Asymmetric carbocyclization

The level of enantioselectivity was highly substrate-dependent, since even slight changes in the substrate led to decreased enantioselectivity (Tab. 11.11). 

It is worth mentioning that, in a related study, a chiral platinum complex prepared from bis(cyclooctadiene) platinum [Pt(COD)2] (5 mol %) and (f ,f )-Me-DuPhos (6mol%), also catalyzed the reaction of 63 c efficiently to provide the product (R)-65c 

The rhodium-catalyzed [m-i-n-i-1] reactions, as exemplified by the [2-t2-tl] may be accomplished with an array of substrates that have proven challenging for other metal complexes. Moreover, the ability to undertake the domino reactions significantly increases the molecular complexity and ultimately the synthetic utihty of this venerable reaction. Although the [i + 2 + 1] and [4-tl] reactions have not been as extensively studied, they will undoubtedly be the subjects of future synthetic efforts. 

15 Perez-Serrano, L. Casarrubios, L. Dominguez, G. Perez-Gastells, J. Chem. Commun. 2001, 2602. 

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Scheme 19 Asymmetric carbocyclization catalyzed by Pd(II) complexes with g em-dimethyl P,N ligand 20...

Asymmetric Pauson-Khand reaction in syntheses of heterocycles fused with five-member carbocyclic fragment 980PP121. 

Trost and co-workers have explored asymmetric transidon metal-catalyzed allylic alkyla-dons. Details on this subject have been well reviewed by Trost and others. With the use of asymmetric palladium-catalyzed desymmetrizadon of meso-2-ene-l,4-diols, cii -l,4-dibenzoy-loxy-2-cyclopentene can be converted to the enandometrically pure cii -4-rfirr-butoxycar-bamoyl-l-methoxycarbonyl-2-cyclopentene. The product is a usefid and general building block for synthesis of carbocyclic analogs of nucleosides as presented in Scheme 5.12. 

Amino-subsdnued dienes are also important dienophiles in Diels-Alder reactions Recently, chiral and achiral 2-amino-l,3-dienes have been prepared to snidy their reactivity Csee also asymmetric Diels-Alder reaction Section 8 1 2 The reaction of 2,3-diamino-l,3-butadienes v/ith nitrostyrene gives unusual [3t-2 carbocyclization products, 2-aminocyclopentanones, which are not formed by the direct cycloaddidon but derived from the Michael addidon products fsee secdon discussing the Michael addidon Secdon 4 1 3 "... 

The biomimetic approach to total synthesis draws inspiration from the enzyme-catalyzed conversion of squalene oxide (2) to lanosterol (3) (through polyolefinic cyclization and subsequent rearrangement), a biosynthetic precursor of cholesterol, and the related conversion of squalene oxide (2) to the plant triterpenoid dammaradienol (4) (see Scheme la).3 The dramatic productivity of these enzyme-mediated transformations is obvious in one impressive step, squalene oxide (2), a molecule harboring only a single asymmetric carbon atom, is converted into a stereochemically complex polycyclic framework in a manner that is stereospecific. In both cases, four carbocyclic rings are created at the expense of a single oxirane ring. 

This section describes Michael-analogous processes in which, mostly under electrophilic conditions, ally - or alkynylsilanes undergo addition to enones or dienones (Sakurai reactions). The intramolecular addition of allylsilanes is an extremely useful reaction especially for the construction of carbocyclic ring systems, which occurs in a diastereoselective manner, in many cases with complete asymmetric induction. 

The asymmetric Michael addition of chiral nonracemic ketone enolates has most frequently been used as part of the Robinson annulation methodology in the synthesis of natural products171-172. The enolates are then derived from carbocyclic chiral ketones such as (+)-nopinone, (-)-dihydrocarvone, or (-)-3-methylsabinaketone. 

Casas R., Chen Z., Diaz M., Hanafi N., Ibarzo J., Jimenez J. M., Ortuno R. M. Some Versatile and Useful Strategies for the Asymmetric Synthesis of Chiral Polyfunctional Carbocyclic Derivatives An. Quim. 1995 91 42-49... 

Hydrosilylation of dienes accompanied by cyclization is emerging as a potential route to the synthesis of functionalized carbocycles. However, the utility of cycliza-tion/hydrosilylation has been Umited because of the absence of an asymmetric protocol. One example of asymmetric cycUzation/hydrosilylation has been reported very recently using a chiral pyridine-oxazoUne ligand instead of 1,10-phenanthroline of the cationic palladium complex (53) [60]. As shown in Scheme 3-21, the pyridine-oxazoUne Ugand is more effective than the bisoxazoUne ligand in this asymmetric cyclization/hydrosilylation of a 1,6-diene. 

With the advent of enantioselective zirconocene-catalyzed alkene carbomagnesiation,27 27a 27c 28 28a chirally modified zirconocenes soon were applied to asymmetric reductive diene carbocyclization.2 a c As demonstrated by the reductive cyclization of 5a,29 highly enantioselective cyclization is enabled through the use Brintzinger s chiral, mszz-zirconocene.30 30a (For the preparation and resolution of chiral tf .szz-zirconocene 6, see Refs 30,30a.) However, moderate diastereoselectivities and yields are generally observed (Scheme 5). 

Hydrosilylation of 1,6-dienes accompanied by cyclization giving a five-membered ring system is emerging as a potential route to the synthesis of functionalized carbocycles.81,81a,81b 82 As its asymmetric version, diallylmalonates 86 were treated with trialkylsilane in the presence of a cationic palladium catalyst 88, which is coordinated with a chiral pyridine-oxazoline ligand. As the cyclization-hydrosilylation products, //ww-disubstituted cyclopentanes 87 were obtained with high diastereoselectivity (>95%), whose enantioselectivity ranged between 87% and 90% (Scheme 25).83 83a... 

The chemistry described in this review article demonstrates the impressive positive influence that catalytic RCM has had on our research in connection to the development of other catalytic and enantioselective C-C bond forming reactions. There is no doubt that in the absence of pioneering work by Schrock and Grubbs, the Zr-catalyzed alkylation and kinetic resolution would be of less utility in synthesis. The number of unsaturated heterocyclic and carbocyclic substrates available for Zr-catalyzed asymmetric carbomagnesation would be far more limited without catalytic RCM. 

Enantioselective hydrogenation of 1,6-enynes using chirally modified cationic rhodium precatalysts enables enantioselective reductive cyclization to afford alky-lidene-substituted carbocycles and heterocycles [27 b, 41, 42]. Good to excellent yields and exceptional levels of asymmetric induction are observed across a structurally diverse set of substrates. For systems that embody 1,2-disubstituted alkenes, competitive /9-hydride elimination en route to products of cycloisomerization is observed. However, related enone-containing substrates cannot engage in /9-hydride elimination, and undergo reductive cyclization in good yield (Table 22.12). 

One active field of research involving the Heck reaction is asymmetric Heck reactions (AHR). The objective is to achieve enantiomerically-enriched Heck products from racemic substrates using a catalytic amount of chiral ligands, making the process more practical and economical Although intermolecular Heck reactions that occurred onto carbocyclic arenes are rare, they readily take place onto many heterocycles including thiophenes, furans, thiazoles, oxazoles,... 

A method for highly efficient asymmetric cyclopropanation with control of both relative and absolute stereochemistry uses vinyldiazomethanes and inexpensive a-hydroxy esters as chiral auxiliaries263. This method was also applied for stereoselective preparation of dihydroazulenes. A further improvement of this approach involves an enantioselective construction of seven-membered carbocycles (540) by incorporating an initial asymmetric cyclopropanation step into the tandem cyclopropanation-Cope rearrangement process using rhodium(II)-(5 )-N-[p-(tert-butyl)phenylsulfonyl]prolinate [RhjtS — TBSP)4] 539 as a chiral catalyst (equation 212)264. 

Miscellaneous Iminium Catalyzed Transformations The enantioselective construction of three-membered hetero- or carbocyclic ring systems is an important objective for practitioners of chemical synthesis in academic and industrial settings. To date, important advances have been made in the iminium activation realm, which enable asymmetric entry to a-formyl cyclopropanes and epoxides. In terms of cyclopropane synthesis, a new class of iminium catalyst has been introduced, providing the enantioselective stepwise [2 + 1] union of sulfonium ylides and ot,p-unsaturated aldehydes.As shown in Scheme 11.6a, the zwitterionic hydro-indoline-derived catalyst (19) enables both iminium geometry control and directed electrostatic activation of sulfonium ylides in proximity to the incipient iminium reaction partner. This combination of geometric and stereoelectronic effects has been proposed as being essential for enantio- and diastereocontrol in forming two of the three cyclopropyl bonds. 

Gilbertson and co-workers were also able to facilitate the rhodium-catalyzed [4-i-2-1-2] carbocyclization reaction with a substrate having an all-carbon tether (Eq. 13). This methodology has been extended to the asymmetric rhodium-catalyzed [4-t 2-1-2] reaction (Eq. 14). Although the exact origin of asymmetric induction was not discussed, the ability to accomplish the asymmetric rhodium-catalyzed [4-i-2-1-2] reaction provides a novel approach to eight-membered ring systems. 

The asymmetric synthesis of (+)-Codeine 432 devised by White and colleagues included a Beckmann rearrangement to introduce the nitrogen atom in the carbocyclic structure (equation 182). Even though two isomeric lactams 430 and 431 were obtained as a result of the rearrangement, the preferential migration of the bridgehead carbon atom produced 430 as the predominant isomer. The synthesis of the non-natural enantiomer of Codeine was completed after oxidation, olefin formation and reduction. 

It was 1996 when Buchwald and Hicks reported the first example of an asymmetric PKR involving a catalytic amount of a chiral titanocene complex. The titanium catalyst (6 ,6 )-(EBTHI)Ti(GO)2 (EBTHI = ethylene-1,2-bis( 7 -4,5,6,7-tetrahydro-l-indenyl)) obtained in situ by treatment of (6 ,6 )-(EBTHI)TiMe2 under CO pressure was efficient for the formation of enantiomerically enriched carbocyclization adducts. ... 

The push toward enaotiomerically-pure carbocyclic intermediates has led to the development of new methods for the enantiodifferentiation of inexpensive prochiral cyclic starting materials. For instance, Robert H. Morris of the University of Toronto recently reported (Organic Lett. 2005, 7, 1757) that a family of enantiomerically-pure Ru complexes originally developed for asymmetric transfer hydrogenation also mediate the enantioselective addition of malonatc to cyclohexenone. 

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