Imines diastereoselective addition reactions

For diastereoselective addition reactions of trialkoxysilylalkynes to N tert butanesulfinyl imines, see Lettan, R.B. 

Increasing interest is expressed in diastereoselective addition of organometallic reagents to the ON bond of chiral imines or their derivatives, as well as chiral catalyst-facilitated enantioselective addition of nucleophiles to pro-chiral imines.98 The imines frequently selected for investigation include N-masked imines such as oxime ethers, sulfenimines, and /V-trimcthylsilylimines (150-153). A variety of chiral modifiers, including chiral boron compounds, chiral diols, chiral hydroxy acids, A-sull onyl amino acids, and /V-sulfonyl amido alcohols 141-149, have been evaluated for their efficiency in enantioselective allylboration reactions.680... 

Although the diastereoselective addition of nucleophiles to imines offers an attractive route to chiral amine derivatives, most chiral nonracemic imines suffer from low reactivity (electrophilicity), resulting in no reaction or competitive reduction with organometallic reagents. Other problems include enolization of aliphatic imines, poor... 

The synthesis of enantiopure amino-functionalized compounds such as a- and (3-amino acids or nonfunctionalized amines can be envisaged by the use of aldehydes, ketones, a- or (3-keto acids, or derivatives thereof as substrates for imine formation followed by, for example, diastereoselective Strecker reactions, reductions, or organometallic addition reactions. In the literature, diastereoselective syntheses based on a large variety of chiral auxiliaries, such as a-arylethylamines,4... 

Kobayashi et al. found that lanthanide triflates were excellent catalysts for activation of C-N double bonds —activation by other Lewis acids required more than stoichiometric amounts of the acids. Examples were aza Diels-Alder reactions, the Man-nich-type reaction of A-(a-aminoalkyl)benzotriazoles with silyl enol ethers, the 1,3-dipolar cycloaddition of nitrones to alkenes, the 1,2-cycloaddition of diazoesters to imines, and the nucleophilic addition reactions to imines [24], These reactions are efficiently catalyzed by Yb(OTf)3. The arylimines reacted with Danishefsky s diene to give the dihydropyridones (Eq. 14) [25,26], The arylimines acted as the azadienes when reacted with cyclopentadiene, vinyl ethers or vinyl thioethers, providing the tet-rahydroquinolines (Eq. 15). Silyl enol ethers derived from esters, ketones, and thio-esters reacted with N-(a-aminoalkyl)benzotriazoles to give the /5-amino carbonyl compounds (Eq. 16) [27]. The diastereoselectivity was independent of the geometry of the silyl enol ethers, and favored the anti products. Nitrones, prepared in situ from aldehydes and N-substituted hydroxylamines, added to alkenes to afford isoxazoli-dines (Eq. 17) [28]. Addition of diazoesters to imines afforded CK-aziridines as the major products (Eq. 18) [29]. In all the reactions the imines could be generated in situ and the three-component coupling reactions proceeded smoothly in one pot. 

Another catalytic application of chiral ketene enolates to [4 + 2]-type cydizations was the discovery of their use in the diastereoselective and enantioselective syntheses of disubstituted thiazinone. Nelson and coworkers described the cyclocondensations of acid chlorides and a-amido sulfones as effective surrogates for asymmetric Mannich addition reactions in the presence of catalytic system composed of O-TM S quinine lc or O-TMS quinidine Id (20mol%), LiC104, and DIPEA. These reactions provided chiral Mannich adducts masked as cis-4,5 -disubstituted thiazinone heterocycles S. It was noteworthy that the in situ formation of enolizable N-thioacyl imine electrophiles, which could be trapped by the nucleophilic ketene enolates, was crucial to the success of this reaction. As summarized in Table 10.2, the cinchona-catalyzed ketene-N-thioacyl-imine cycloadditions were generally effective for a variety of alkyl-substituted ketenes and aliphatic imine electrophiles (>95%ee, >95%cis trans) [12]. 

The vinylogous Mannich reaction of 2 silyloxy furans and imines may also be catalyzed through chiral Brpnsted acids, as shown by Akiyama et al. [10]. Previously, Akiyama [11] and Terada [12] had independently discovered that 3,3 substituted BINOL based phosphoric acids were excellent Bronsted acids for a broad range of mainly imine addition reactions via protonation of the imines and in situ formation of chiral iminium contact ion pairs. Using the slightly modified phosphoric acid 28 as catalyst carrying additional iodine substituents in the 6,6 positions, the y amino substituted butenolides 27 were obtained in excellent enantioselectivity and variable diastereoselectivity (Table 5.4). 

The cycloaddition of ester enolates with imines is of continuing interest and potassium rert-butoxide may be used to generate the enolate (94S805) but more usually tin, titanium or zinc enolates are employed. When enolates are generated from 2-pyridylthioesters, the stereochemistry of the tin enolate may be greater than and, in some cases, opposite to that for titanium enolates (94T5821). The effect of the lithium, zinc or titanium on the diastereoselectivity in addition reactions of the enolates of a-... 

Kaboudin and Yokomatsu reported the diastereoselective addition of a-substituted a-amino-//-phosphinates 304 to imines catalyzed by Lewis acids. Among Lewis acids, Yb(OTf)3 was found to be the best catalyst. With this catalyst the a,a -diaminophosphinic derivatives 305 were obtained with des ranging from 10% to 95%. The structure of product 305 was determined by X-ray analysis as shown in Scheme 102. The reaction proceeded with retention of configuration at the phosphorus atom [200, 201]. 

Addition to Carbonyls, Imines (Strecker-type Reactions), and Heteroaromatic Rings (Reissert-type Reactions). Cyanohydrin trimethylsilyl ethers are of significant synthetic interest as they can be transformed into a variety of multifunctional intermediates. Aldehydes and ketones can be enantioselectively converted to cyanohydrin trimethylsilyl ethers when treated with cyanotrimethylsilane in the presence of a Lewis acid and a chiral ligand. Enantioselective and/or diastereoselective formation of cyanohydrins and their derivatives has been reported and most of these reactions involve chiral ligands and metal catalysts containing Ti (eq 24), Sm (eq 25), and A1 (eq 26). ... 

By aiming at BRMs within MBFTs and organocatalysis, this section is limited to a small field of research. Nonetheless, the method is very productive, and the number of interesting examples extends far beyond the number that will be discussed in this section. Therefore, we will start, without further introduction, with the first example by Itoh and coworkers, who reported a proline-catalyzed asymmetric addition reaction for the synthesis of mf-dihydrocomynantheol in 2006 [6]. The reaction commences with activation of methyl vinyl ketone derivative 1 to form the intermediate enamine 4. Simultaneously, the acidic carboxyl group allows activation of the imine 2 and directs the newly formed nucleophile to add stereoselectively on iminium ion 5. The resulting o,p-unsaturated iminium is prone to diastereoselective cyclization by aza-Michael addition of the liberated secondary amine (Scheme 14.1). 

In the first preparations of 128 and 129, 191 reacted with TMSNCO to give adducts 192, which were transformed to cyclic imines 193 upon dehydratation. Reaction of 193 with lithium cyclopropylacetylenide gave racemic 128 and 129, which were subjected to chiral stationary phase HPLC to isolate 128 and 129 as pure enantiomers [136, 137]. Several improvements were reported for this synthetic scheme. In particular, diastereoselective additions of lithium cyclopropyl acetylenide to the derivatives of 193 containing residues of a-phenylethyl amine or campheic acid were developed [154,155]. Moreover, an enantioselective modification of this method employing amino alcohol 194 as an asymmetric catalyst was discovered [156, 157]. Another enantioselective method involved reaction of the derivatives of 193 and cyclopropyl acetylene itself, catalysed by amino alcohol derivatives (e.g. 195) and Zn(OTf)2 [158]. 

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