Amino-allenes, hydroamination

While effective bimetallic catalyst design has the potential to lead to an enhancement of the reaction rate, the use of chiral bimetallic catalysts has also been explored to enhance the enantioselectivity of a reaction. Such bimetallic chiral induction is excellently demonstrated by the use of digold catalysts for the hydroamination of prochiral substrates such as allenes and alkenes [59]. The bimetallic Au catalyst 66, for example, was shown to be an effective catalyst for the hydroamination of amino-allenes in the presence of a silver salt activator (Scheme 24) [106]. The highest enantioselective induction for this reaction was achieved with a 1 1 ratio of AgBp4 to 66 (51 % ee) suggesting that the monocationic... 

Scheme 24 Different reactivities and selectivities of chiral bimetallic Au complexes used in the enantioselective hydroamination reaction of amino-allenes...

Asymmetric hydroamination has made a significant contribution toward the synthesis of chiral cyclic amines. Intramolecular asymmetric hydroamination of amino alkenes, amino alkynes, and amino allenes has been extensively studied to develop interesting strategies for the synthesis of chiral cyclic amines. 

It has been proposed that Au-catalyzed asymmetric hydroamination/cyclization of amino-allenes proceeds through a catalytic cycle demonstrated in Scheme 39.3. The chiral Au-complex activates the allenes generating the complex A, which is attacked by nitrogen to form species B. Species B upon protonolysis releases the product and regenerates the catalyst. 

SCHEME 39.3. Mechanism of hydroamination/cyclization of amino-allenes with Au-complexes. ... 

To meet the demand, the compound has been successfully synthesized by hydroamination/ cyclization of amino-allene 13" ° (Scheme 39.7). Enantio-selective addition of n-dibutyl zinc to allenyl aldehyde 10 using a chiral Ti catalyst (generated by heating the mixture of 11 and Ti(Ot-Pr)4 in dry toluene at 40-45 °C for 30 minutes) provides the corresponding hydroxyl... 

Hydroamination of Allenes Different related amines can also be cyclized. The use of free amino groups led to long reaction times (several days), but sulfonamides, acetyl or BOc as protecting group led to fast conversion (in the latter case, problems of diastereoselectivity were observed). Optimization studies showed that, although cationic gold (I) complexes were not effective for these conversions, AuCI was a very good catalyst for these reactions. 

Phenyl-1-propyne (55) underwent facile formal intermolecular hydroamination, affording the allylic amine 56 in high yield at 0 "C in the presence of AcOH or benzoic acid. In this reaction, at first, Pd-catalyzed isomerization of 55 to pheny-lallene (57) occurs by addition-elimination of H-Pd-OAc to internal alkyne 55, and then the allene 57 is converted to jr-allylpalladium intermediate 58 by hydropal-ladation. The final step is a well-known amination to produce the allylic amine 56. As an intramolecular version, 2-(2-phenylpropenyl)pyrrole (60) was obtained from l-phenyl-7-amino-l-hexyne 59 [16,16a]. Similarly Pd/benzoic acid-catalyzed hydroalkoxylation of 55 with (—)-menthol (61) afforded the allylic ether 62 [17]. 

In the hydroamination of unsaturated carbon-carbon bonds, gold catalysts play an important role. Intermolecular hydroamination of alkenes [177], 1,3-dienes [204], terminal and internal alkynes [205], and allenes [206] are known to proceed smoothly in the presence of PhsP AufI) or AuCls catalyst. In addition, amino olefins also efficiently undergo intramolecular hydroamination using similar gold catalysts. He and coworkers have developed the catalytic cycloaddition of tosylated amino olefins [207], A representative example is shown in Scheme 18.35. When N-tosylated y-amino olefin (97) is exposed to a mixture of PhsP AuCl and AgOTf (5 mol% each) in toluene at 85 °C, pyrrolidine (98) is obtained in 96% yield. The gold(I)-catalyzed intramolecular hydroamination is applicable to N-alkenyl carbamates [208], N-alkenyl carboxamides [209], and N-alkenyl ureas [210], The use of microwave irradiation results in completing the hydroamination in a much shorter time than that required under thermal reaction conditions [211], The... 

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