Metallated Intermediates

Some acetylenic (with a non-terminal triple bond) or allenic compounds, RCH=C CH2, can be transformed into alkali metal derivatives of terminal acetylenes by treatment with a very strong base. Treatment of an acetylenic compound with the grouping CHjCsC- or CH3C=CCH=CH- with one equivalent of an alkali amide (preferably the soluble potassium 

Enyne systems + iCsCCH=CH2 give intractable product mixtures and tar [2], 

Reaction of 2-alkynoic acids with an excess of sodamide in hquid ammonia followed by treatment with mineral acid (after evaporation of the ammonia) gives 3-alkynoiC acids in excellent yields [183], Presumably, the 2-alkynoic acid is convened into the disodium compound of the 3-alkynoic acid via a process of proton removal and proton donation  

RCH2C=CCOOH---------- RCHO-CCOO - RCH=C=CHCOO - RC=C=CHCOO 

The same 3-alkynoic acids can also be obtained (in lower yields) by heating 2-alkynoic acids with an excess of aqueous potassium hydroxide [184]. 

---

The abundance of indium in the earth s cmst is probably about 0.1 ppm, similat to that of silver. It is found in trace amounts in many minerals, particulady in the sulfide ores of zinc and to a lesser extent in association with sulfides of copper, tin, and lead. Indium follows zinc through flotation concentration, and commercial recovery of the metal is achieved by treating residues, flue dusts, slags, and metallic intermediates in zinc smelting and associated lead (qv) and copper (qv) smelting (see Metallurgy, EXTRACTIVE Zinc and zinc alloys). 

C. W. Bird, Transition Metal Intermediates in Organic Synthesis, Logos Press, London, UK, 1968. 

Addition of carbon nucleophiles to vinylepoxides is of particular importance, since a new carbon-carbon bond is formed. It is of considerable tactical value that conditions allowing for regiocontrolled opening of vinyloxiranes with this type of nucleophiles have been developed. Reactions that proceed through fonnation of a rr-allyl metal intermediate with subsequent external delivery of the nucleophile, or that make use of a soft carbon nucleophile, generally deliver the SN2 product. In contrast, the Sn2 variant is often the major reaction pathway when hard nucleophiles are employed. In some methods a nucleophile can be delivered selectively at either the Sn2 or SN2 positions by changing the reaction conditions. 

The potential of Fischer carbene complexes in the construction of complex structures from simple starting materials is nicely reflected in the next example. Thus, the reaction of alkenylcarbene complexes of chromium and tungsten with cyclopentanone and cyclohexanone enamines allows the di-astereo- and enantioselective synthesis of functionalised bicyclo[3.2.1]octane and bicyclo[3.3.1]nonane derivatives [12] (Scheme 44). The mechanism of this transformation is initiated by a 1,4-addition of the C -enamine to the alkenylcarbene complex. Further 1,2-addition of the of the newly formed enamine to the carbene carbon leads to a metalate intermediate which can... 

Secondary bromides and tosylates react with inversion of stereochemistry, as in the classical SN2 substitution reaction.24 Alkyl iodides, however, lead to racemized product. Aryl and alkenyl halides are reactive, even though the direct displacement mechanism is not feasible. For these halides, the overall mechanism probably consists of two steps an oxidative addition to the metal, after which the oxidation state of the copper is +3, followed by combination of two of the groups from the copper. This process, which is very common for transition metal intermediates, is called reductive elimination. The [R 2Cu] species is linear and the oxidative addition takes place perpendicular to this moiety, generating a T-shaped structure. The reductive elimination occurs between adjacent R and R groups, accounting for the absence of R — R coupling product. 

Direct metallation of o-halogenophenoxyelement derivatives of silicon, tin, and phosphorus leads to an unstable metallated intermediate which undergoes a rapid 1,3-rearrangement under element-carbon bond formation. This type of reaction seems to be a general method for the synthesis of hydroxyphenyl element derivatives [1-4], We have studied the influence of different organoelement groups on the reaction pathway. The yield increases in the sequence R3Sn < R2P < RjSi P(0)(0R)2. 

In view of the extensive and fruitful results described above, redox reactions of small ring compounds provide a variety of versatile synthetic methods. In particular, transition metal-induced redox reactions play an important role in this area. Transition metal intermediates such as metallacycles, carbene complexes, 71-allyl complexes, transition metal enolates are involved, allowing further transformations, for example, insertion of olefins and carbon monoxide. Two-electron- and one-electron-mediated transformations are complementary to each other although the latter radical reactions have been less thoroughly investigated. 

The vinyl metal intermediate arising from intermolecular nucleophilic addition of an oxygen nucleophile to a metal-alkyne complex has been harnessed for further transformations prior to protonation. An example is the ruthenium-catalyzed benzannulation of 1,5-enedyines that occurs through a tandem sequence involving hydroalk-oxylation, carbometallation, and protonation (Equation (82)).293... 

In addition to /3-H elimination, olefin insertion, and protonolysis, the cr-metal intermediate has also proved to be capable of undergoing a reductive elimination to bring about an alkylative alkoxylation. Under Pd catalysis, the reaction of 4-alkenols with aryl halides affords aryl-substituted THF rings instead of the aryl ethers that would be produced by a simple cross-coupling mechanism (Equation (126)).452 It has been suggested that G-O bond formation occurs in this case by yy/z-insertion of a coordinated alcohol rather than anti-attack onto a 7r-alkene complex.453... 

In general, transition metal-catalyzed addition reactions to 1,3-dienes gave 1,4-adducts via 7t-allyl metal intermediates.23 The ar //-Markovnikov 1,2-addition mode of this reaction is therefore unusual (Scheme 17). It was noted that the configuration of the 3-olefin was retained with either ( )- or (Z)-1,3-dienes. The observation that the 3-olefin was unimportant for this reaction strongly suggests that the method could be applicable to unactivated alkenes. 

However, with allylzinc bromide the reaction afforded the vinylic metal intermediate 111 with the allyl group connected to the carbon linked to a methoxy group, which may afford a new allenic product via /3-elimination. 

Already 20 years ago, Antonova et al. proposed a different mechanism, with a more active role of the transition metal fragment [3], The tautomerization takes place via an alkynyl(hydrido) metal intermediate, formed by oxidative addition of a coordinated terminal alkyne. Subsequent 1,3-shift of the hydride ligand from the metal to the P-carbon of the alkynyl gives the vinylidene complex (Figure 2, pathway b). 

Instead of the borohydrido pinacol ester one can also use the boron dimer. Several metals, intermediates as the one shown in Figure 19.10 have been isolated. They may contain 1-3 Bpin units and 3-1 hydrides. For the mechanism... 

For further details of this reaction, the reader is referred to Chapter 9. The catalytic allylation with nucleophiles via the formation of Ti-allyl metal intermediates has produced synthetically useful compounds, with the palladium-catalyzed reactions being known as Tsuji-Trost reactions [31]. The reactivity of Ti-allyl-iridium complexes has been widely studied [32] for example, in 1997, Takeuchi idenhfied a [lrCl(cod)]2 catalyst which, when combined with P(OPh)3, promoted the allylic alkylation of allylic esters 74 with sodium diethyl malonate 75 to give branched... 

Various topics related to the production of metallated intermediates or their quenching to final products have been reviewed ... 

Various organolithium intermediates may be posmlated for the synthesis of functionalized indoles and other heterocyclic compounds, from substituted Af-allylanilines (331a-c) or the cychc analog 332, on treatment with f-BuLi. For example, in equation 81 intermediate 333, derived from 331a, was quenched with deuterium oxide. Participation of benzyne metallated intermediates, such as 334, derived from 332, is surmised in equation 82 and other processes. The products of equations 81 and 82 can be characterized by H and NMR spectra . 

The synthetic scheme for functionalized indolines shown in equation 83 assumes formation of a doubly metallated intermediate (335), derived from V,iV-diallyl-2,6-dibromo-p-toluidine, that may be quenched to the dehalogenated toluidine 336, or may undergo cyclization to 337. Quenching of 337 with trimethylchlorosilane in the presence of TMEDA leads to formation of indoline derivatives 338 and 339. Apparently a second cyclization of intermediate 337 to compound 340 is hard to accomplish . 

Deprotonation of 3-fluorotoluene 623 with n-BuLi—KOBu-f or, better, f-BuLi—KOBu-f follows the selectivity expected with these superbases and leads to metallation at the least hindered position ortho to the fluoro substituent. Trapping the metallated intermediate 624... 

Treatment of the enantiomerically enriched acyclic allylic carbonate (S)-l (97% ee) under the standard reaction conditions furnished the allylic alkylation product (S)-14 (95% ee) in 86% yield, with net retention of absolute configuration (Eq. 3). This result implies that the displacement occurs via a classical double inversion process, albeit through a configurationally stable distorted u-allyl or enyl ff+n) organorhodium intermediate. This is supported by the fact that the achiral ff-spedes iii would undoubtedly have afforded the racemate of 14 (Scheme 10.3). Additionally, the enyl (a+n) organo-metallic intermediate provides a model for the regio- and enantiospedfidty observed in the reaction. 

---