Rhodium-catalyzed cascade

In addition, Wu and Li recently have developed an efficient rhodium-catalyzed cascade hydrostannation/conjugate addition of terminal alkynes and unsaturated carbonyl compounds in water stereoselectively (Scheme 4.5).88... 

Diallenes undergo rhodium-catalyzed cascade carbobicyclization similar to the SiCaB reaction (see Section 4.2) [21]. For example, the reaction of diallene 87 with PhMe2SiH catalyzed by Rh(acac)(CO)2 at ambient temperature and pressure of CO gives ds-2-... 

A rhodium-catalyzed cascade reaction of a cyclobutanone with an electron-deficient alkene ... 

Copper- and rhodium-catalyzed cascade reactions in organic synthesis... 

COPPER- AND RHODIUM-CATALYZED CASCADE REACTIONS IN ORGANIC SYNTHESIS... 

Graening, T, Friedrichsen, W., Lex, J., Schmalz, H.G. (2002) FacUe Construction of the Colchicine Skeleton by a Rhodium-Catalyzed Cyclization/Cycloaddition Cascade. Angewandte Chemie International Edition, 41, 1524-1526. 

Very recently, Ma has reported a rhodium-catalyzed route to 18,19-norsteroid skeletons from bis-allenes, involving a cyclometallation-carbometallation-reductive elimination-Diels-Alder reaction cascade process.410... 

Using the catalyst system described above in combination with a rhodium phosphine catalyst Lebel reported the de novo synthesis of alkenes from alcohols [100]. They developed a one-pot process, avoiding the isolation and purification of the potentially instable aldehyde intermediate. They combined the oxidation of alcohols developed by Sigman [89] with their rhodium-catalyzed methylenation of carbonyl derivatives. The cascade process is compatible with primary and secondary aliphatic as well as benzyUc alcohols in good yields. They even added another reaction catalyzed by a NHC complex, the metathesis reaction, which has not been addressed in this review as there are many good reviews, which exclusively and in great depth describe all aspects of the reaction. 

Rhodium-catalyzed, silane-initiated cascade cyclization of 1,6,11-triynes 83 was proposed to occur via a silane-initiated cascade carbocyclization to form the silylated bicyclic triene (Z,Z)-In. / -Migratory insertion of the silylated G=G bond into the Rh-G bond of (Z,Z)-In followed by / -hydride elimination from frans-lln could then form 84a. Alternatively, cisitrans isomerization of (Z,Z)-In followed by / -migratory insertion of the silylated G=G bond into the Rh-G bond of resulting isomer ( ,Z)-In could form cis-Wn. Subsequent / -silyl elimination from m-IIn would form unsilylated tricycle 84b (Scheme 21). 

Rhodium carbonyl complexes also catalyze the cascade cyclization/hydrosilylation of 6-dodecene-l,l 1-diynes to form silylated tethered 2,2 -dimethylenebicyclopentanes. For example, reaction of ( )-85 with dimethylphenylsilane catalyzed by Rh(acac)(CO)2 in toluene at 50 °G under GO (1 atm) gave 86a in 55% yield as a single diastereomer (Equation (56)). Rhodium-catalyzed caseade cyclization/hydrosilylation of enediynes was stereospecific, and reaction of (Z)-85 under the conditions noted above gave 86b in 50% yield as a single diastereomer (Equation (57)). Rhodium(i)-catalyzed cascade cyclization/hydrosilylation of 6-dodecene-1,11-diynes was proposed to occur via silyl-metallation of one of the terminal G=G bonds of the enediyne with a silyl-Rh(iii) hydride complex, followed by two sequential intramolecular carbometallations and G-H reductive elimination. ... 

In contrast to the reactivity of 6-dodecene-1,11-diynes, rhodium-catalyzed reaction of l-dodecene-6,11-diynes with silane led not to cascade cyclization/hydrosilylation but rather to carbonylative tricyclization. For example, reaction of 87 [X = G(G02Me)2] and dimethylphenylsilane catalyzed by Rh(acac)(GO)2 in THE at room temperature under GO gave the cyclopenta[e]azulene 88 in 92% yield as the exclusive product (Scheme 22). Although the protocol was... 

Eilbracht et al. by means of rhodium-catalyzed tandem hydroformylation/acetalization of cccw-alkenediols [20]. It had been previously reported that hydroformylation of alkenol resulted in cyclic hemiacetal [21]. Starting from enediols, the authors paved the way for subsequent acetalization, leading to fused bicyclic compounds in a one-pot cascade. As expected, exclusive formation of czs-fused perhydrofuro[2,3fr]furan 6 occurred when applying 60 bar of syngas (CO H2 = 3 1) at 120 °C in dichloromethane to diol 5 in the presence of a [Rh(cod)Cl]2/PPh3 catalytic system (Scheme 4). 

In the same vein, Schmalz has proposed a facile construction of the colchicine skeleton by a rhodium-catalyzed cyclization/cycloaddition cascade [56]. A TMS group has to be introduced on the alkyne moiety of 66 in order to avoid participation of the relatively acidic alkynyl hydrogen atom in undesired proton transfers. The resulting 6,7,7 of 67a and 67b architecture was assembled in a remarkably diastereoselective manner (14 1) and in satisfactory yield (Scheme 30). 

The beauty of this method is that iterative processes can proceed and that polycyclic frameworks can be constructed. In the formal synthesis of (-)-brevisin, compound 36 was obtained by using a rhodium-catalyzed e do-selective epoxide-opening cascades. Thus, when THP 35 was treated with [Rh(CO)2Cl]2, compound 36 was formed and then transformed to primary alcohol 37 which is a precursor of (-)-brevisin (Scheme 20) (2015JA6941). 

The rhodium-catalyzed [5-1-2] cycloadditions have been used in cascade with other processes to synthesize molecules of more complexity in a single operation. The first example was reported by Martin who developed a cascade sequence involving allylic alkylation and [5-1-2] cycloaddition (see (20)) [42,43]. The catalyst [Rh(CO)2Cl]2 could be used to catalyze both the highly regioselective allylic alkylation and the following intramolecular [5-1-2] cycloaddition. As another example, Wender and co-workers combined intermolecular [5-1-2] cycloaddition with... 

Hojo, D. Tanaka, K. Rhodium-catalyzed C—H bond activation/[4-I-2 annulation/ aromatization cascade to produce phenol, naphthol, phenanthrenol, and triphenylenol derivatives. Org. Lett. 2012, 14, 1492-1495. 

The hydrosilylation of unsaturated carbon-rhodium-catalyzed silylcarbocyclizations. In the presence of Rli4(CO)i2 and triethoxysilane, a rigid triyne backbone can undergo a silylcarbotricyclization cascade reaction to yield [5,6,5]-tricycles (eq 16). Similar to the results observed by Sieburth for the hydrosilylation of enamines, the alkoxysilane functionality provides significant rate enhancement in comparison to silylcarbocyclizations using alkyl- and arylsilane reagents. The incorporation of carbonyl functionality as terminal electrophiles into these cyclizations has also been successful. Rhodium-catalyzed carbonylative silylcarbocyclizations proceed in the presence of carbon monoxide (10 atm) to incorporate a carbonyl unit, usually as the aldehyde. Both of these tandem ad-dition/cyclization strategies produce functionalized carbocycles with simultaneous incorporation of sUyl functionality as aryl- and vinylsilanes. These alkenylsilanes can then be exploited for further synthetic manipulations as discussed above. "" ... 

Scheme 7.7 Rhodium-catalyzed [2-1-2-1-2] cycloadditioii/[4-l-2] Diels-Alder cascade.

Various cyclohexadienes can be obtained through the rhodium-catalyzed cyclotrimerization of 1,6-diynes with alkenes [12] or 1,6-enynes with alkynes [13], Valorization of these cyclohexadienes was reported with the development of original tandem [2-I-2-I-2] cycloaddition/[4-l-2] Diels-Alder cascades. For example, Tanaka and coworkers recently achieved the construction of bridged polycyclic lactam products, by performing a [2-1-2-1-2] cycloaddition/[4-l-2] Diels-Alder cascade between... 

An elegant example of the cascade processes involving rhodium-catalyzed C—H bond activation is the three-component reaction of benzaldehydes, amines, and alkynes, which led to the one-pot synthesis of isoquinoUnium salts 58 (Scheme 5.39) [39], The process involves generation of imine, C—H bond activation, and annula-tion. The mechanism proposed is strongly supported by the isolation of the five-membered rhodacycle A and an intermediate (Scheme 5.40). The significance of this cascade C—H activation/annulation reaction has been demonstrated by its application to the total synthesis of the isoquinohnone alkaloid oxychelerythrine 59 with excellent yield (Scheme 5.41). 

Significant progress has been made in the fields of ruthenium-, iron-, iridium-, rhodium-, and copper-catalyzed cascade reactions. Noticeably, these transition metal catalysts are critically important in numerous commercial chemical processes. Discoveries of new cascade processes along with improvements in the activity, selectivity, and scope of these catalysts could drastically reduce the environmental impact and increase the sustainability of chemical reactions. From the viewpoint of practical applications, iron and copper are the most abundant metals on Earth and, consequently, inexpensive and environmentally friendly. Moreover, many iron and copper salts and complexes are commercially available or are described in the literature. Due to these advantages, the development and applications of iron- and copper-catalyzed cascade reactions are becoming a thriving area of organic synthesis chemistry. 

Rhodium carbonyl complexes catalyze the silane-initiated cascade cyclization of 1,6,11-triynes to form fused aromatic tricyclic compounds. For example, reaction of 83 [X = G(G02Et)2] with methyldiphenylsilane catalyzed by the tetrarhodium carbonyl cluster Rh4(GO)i2 in toluene at room temperature gave an 88 12 mixture of the silylated and unsilylated fused tricycles 84a and 84b [X = G(G02Et)2] in 85% combined yield (Equation (55)). The ratio of silylated to unsilylated tricyclic product formed in the reaction of 1,6,11-triynes was dependent on the nature of the substrate (Equation (55)). For example, Rh4(GO)i2-catalyzed reaction of diaminotriyne 83 (X = NBn) with methyldiphenylsilane gave unsilylated tricycle 84b (X = NBn) in 92% yield as the exclusive product (Equation (55)). 

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