Alkynals, cyclization complexes

One of the earliest enantioselective carbon-carbon bond-forming processes catalyzed by chiral transition-metal complexes is asymmetric cyclopropanation discussed in Chapter 5, which can proceed via face-selective carbometallation of carbene-metal complexes. Some other more recently developed enantioselective carbon-carbon bond forming reactions, such as Pd-catalyzed enantioselective alkene-CO copolymerization (Chapter 7) and Pd-catalyzed enantioselective alkene cyclization (Chapter 8.7), are thought to involve face-selective carbometallation of acy 1-Pd and carbon-Pd bonds, respectively (Scheme 4.4). Similarly, the asymmetric Pauson-Khand reaction catalyzed by chiral Co complexes most likely involves face-selective cyclic carbometallation of chiral alkyne-Co complexes (Chapter 8,7). 

The reaction of two alkynes in the presence of pentacarbonyliron affords via a [2 + 2 + 1]-cycloaddition tricarbonyl(ri4-cyclopentadienone)iron complexes (Scheme 1.6) [5, 21-23]. An initial ligand exchange of two carbon monoxide ligands by two alkynes generating a tricarbonyl[bis(ri2-alkyne)]iron complex followed by an oxidative cyclization generates an intermediate ferracyclopentadiene. Insertion of carbon monoxide and subsequent reductive elimination lead to the tricarbonyl(T 4-cyclopentadienone)iron complex. These cyclopentadienone-iron complexes are fairly stable but can be demetallated to their corresponding free ligands (see Section 1.2.2). The [2 + 2 + l]-cycloaddition requires stoichiometric amounts of iron as the final 18-electron cyclopentadienone complex is stable under the reaction conditions. 

Intramolecular allene alkyne cyclizations using cobalt complexes are nonspecific and both double bonds of the allene participate in the reaction affording [4.3.0] and [3.3.0]ring systems (Scheme 260). Both inter- and intramolecnlar Pauson - Khand-type reactions have been reported using... 

As is clear from the introductory discussion, most, if not all, of the d-block transition metals are expected to participate in reactions that are related to those discussed here. In addition to the Co-based methodology mentioned earlier, some related reactions of Pd and are known. Also related are the cyclization reactions of metal-carbene complexes containing Cr, Mo, W and other transition metals with alkynes and alkenes and a recently reported Nb- or Ta-promoted diyne-alkyne cyclization reaction, which appears to be closely related to a number of previously developed alkyne cyclotrimerization reactions, such as those catalyzed by Co. Investigations of reactions involving other transition metals may prove to be important especially from the viewpoint of developing asymmetric and catalytic procedures. 

The pronounced sensitivity of alkynes to cyclization in the presence of external nucleophiles is illustrated in studies of formaldiminium ion (99) in which an alkyne and alkene compete as intramolecular ir-nucleophiles. While cyclization of (99) in water afforded 4-hydroxypiperidine (98) in 73% yield, cyclization in the presence of 10 equiv. of Nal gave vinyl iodide (100) in 76% yield (Scheme 34). It has been suggested that the mechanism of these nucleophile-promoted iminium ion-alkyne cyclizations probably involves rate-determining attack of the nucleophile on a ir-complex or bridged cation produced from reversible interaction of the iminium ion and alkyne groups. ... 

Scheme 26. Exo-endo dig cyclization modes involving nucleophilic attack of the arene upon the metal-alkyne n complex.

The more complex [2 -f 2 + 2] cycloisomerization reaction of acetylene units is also catalyzed by transition metal-alkyne n complexation and can be readily utilized for the synthesis of a variety of polysubstimted benzene derivatives in a straightforward manner (10, 352, 353). Recently, this methodology has been applied to the cyclization of 15-membered, nitrogen-containing di- and triacetylenic macrocycles. Upon coordination with Pd(0) to the triacetylenic macrocycle at ambient temperature, the ti-coordinated Pd(0) complex results. Subsequent refluxing of this species in toluene promotes cycloisomerization to the hexasubstituted arene (354) (Scheme 28). The Rh(I) [e.g., RhCl(CO)(PPh3)2] complex also catalyzes these same transformations in high (>80%) yields. 

Scheme 82. Bergman cyclization of (a) cyclic and (fo) acyclic enediynes by Ru-alkyne It complexation.

Despite the rich catalytic alkyne cyclization chemistry of Fe , there are few mononuclear ferracyclopentadienes, perhaps because of their high reactivity e.g., reduction of FeCl2[P(CH3)3]2 with Na-Hg in 2-butyne gives the blue, highly volatile and thermally unstable [(CH3)3P]4Fe[C4(CH3)4] and the cyclotrimer hexamethylbenzene . A similar blue entity IV arises when the 4-coordinate complex (dad)2Fe is exposed to dimethyl butynedioate [dad = ethanedialbis(cyclohexylimine)] . 

Palladium-catalyzed reactions have been widely investigated and have become an indispensable synthetic tool for constructing carbon-carbon and carbon-heteroatom bonds in organic synthesis. Especially, the Tsuji-Trost reaction and palladium(II)-catalyzed cyclization reaction are representative of palladium-catalyzed reactions. These reactions are based on the electrophilic nature of palladium intermediates, such as n-allylpalladium and (Ti-alkyne)palladium complexes. Recently, it has been revealed that certain palladium intermediates, such as bis-7i-allylpalladium, vinylpalladium, and arylpalladium, act as a nucleophile and react with electron-deficient carbon-heteroatom and carbon-carbon multiple bonds [1]. Palladium-catalyzed nucleophilic reactions are classified into three categories as shown in Scheme 1 (a) nucleophilic and amphiphilic reactions of bis-n-allylpalladium, (b) nucleophilic reactions of allylmetals, which are catalytically generated from n-allylpalladium, with carbon-heteroatom double bonds, and (c) nucleophilic reaction of vinyl- and arylpalladium with carbon-heteroatom multiple bonds. According to this classification, recent developments of palladium-catalyzed nucleophilic reactions are described in this chapter. 

A possible triggering complex, palladacyclopropene (B ) (Scheme 7), could be isolated (vide infra), but did not provide the cyclization product (D ) under the reaction conditions used (80-100 °C). This result indicates that the alkyne-metal complex (B ) does not initiate the present cyclization leading to the six-membered ring product (D ) via the ionic intermediate (F). 

Finally, reference is made to the remarkably facile cyclization which alkynyl Fischer carbene complexes can undergo under conditions normally leading only to alkyne-cobalt complex formation (eq 66) (M = Cr or W R=Ph or Et). 

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