Multicomponent coupling reactions

The palladium-catalyzed multicomponent coupling reactions have attracted considerable interest.12,12a 12e A reaction using allylstannane 39 and allyl chloride 40 was applied to the three-component diallylation of benzylidenema-lonitrile and its congeners by Yamamoto et al 2 Analogous diallylation of isocyanate 41 was studied by Szabo et al. (Scheme 7).12a The reaction mechanism can be explained by formation of an amphoteric bis-allylpalladium intermediate 43 which undergoes an initial electrophilic attack on one of the allyl moieties followed by a nucleophilic attack on the other. 

The same research group has further performed radical carbonylation reactions on the same microreactor system [36]. First, alkyl halides were initiated and effectively reacted with pressurized carbon monoxide to form carbonyl compounds. The principle was subsequently successfully extrapolated to the multicomponent coupling reactions. 1-Iodooctane, carbon monoxide and methyl vinyl ketone were reacted in the presence of 2,2 -azobis(2,4-dimethylvaleronitrile) (V-65) as an initiator and tributyltin hydride or tris(trimethylsilyl)silane (TTMSS) as catalyst (Scheme 15). 

Free-radical-mediated Multicomponent Coupling Reactions... 

Radicals add to unsaturated bonds to form new radicals, which then undergo addition to other unsaturated bonds to generate further radicals. This reaction sequence, when it occurs iteratively, ultimately leads to the production of polymers. Yet the typical radical polymerization sequence also features the essence of radical-induced multicomponent assembling reactions, assuming, of course, that the individual steps occur in a controlled manner with respect to the sequence and the number of components. The key question then becomes how does one control radical addition reactions such that they can be useful multicomponent reactions Among the possibilities are kinetics, radical polar effects, quenching of the radicals by a one-electron transfer and an efficient radical chain system based on the judicious choice of a radical mediator. This chapter presents a variety of different answers to the question. Each example supports the view that a multicomponent coupling reaction is preferable to uncontrolled radical polymerization reactions, which can decrease the overall efficiency of the process. 

In designing multicomponent coupling reactions, the nature of the individual components is obviously a key factor. Generally speaking, carbon radical species, such as alkyl radicals, aryl radicals, vinyl radicals, and acyl radicals are all classified as nucleophilic radicals, which exhibit high reactivity toward electron-deficient alkenes [2]. To give readers some ideas about this, kinetic results on the addition of tert-butyl and pivaloyl radicals are shown in Scheme 6.2. These radicals add to acrylonitrile with rate constants of 2.4 x 106 M-1 s 1 and 5 x 105 M-1 s-1 at... 

Multicomponent Coupling Reactions Mediated by Group 14 Radicals I 175... 

The combination of carbon monoxide with sulfonyl oxime ethers allow for a set of multicomponent coupling reactions involving consecutive Cl/Cl-type coupling, a rare class of radical multicomponent reactions. In Scheme 6.27, examples of three-, four-, and five-component coupling reactions are shown [46], In these reactions, allyltin is not incorporated into the product, but serves as an acceptor of the phenylsulfonyl radical and a source of the tributyltin radical, which delivers the radical chain. 

Multicomponent Coupling Reactions Involving Electron-transfer Processes... 

Andreana and co-workers [188] developed a one-pot method for generating molecular diversity via a multicomponent coupling reaction under microwave irradiation. The initially formed Ugi four-component coupling products gave rise to three structurally distinct scaffolds depending on the solvent effects and sterics the 2,5-diketopiperazines 137, the 2-azaspiro[4.5]deca-6,9-diene-3,8-diones 138, and the thiophene-derived Diels-Alder tricyclic lactams 139 (Scheme 107). 

Indoles could be prepared by using o-iodoacetanilides in place of the o-iodophenols in the multicomponent coupling reaction (Scheme 24). 

The radical carbonylation of an alkyl iodide in the presence of Kim s sulfonyl oxime ethers [58, 59, 60] provides a new type of multicomponent coupling reaction where plural radical Cl synthons are consecutively combined [61]. In the transformation, allyltin was used to serve as a trap of benzenesulfonyl radical which converts sulfonyl radical to a tin radical, thus creating a chain. Scheme 14 illustrates such an example, where the product was easily dehydroxylated to give the corresponding tricarbonyl compound on treatment with zinc/AcOH. The radical acylation reaction by Kim s sulfonyl oxime ethers can be conducted under irradiation with the addition of hexamethylditin. This is an alternative path for achieving a similar transformation without the use of photolysis equipment. Scheme 15 illustrates several examples where carbon monoxide and Kim s sulfonyl oxime ethers are successfully combined to create new tandem radical reaction sequences [61],... 

Bartlett proposed some early guidelines for library synthesis (a) The sequence should involve a small number of steps, (b) no more than one variable should be introduced in any step, (c) starting materials should be readily obtained with a diverse selection of substituents, and (d) cyclic, nonoligomeric structures represent the most interesting targets [18]. Furthermore, Armstrong did some early work toward libraries composed of multiple scaffolds, derived from common synthetic intermediates [19, 20]. In one case, Ugi multicomponent coupling reaction products were converted to various linear and cyclic derivatives (Fig. 9.1-4(a)). In another, squaric acid was proposed as a precursor that could be converted to multiple cyclic and polycyclic products (Fig. 9.1-4(b)) and several such transformations were demonstrated. 

Annulated pyridines have also been synthesized via a (4+2) cycloaddition strategy involving oxazole 6, which is made via a multicomponent coupling reaction in a single step <01OL877>. Acylation of 6 with a a,P-unsaturated acyl chloride is the first step in a domino reaction where an intramolecular Diels-Alder reaction is followed by a retro-Michael reaction (7-+8). 

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