (ADMET) polymerization, provides oligomers and polymers. Alteration of the dilution of the reaction mixture can to some extent control the intrinsic competition between RCM and ADMET. 

Structural analogues of the /]4-vinylketene E were isolated by Wulff, Rudler and Moser [15]. The enaminoketene complex 11 was obtained from an intramolecular reaction of the chromium pentacarbonyl carbene complex 10. The silyl vinylketene 13 was isolated from the reaction of the methoxy(phenyl)-carbene chromium complex 1 and a silyl-substituted phenylacetylene 12, and -in contrast to alkene carbene complex 7 - gave the benzannulation product 14 after heating to 165 °C in acetonitrile (Scheme 6). The last step of the benzannulation reaction is the tautomerisation of the /]4-cyclohexadienone F to afford the phenol product G. The existence of such an intermediate and its capacity to undergo a subsequent step was validated by Wulff, who synthesised an... 

There are numerous examples of metal carbene insertion reactions, usually requiring a catalyst. " The C—H insertion reactions of metal carbenes can be highly selective. Intramolecular insertion reactions are very versatile and tolerate a... 

Owing to the low barriers to bond formation, reactant conformation often plays a decisive role in the outcome of these reactions. Carbocations, carbene, and radicals frequently undergo very efficient intramolecular reactions that depend on the proximity of the reaction centers. Conversely, because of the short lifetimes of the intermediates, reactions through unfavorable conformations are unusual. Mechanistic analyses and synthetic designs that involve carbocations, carbenes, and radicals must pay particularly close attention to conformational factors. 

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. 

The view has been expressed that a primarily formed ylide may be responsible for both the insertion and the cyclopropanation products 230 246,249). In fact, ylide 263 rearranges intramolecularly to the 2-thienylmalonate at the temperature applied for the Cul P(OEt)3 catalyzed reaction between thiophene and the diazomalonic ester 250) this readily accounts for the different outcome of the latter reaction and the Rh2(OAc)4-catalyzed reaction at room temperature. Alternatively, it was found that 2,5-dichlorothiophenium bis(methoxycarbonyl)methanide, in the presence of copper or rhodium catalysts, undergoes typical carben(oid) reactions intermole-cularly 251,252) whether this has any bearing on the formation of 262 or 265, is not known, however. 

Ifcobs is directly proportional to pyridine concentration. Therefore a plot of kobs vs. [pyridine] is linear, with a slope (k ) equal to the second order rate constant for ylide formation, and an intercept (k0) equal to the sum of all processes that destroy the carbene in the absence of pyridine (e.g.) intramolecular reactions, carbene dimerization, reactions with solvent, and, in the case of diazirine or diazo carbene precursors, azine formation. 

Knowledge of the intramolecular product distribution may allow for the partitioning of k between competitive intramolecular reactions, but one must be certain that noncarbenic routes to the products do not compete with the carbenic pathways. In particular, we must be concerned with the possible intervention of RIES (cf. Section m.C), especially when diazirines or diazoalkanes are the carbene precursors. Again, corrections for RIES can be made to quantitate the carbenic routes see, for example, the discussion of the cyclobutylhalocarbene rearrangements (Section m.C.1). 

It has been reported that thermolysis of the bis(diazomethyl)phosphines lo leads to the formation of the diazaphospholes 64. This can be explained by either an intramolecular [2 + 3] cycloaddition process involving the diazo group, or a diazo-carbene coupling reaction. 

Electronically, the o-phenylene-linked carbenes and nifrenes are very similar to their para isomers. However, the proximity of the reactive centers in the former case allows for intramolecular reactions to take place revealing, thus, some aspects of their intrinsic chemical reactivity. o-Phenylene-linked carbenes and nifrenes are less known compared to their meta and para isomers, due to difficulties of preparing appropriate precursor molecules. From the available data, the following general remarks can be made. 

The most spectacular application of the donor/acceptor-substituted carbenoids has been intermolecular C-H activation by means of carbenoid-induced C-H insertion [17]. Prior to the development of the donor/acceptor carbenoids, the intermolecular C-H insertion was not considered synthetically useful [5]. Since these carbenoid intermediates were not sufficiently selective and they were very prone to carbene dimerization, intramolecular reactions were required in order to control the chemistry effectively [17]. The enhanced chemoselectivity of the donor/acceptor-substituted carbenoids has enabled intermolecular C-H insertion to become a very practical enantioselective method for C-H activation. Since the initial report in 1997 [121], the field of intermolecular enantioselective C-H insertion has undergone explosive growth [14, 15]. Excellent levels of asymmetric induction are obtained when these carbenoids are derived... 

Intramolecular carbene addition reactions have a special importance in the synthesis of strained ring compounds. Because of the high reactivity of carbene or carbenoid species, the formation of highly strained bonds is possible. The strategy for synthesis is to construct a potential carbene precursor, such as diazo compounds or di- or trihalo compounds, which can undergo intramolecular addition to the desired structure. Section E of Scheme 10.5 gives some representative examples. 

This reaction apparently proceeds by way of the normal phosphonate condensation product, the diazoalkylidene, which then spontaneously loses nitrogen to form the transient alkylidene car-bene. Careful work showed that, after statistical corrections were applied, the reactivity of a C-H bond toward insertion was approximately 0.003 for primary C-H bonds (methyl), 1.0 for secondary C-H bonds (methylene), 7.5 for benzylic (methylene) C-H bonds and 18.6 for tertiary C-H bonds. These relative reactivities are very similar to those previously observed for intramolecular C-H insertion by an alkylidene carbenoid generated from a vinyl bromide27. It was shown subsequently that the alkylidene carbene insertion reaction proceeds with retention of absolute configuration28. Using this approach, (l )-3-dimethyl-3-phenyl-l-cyclopentene and (i )-4-methyl-4-phenyl-2-cyclohexcnonc were prepared in high enantiomeric purity. 

Alkylcarbenes generally lack useful UV signals for LFP studies, but they can be indirectly visualized by the pyridine ylide method in which their intramolecular reactions compete kinetically with capture of the carbene by added pyridine. 

As early as 1964 Frey observed that the ratio of 1,1-dimethylcyclopropane and 2-methyl-2-butene, the products from intramolecular reactions of tert-butyl diazomethane, was strongly dependent on the method used to decompose the diazo compound (Table The response of the community of carbene chemists was... 

In a similar study, arc generated atoms were allowed to react with tert-butyl-benzene in order to use the tert-butyl group as an intramolecular trap for the carbene. This reaction gave drmethylindane-3- C (56) and 3,3-dimethyl-3-phen-ylpropene-l- C (57). The label distribution in 56 indicates that it arises from an initial insertion into an ortho C H bond to give o-tert-butylphenylcarbene (58), whUe 57 results from insertion into a methyl group C—H (Eq. 35). The fact that... 

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... 

In contrast to considerations of 50 years ago, today carbene and nitrene chemistries are integral to synthetic design and applications. Always a unique methodology for the synthesis of cyclopropane and cyclopropene compounds, applications of carbene chemistry have been extended with notable success to insertion reactions, aromatic cycloaddition and substitution, and ylide generation and reactions. And metathesis is in the lexicon of everyone planning the synthesis of an organic compound. Intramolecular reactions now extend to ring sizes well beyond 20, and insertion reactions can be effectively and selectively implemented even for intermolecular processes. 

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