Rhodium-catalyzed synthesis activation

Another important reaction principle in modem organic synthesis is carbon-hydrogen bond activation [159]. Bergman, Ellman, and coworkers have introduced a protocol that allows otherwise extremely sluggish inter- and intramolecular rhodium-catalyzed C-H bond activation to occur efficiently under microwave heating conditions. In their investigations, these authors found that heating of alkene-tethered benzimidazoles in a mixture of 1,2-dichlorobenzene and acetone in the presence of di-//-... 

The signature application for the G-H insertion in synthesis is probably the total synthesis of (—)-tetrodotoxin 126 by Du Bois and Hinman.233 Two stereospecific G-H activation steps, rhodium-catalyzed carbene G-H insertion and carbamate-based nitrene C-H insertion, have been used to install the two tetrasubstituted centers C6 and C8a (Scheme 12). Diazoketone 122 was treated with 1.5mol% Rh2(HNCOCPh3)4, and cyclic ketone 123 was selectively formed in high yield without purification. The reaction of carbamate 124 with 10mol% Rh2(HNCOCF3)4, PhI(OAc)4, and MgO in C6H6 solvent furnished the insertion product 125 in 77% yield. 

Optically active aldehydes are important precursors for biologically active compounds, and much effort has been applied to their asymmetric synthesis. Asymmetric hydroformylation has attracted much attention as a potential route to enantiomerically pure aldehyde because this method starts from inexpensive olefins and synthesis gas (CO/H2). Although rhodium-catalyzed hydrogenation has been one of the most important applications of homogeneous catalysis in industry, rhodium-mediated hydroformylation has also been extensively studied as a route to aldehydes. 

Hydroformylation of hetero olefins such as carbonyl compounds is not known to proceed with significant levels of efficiency, whereas the hydroformylation of olefins has been developed to a sophisticated stage. Generally, aldehydes resultant from the latter process exhibit a low propensity to undergo further hydroformylation, with the exception of some activated aldehydes. The rhodium-catalyzed hydroformylation of formaldehyde is the key step in the synthesis of ethyleneglycol from synthesis gas. Chan et al. found... 

Based on previous success in the Pauson-Khand reaction [43], Evans demonstrated a sequential approach to the synthesis of eight-membered rings, which involved a rhodium-catalyzed aUyhc amination reaction followed by carbocyclization, to effect a three-component couphng (Scheme 12.11). To date, this transformation is only the second example of a sequential rhodium-catalyzed reaction in which only temperature is used to modulate catalytic activity. 

The stmctural complexity and biological activity of the cyathane family of diterpenes has stimulated considerable interest from synthetic chemists, as reflected in the number and diversity of approaches reported thus far [42]. Our own strategy for cyathane synthesis is based on a rhodium-catalyzed [5+2] cycloaddition. The precursor for this reaction was fashioned ultimately from commercially available and inexpensive (S)-(-)-limonene. Treatment of the ketone 139 with 5 mol% [RhCl(CO)2]2 in 1,2-dichloro-ethane gave cycloadduct 140 (Scheme 13.14) in 90% yield and in analytically pure form after simple filtration through a plug of neutral alumina [43]. 

The high regio- and stereospecificity in the rhodium-catalyzed system does not seem to be compatible with the catalytic asymmetric synthesis using a chiral rhodium catalyst, and thus, there have so far been very few reports on the use of chiral rhodium catalysts for the asymmetric allylic alkylation. In 1999, Pregosin and his co-workers first reported asymmetric rhodium-catalyzed allylic alkylation of allylic esters (Equation (48)). Use of optically active... 

Mankind has produced acetic acid for many thousand years but the traditional and green fermentation methods cannot provide the large amounts of acetic acid that are required by today s society. As early as 1960 a 100% atom efficient cobalt-catalyzed industrial synthesis of acetic acid was introduced by BASF, shortly afterwards followed by the Monsanto rhodium-catalyzed low-pressure acetic acid process (Scheme 5.36) the name explains one of the advantages of the rhodium-catalyzed process over the cobalt-catalyzed one [61, 67]. These processes are rather similar and consist of two catalytic cycles. An activation of methanol as methyl iodide, which is catalytic, since the HI is recaptured by hydrolysis of acetyl iodide to the final product after its release from the transition metal catalyst, starts the process. The transition metal catalyst reacts with methyl iodide in an oxidative addition, then catalyzes the carbonylation via a migration of the methyl group, the "insertion reaction". Subsequent reductive elimination releases the acetyl iodide. While both processes are, on paper, 100%... 

Evans and Leahy reported on a method for the rhodium-catalyzed allylic alkylation using copper enolates, generated by transmetalation of the corresponding lithium enolates (equation 19). These enolates are softer and less basic nucleophiles than lithium enolates and therefore problems typically associated with enolate nncleophiles in metal-allyl chemistry can be avoided. A copper(I) enolate, derived from acetophenone derivative 63, was used as nucleophile in a regio- and stereoselective rhodinm-catalyzed alkylation of the in situ activated allylic alcohol 62. Thereby, the synthesized ketone 64, a key intermediate in the total synthesis of (—)-sugiresinol dimethyl ether (65), was produced as the only detectable regioisomer with complete conservation of enantiomeric excess. 

Preparative Methods substituted 2,3-methanoamino acids are difficult to prepare. Unfortunately, most of the reported syntheses give racemic materials whereas stereochemically pure compounds are required for studies of cyclopropane-based peptidomimetics. The only 2,3-methanologs of protein amino acids prepared in optically active form are ( )- and (Z)-cyclo-Phe and -Tyr, all four stereoisomers of cyc/o-Met, (Z)-cyclo-Arg and (25,35)-(Z)-cyc/o-Trp, although several routes to enantio-enriched 2,3-methanologs of simple nonproteogenic amino acids have been reported. " The most practical synthesis of the title compound is that based on a diastereoselective, rhodium-catalyzed cyclopropanation reaction. ... 

The catalytic activation of a C-H bond and successive insertion of CO provides new tools for organic synthesis. Hong and Yamazaki reported that the rhodium-catalyzed reaction of benzene, ethylene and carbon monoxide gives propiophenone (Eq. 11.29) [71]. 

Considerable progress has been made recently by using phosphites (general formula (R0)3P) as ligands in rhodium-catalyzed oxo synthesis. Rhodium catalysts with phosphites such as 2 and 3 showed high activities in the hydroformylation of long-chain olefins [39, 40]. 

Sawamnra, M., Hamashima, H., and Ito, Y., Rhodium-catalyzed enantioselective Michael addition of (l-cyanoethyl)phosphonate. Synthesis of optically active phosphonic acid derivatives with phosphorussubstituted quaternary asymmetric carbon center, Bull. Chem. Soc. Jpn., 73, 2559, 2000. 

An efficient asymmetric synthesis of substituted methyl 2-aryl-dihydrobenzo[h]furan-3-carlx)xylate was achieved by a rhodium-catalyzed C-H bond activation route in an excellent yield, and the generated product was an intermediate applicable to the total synthesis of (+)-lithospermic acid <0 A13496>. A similar type of framework existing in ( )-E-viniferin was m e through a biomimetic transformation by a T1(N03)3-mediated oxidative dimerization of resveratrol <05T10285>. 

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