Allylic amination enantioselective

The disclosure, in 1982, that cationic, enantiopure BINAP-Rh(i) complexes can induce highly enantioselective isomerizations of allylic amines in THF or acetone, at or below room temperature, to afford optically active enamines in >95 % yield and >95 % ee, thus constituted a major breakthrough.67-68 This important discovery emerged from an impressive collaborative effort between chemists representing Osaka University, the Takasago Corporation, the Institute for Molecular Science at Okazaki, Japan, and Nagoya University. BINAP, 2,2 -bis(diphenylphosphino)-l,l -binaphthyl (Scheme 7), is a fully arylated, chiral diphosphine which was introduced in... 

Enantioselectivity (which is hnked to the regioselectivity of the attack of the nucleophile to the coordinated allyl) in the allylic amination of 1,3-diphenyl-allyl ethyl carbonate was also very low compared to the P-N system. This was attributed to the comparable fran -influence of P and NHC functionalities, leading to poor regioselec-tion of the two aUyl termini trans to the P and NHC ligands by the nucleophile [95],... 

Takasago A catalytic process for the enantioselective isomerization of allylic amines. The catalyst is a chiral rhodium complex. Used in the manufacture of (-)menthol. Named after Takasago International Corporation, the Japanese company which commercialized the process in 1983. 

Palladium complexes are general and versatile catalysts for allylic amination.1,la lh The palladium-catalyzed allylic aminations of 1,3-symmetrically disubstituted substrates, including enantioselective versions, have been widely studied.1, a h It has been important to control the regioselectivity in allylic amination of unsymmetrical substrates 1 or 2 (Equation (1)). In general, palladium-catalyzed allylic amination gives the ( )-linear product 3Tla lh regiocontrol in amination has recently attracted much attention in approaches toward the branched product 4. 

For the synthesis of heterocycles, an efficient strategy has been introduced utilizing the dual transition metal sequences (Scheme 6).11,lla The key issue is the compatibility of the two catalyst systems. Jeong et al. studied the one-pot preparation of bicyclopentenone 35 from propargylsulfonamide 33 and allylic acetate.11 This transformation includes two reactions the first palladium-catalyzed allylation of 33 generates an enyne 34 and the following Pauson-Khand type reaction (PKR) of 34 yields a bicyclopentenone 35. The success of this transformation reflects the right combination of catalysts which are compatible with each other because the allylic amination can be facilitated by the electron-rich palladium(O) catalyst and the PKR needs a Lewis-acidic catalyst. Trost et al. reported the one-pot enantioselective... 

A novel procedure for the synthesis of an indole skeleton 81 was developed by Mori s group (Scheme 13).16e,16f Enantioselective allylic amination of 78 with A-sulfonated < r/ < -bromoaniline 79 followed by Heck cyclization of 80 provided chiral indoline 81. The treatment of a cyclohexenol derivative 78 with 79 in the presence of Pd2(dba)3-GHGl3 and ( )-BINAPO gave compound 80 with 84% ee in 75% yield. Total syntheses of (—)-tubifoline, (—)-dehydrotubifoline, and (—)-strychnine were achieved from compound 80. 

Isomerization of allylic amines is another example of the application of the BINAP complex. Rh BINAP complex catalyzes the isomerization of N,N-diethylnerylamine 40 generated from myrcene 39 with 76-96% optical yield. Compound (R)-citronellal (R)-42. prepared through hydrolysis of (R)-41, is then cyclized by zinc bromide treatment.49 Catalytic hydrogenation then completes the synthesis of (—)-menthol. This enantioselective catalysis allows the annual production of about 1500 tons of menthol and other terpenic substances by Takasago International Corporation.50... 

Scheme 5 Enantioselective iridium-catalyzed hydrogenation of alkynes in the presence of N-arylsulfonyl imines to furnish trisubstituted allylic amines...

The scope of allylic electrophiles that react with amines was shown to encompass electron-neutral and electron-rich ciimamyl methyl carbonates, as well as furan-2-yl and alkyl-substituted allylic methyl carbonates. An ort/io-substituted cinnamyl carbonate was found to react with lower enantioselectivity, a trend that has been observed in later studies of reactions with other nucleophiles. The electron-poor p-nitrocinnamyl carbonate also reacted, but with reduced enantioselectivity. Allylic amination of dienyl carbonates also occur in some cases with high selectivity for formation of the product with the amino group at the y-position over the s-position of the pentadienyl unit [66]. Arylamines did not react with allylic carbonates under these conditions. However, they have been shown to react in the presence of the metalacyclic iridium-phosphoramidite catalysts that are discussed in Sect. 4. 

As previously discussed, activation of the iridium-phosphoramidite catalyst before addition of the reagents allows less basic nitrogen nucleophiles to be used in iridium-catalyzed allylic substitution reactions [70, 88]. Arylamines, which do not react with allylic carbonates in the presence of the combination of LI and [Ir(COD)Cl]2 as catalyst, form allylic amination products in excellent yields and selectivities when catalyzed by complex la generated in sim (Scheme 15). The scope of the reactions of aromatic amines is broad. Electron-rich and electron-neutral aromatic amines react with allylic carbonates to form allylic amines in high yields and excellent regio- and enantioselectivities as do hindered orlAo-substituted aromatic amines. Electron-poor aromatic amines require higher catalyst loadings, and the products from reactions of these substrates are formed with lower yields and selectivities. 

The use of ethylene adduct lb is particularly important when the species added to activate catalyst la is incompatible with one of the reaction components. Iridium-catalyzed monoallylation of ammonia requires high concentrations of ammonia, but these conditions are not compatible with the additive [Ir(COD)Cl]2 because this complex reacts with ammonia [102]. Thus, a reaction between ammonia and ethyl ciimamyl carbonate catalyzed by ethylene adduct lb produces the monoallylation product in higher yield than the same reaction catalyzed by la and [Ir(COD)Cl]2 (Scheme 27). Ammonia reacts with a range of allylic carbonates in the presence of lb to form branched primary allylic amines in good yield and high enantioselectivity (Scheme 28). Quenching these reactions with acyl chlorides or anhydrides leads to a one-pot synthesis of branched allylic amides that are not yet directly accessible by metal-catalyzed allylation of amides. 

More recently, Hartwig and coworkers reported iridium-catalyzed, asymmetric aminations of allylic alcohols in the presence of Lewis acid activators [103]. The addition of molecular sieves and Nb(OEt)5 or catalytic amounts of BPh3 activated the allylic alcohol sufficiently to allow allylic amination reactions to occur in high yield, branched-to-linear selectivity, and enantioselectivity (Scheme 29). Without the activators, only trace amounts of product were observed. 

More recently, Carreira and coworkers reported the reactions of sulfamic acid with branched allylic alcohols to form branched primary allylic amines [106]. One enantioselective reaction was disclosed, and the product was isolated in 70% ee when using a 5//-dibenzo[h, / jazepine-derived phosphoramidite with [lr(COE)2Cl]2 (Scheme 33). This reaction occurs under acidic conditions, which is incompatible with the metalacyclic catalysts. 

Another type of Cinchona alkaloid catalyzed reactions that employs azodicarbo-xylates includes enantioselective allylic amination. Jprgensen [51-53] investigated the enantioselective electrophilic addition to aUyhc C-H bonds activated by a chiral Brpnsted base. Using Cinchona alkaloids, the first enantioselective, metal-free aUyhc amination was reported using alkylidene cyanoacetates with dialkyl azodi-carboxylates (Scheme 12). The product was further functionalized and used in subsequent tandem reactions to generate useful chiral building blocks (52, 53). Subsequent work was applied to other types of allylic nitriles in the addition to a,P-unsaturated aldehydes and P-substituted nitro-olefins (Scheme 13). 

One of the landmark achievements in the area of enantioselective catalysis has been the development of a large-scale commercial application of the Rh(I)/BINAP-catalyzed asymmetric isomerization of allylic amines to enamines. Unfortunately, methods for the isomerization of other families of olefins have not yet reached a comparable level of sophistication. However, since the early 1990s promising catalyst systems have been described for enantioselective isomerizations of allylic alcohols and aUylic ethers. In view of the utility of catalytic asymmetric olefin isomerization reactions, I have no doubt that the coming years will witness additional exciting progress in the development of highly effective catalysts for these and related substrates. 

Separation of catalysts from high-value products such as fine chemicals or pharmaceuticals is often accomplished by precipitating the catalyst from the product solution. Recycling of these catalysts is feasible, provided that they do not decompose. In industry, catalyst recovery by means of catalyst precipitation is applied only in relatively small batch processes. An example of such a process is the production of (—)-menthol (id) in which an Rh-BINAP isomerization catalyst converts the allylic amine substrate into (R)-citronellal (after hydrolysis of the enamine) in high yield (99%) and with high enantioselectivity (98.5% ee). After distillation of the solvent (THF) and product, the catalyst is recovered from the residue by precipitation with -heptane. 

RHODIUM-CATALYZED ENANTIOSELECTIVE ISOMERIZATION OF ALLYLIC AMINES... 

RHODIUM-CATALYZED enantioselective isomerization of ALLYLIC AMINES 103... 

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