Enantioselectivity intramolecular reactions

Application of this catalytic process was extended to asymmetric intramolecular Diels-Alder reactions. Synthetically useful intermediates with octalin and decalin skeletons were obtained in high optical purity by use of a catalytic amount of the chiral titanium reagent [45] (Scheme 1.57, Table 1.25). The core part of the mevi-nic acids was enantioselectively synthesized by use of this asymmetric intramolecular reaction [46] (Scheme 1.58). 

The inverse electron-demand catalytic enantioselective cycloaddition reaction has not been investigated to any great extent. Tietze et al. published the first example of this class of reaction in 1992 - an intramolecular cycloaddition of heterodiene 42 catalyzed by a diacetone glucose derived-titanium(IV) Lewis acid 44 to give the cis product 43 in good yield and up to 88% ee (Scheme 4.31) [46]. 

Addition to a carbon-carbon triple bond is even more facile than addition to a carbon-carbon double bond, and there are now several reports of intermolec-ular [71] and intramolecular reactions [72-74] that produce stable cyclopropene products with moderate to high enantioselectivities. One of the most revealing examples is that shown in Scheme 9 [72] where the allylic cyclopropanation product (30) is formed by the less reactive Rh2(MEPY)4 catalyst, but macrocy-clization is favored by the more reactive Rh2(TBSP)4 and Rh2(IBAZ)4 catalysts and, as expected, the highest enantioselectivities are derived from the use of chiral dirhodium(II) carboxamidate catalysts. 

The most useful of the insertion processes is the intramolecular reactions that occur with high selectivity for the formation of five-membered ring products. The electrophilic nature of the process is suggested by C-H bond reactivity in competitive experiments (3°>20 >1°) [76, 77]. Asymmetric catalysis with Rh2(MPPIM)4 has been used to prepare a wide variety of lignans that include (-)-enterolactone (3) [8], as well as (R)-(-)-baclofen (2) [7],2-deoxyxylolactone (31) [80,81],and (S)-(+)-imperanane (32) [82].Enantioselectivities are 91-96%... 

A comparison of several of the PY and IM types of catalysts in intramolecular reactions of allylic diazoacetates led to a consistent model for the enantioselectivity. The highest e.e. values are observed for ds-substituted allylic esters. Both R and R1 are directed toward the catalyst and introduce steric interactions that detract from enantioselectivity.208... 

Rhodium(n) carboxamidates are clearly superior to all other types of catalysts in effecting highly chemo-, regio-, diastereo-, and enantioselective intramolecular C-H activation reactions of carbenoids derived from diazoacetates. Specifically, Rh2(4Y-MPPIM)4 is the catalyst of choice for C-H activation reactions of simple primary and secondary alkyl diazoacetates. Likewise, Rh2(4Y-MACIM)4 thus far has been the most successful catalyst with tertiary alkyl diazoacetates, whereas for primary acceptor-substituted diazoacetates with a pendant olefin side chain, Rh2(4A-MEOX)4 has proved to be highly selective. 

Intramolecular cyclopropanation has a noteworthy advantage. Unlike intermolecular asymmetric cyclopropanation, the intramolecular reaction produces only one diastereomer due to geometric constrains on the fused bicyclic products. Doyle has extensively studied the intramolecular enantioselective reactions of a variety of alkenyl diazoacetates catalyzed by chiral rhodium carboxamides 198 and 200 and has achieved excellent results. 

D. A. Evans, J. S. Johnson Chiral C2-Symmetric Cu(II) Complexes as Catalysts for Enantioselective Intramolecular Dids-Alder Reactions. Asymmetric Synthesis of (-)-Isopulo upone , J. Org. Chem 1997, 62,786-787. 

The aldol reaction is one of the most important reactions in synthetic organic chemistry. Many traditional ionic routes are currently available for diastereo- and enantioselective aldol reaction [97-99]. In contrast to highly basic ionic processes, development of radical methods for preparation of aldols using neutral conditions is attractive [100-102]. With the exception of intramolecular cyclization reactions, radical approaches towards aldol products remain largely unexplored [103-109]. 

An enantioselective intramolecular Pauson-Khand reaction based on chiral auxiliary-directed 7t-face discrimination in acetylenic 0-alkyl enol ether-dicobalt hexacarbonyl complexes, which proceeds with good yields and high facial diastereoselectivity, has recently been developed by M.A. Pericas, A. Moyano, A.E. Greene and their associates. The method has been applied to an enantioselective formal synthesis of hirsutene. Moreover, the process is stereodivergent and the chiral auxiliary -rran5-2-phenylcyclohexanol- is recovered in a yield as high as 92% [18]. 

Two precedent examples had been reported of the enantioselective [2+2+2] cycloaddition of alkynes. In one case, an enantioposition-selective intermolecular reaction of a triyne with acetylene generated an asymmetric carbon at the benzylic position of a formed benzene ring [19]. In the other case, an intramolecular reaction of a triyne induced helical chirality [20]. Both reactions were developed by chiral Ni catalysts. 

In 2004 and 2005, respectively, Bach and Miller independently described the use of chiral thiazolium salts as pre-catalysts for the enantioselective intramolecular Stetter reaction. Bach and co-workers employed an axially chiral A-arylthiazolium salt 109 to obtain chromanone 73 in 75% yield and 50% ee (Scheme 16) [77]. Miller and co-workers found that thiazolium salts embedded in a peptide backbone 65 could impart modest enantioselectivity on the intramolecular Stetter reaction [78]. In 2006, Tomioka reported a C -symmetric imidazolinylidene 112 that is also effective in the aliphatic Stetter reaction, providing three examples in moderate enantioselectivities (Scheme 17) [79]. 

While catalysts and reaction protocols are well established for the enantioselective intramolecular Stetter reaction, asymmetric intermolecular Stetter products are much more difficult to obtain using known methodologies. A report by Enders and co-workers described the first asymmetric intermolecular Stetter reaction utilizing n-butanal and chalcone [4], When thiazolium salt 114 is used in this system the reaction proceeds in 39% ee, albeit in 4% yield of 113. The authors comment that both thiazolium and triazolium pre-catalysts perform poorly. The yield was increased to 29% yield with thiazolium pre-catalyst 115 although a loss in enanti-oselectivity was observed (Scheme 18) [80]. 

Since the early 1990s, considerable progress has been achieved in the development of catalytic enantioselective intramolecular hydroacylation reactions of alkenes/alkynes that generate five-membered rings. Nonetheless, the vast majority of interesting hydroacylation reactions has not yet proven susceptible to effective asymmetric catalysis. This deficiency represents an exciting opportunity for future investigations in this... 

In contrast to the intermolecular cyclopropanation, the dirhodium tetraprolinates give modest enantioselectivities for the corresponding intramolecular reactions with the do-nor/acceptor carbenoids [68]. For example, the Rh2(S-DOSP)4-catalyzed reaction with al-lyl vinyldiazoacetate 32 gives the fused cyclopropane 33 in 72% yield with 72% enantiomeric excess (Eq. 4) [68]. The level of asymmetric induction is dependent upon the substitution pattern of the alkene cis-alkenes and internally substituted alkenes afford the highest asymmetric induction. Other rhodium and copper catalysts have been evaluated for reactions with vinyldiazoacetates, but very few have found broad utility [42]. 

The most spectacular application of the donor/acceptor-substituted carbenoids has been intermolecular C-H activation by means of carbenoid-induced C-H insertion [17]. Prior to the development of the donor/acceptor carbenoids, the intermolecular C-H insertion was not considered synthetically useful [5]. Since these carbenoid intermediates were not sufficiently selective and they were very prone to carbene dimerization, intramolecular reactions were required in order to control the chemistry effectively [17]. The enhanced chemoselectivity of the donor/acceptor-substituted carbenoids has enabled intermolecular C-H insertion to become a very practical enantioselective method for C-H activation. Since the initial report in 1997 [121], the field of intermolecular enantioselective C-H insertion has undergone explosive growth [14, 15]. Excellent levels of asymmetric induction are obtained when these carbenoids are derived... 

Diazoacetamides undergo intramolecular cyclopropanation with similarly high enantios-electivities (Eq. 4) [33, 36, 37]. In these cases, however, competition from intramolecular dipolar cycloaddition can compHcate the reaction process. Therefore, the use of R = Me or Bu has been required to achieve good yields of reaction products. Representative examples of applications of chiral dirhodium(II) carboxamidates for enantioselective intramolecular cyclopropanation of diazoacetamides are compiled in Scheme 15.2. 

Thus far, enantioselective intramolecular aziridination via metal nitrene intermediates has not been successful. Bromamine-T has recently been shown to be a viable source of nitrene for addition to alkenes in copper halide catalyzed reactions, " and so has iodosylbenzene (Phl=0) that forms 44 in situ. Conceptually, aziridination does not necessarily fall between cyclopropanation and epoxidation, as some have suggested. Instead, metal nitrene chemistry has unique problems and potential advantages associated with the electron pair at nitrogen that are yet to be fully overcome. 

Inter- and intramolecular reactions between a propargyiic carbocation equivalent stabilized by Co2(CO)6-coordination and enol derivatives also provide a good method for the carbon-carbon bond formation at the propargyiic carbon of propargyiic alcohols and their derivatives. Many diastereoselective and enantioselective propargyiic alkylation reactions at the propargyiic position take place between chiral propargyiic cation equivalents and enol derivatives. 

Hashimoto and co-workers, on the other hand, studied the intramolecular reaction between cyclic carbonyl yield and dimethyl acetylenedicarboxylate (DMAD) (Equation (14)). With dirhodium(ii) tetrakis[A-benzene-fused phthaloyl-(A)-valinate] [Rh2(WBPTV)4] 104, high enantioselectivity (68-92% ee) was achieved over a range of diazo substrates.The high level of enantiocontrol provided conclusive evidence that chiral Rh(ii) catalyst is associated with the ylide in the cycloaddition step. 

It is interesting to note that the oxa-analogous Michael addition was reported for the first time in 1878 by Loydl et al. [19] in their work on the synthesis of artificial malic acid, which was five years ahead of the discovery of the actual Michael reaction described first by Komnenos [20], Claisen [21], and later Michael in 1887 [22] as one of the most important methods for C—C bond formation. In continuation of the early work on the oxa-Michael addition [23], the inter- and intramolecular additions of alkoxides to enantiopure Michael acceptors has been investigated, leading to the diastereo- and enantioselective synthesis of the corresponding Michael adducts [24]. The intramolecular reaction has often been used as a key step in natural product synthesis, for example as by Nicolaou et al. in the synthesis of Brevetoxin B in 1989 [25]. The addition of oxygen nucleophiles to nitro-alkenes was described by Barrett et al. [26], Kamimura et al. [27], and Brade and Vasella [28]. 

Certain unsaturated aldehydes may be converted to cyclic ketones by a related mechanism. The formyl group reacts with Rh(I) complexes to form an acyl-Rh hydride species, which undergoes intramolecular reaction with the olefinic linkage present in the same molecule (117a). Asymmetric induction is observed with a chiral diphosphine ligand (Scheme 53) (117b-d). Enantioselective cyclization of 4-substituted 4-pentanals into 3-substituted cyclopentanones in greater than 99% ee is achieved with a cationic BINAP-Rh complex. 

The potential of the enantioselective intramolecular 1,3-dipolar cycloaddition was first described by Hodgson in the intramolecular version shown in Eq. (25). The Rh2(S-DOSP)4-catalyzed reaction of the diazoacetatoacetate 44 generated the tricyclic product 45 in 53% ee [38], but in a more recent study using the binaphthylphosphate catalyst Rh2(R-DDNP)4 (6b) the tricyclic product was formed in 90% ee [11]. 

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