Imines transition metal catalysts

The development of chiral phosphorus ligands has made undoubtedly significant impact on the asymmetric hydrogenation. Transition metal catalysts with efficient chiral phosphorus ligands have enabled the synthesis of a variety of chiral products from prochiral olefins, ketones, and imines in a very efficient manner, and many practical hydrogenation processes have been exploited in industry for the synthesis of chiral drugs and fine chemicals. 

In hydrogenation, early transition-metal catalysts are mainly based on metallocene complexes, and particularly the Group IV metallocenes. Nonetheless, Group III, lanthanide and even actinide complexes as well as later metals (Groups V-VII) have also been used. The active species can be stabilized by other bulky ligands such as those derived from 2,6-disubstituted phenols (aryl-oxy) or silica (siloxy) (vide infra). Moreover, the catalytic activity of these systems is not limited to the hydrogenation of alkenes, but can be used for the hydrogenation of aromatics, alkynes and imines. These systems have also been developed very successfully into their enantioselective versions. 

In summary, the reduction of ketones and aldehydes can both be performed with MPV and transition-metal complexes as catalysts. Reductions of alkenes, al-kynes, and imines require transition-metal catalysts MPV reductions with these substrates are not possible. 

Theoretical studies have been carried out on all the late transition metal catalysts la [10-13], lb [14] and lc [15] in Figure 1. It is not the objective here to review all the computational results. We shall instead describe the general mechanistic insight that has been gained from the theoretical studies with the main emphasis on Brookhart s bis-imine catalysts. The experimental work on late transition metal olefin polymerization catalysts has been reviewed recently by Ittel [16] et al. 

This chelation-assisted C-H/olefin and C-H/acetylene coupling can be applied to a variety of aromatic compounds with a directing group such as ester, aldehyde, imine, azo, oxazolyl, pyridyl, and nitrile [7]. In this section, we describe the coupling reactions of aromatic carbonyl compounds with olefins using a transition metal catalyst. 

Not only palladium, but many more non-metallocene late (and early) transition metal catalysts for the coordination polymerization of ethene and 1-olefins were reported [11]. Among the most significant findings in this area are the disclosures of novel highly active and versatile catalysts based on (i) bidentate diimine [N,N] nickel and palladium complexes [12], (ii) tridentate 2,6-bis(imino)pyridyl [N,N,N] iron and cobalt complexes [13], and (iii) bidentate salicyl imine [N,O] nickel complexes [14]. 

The asymmetric catalytic reduction of ketones (R2C=0) and imines (R2C=NR) with certain organohydrosilanes and transition-metal catalysts is named hydrosilylation and has been recognized as a versatile method providing optically active secondary alcohols and primary or secondary amines (Scheme 1) [1]. In this decade, high enantioselectivity over 90% has been realized by several catalytic systems [2,3]. Therefore the hydrosilylation can achieve a sufficient level to be a preparative method for the asymmetric reduction of double bond substrates. In addition, the manipulative feasibility of the catalytic hydrosilylation has played a major role as a probe reaction of asymmetric catalysis, so that the potential of newly designed chiral ligands and catalysts can be continuously scrutinized. 

A transition metal catalyst has also been used to effect the reductive alkylation of amino groups on proteins [41], This reaction uses [Cp Ir(4-4 -dimethoxybipy)(H20)]S04 31 as a mild transfer hydrogenation catalyst and formate ion as the stoichiometric hydride source, in Fig. 10.3-11 (a). Presumably, this reaction occurs via the reversible formation of imine 33 with free amino groups on the protein surface, followed by reduction of iridium hydride 32. For most proteins, multiple modifications are observed (Fig. 10.3-ll(b)), although the overall level of conversion can be altered through variation of either the reaction temperature or the concentrations of the aldehyde and catalyst. In general, the reaction has shown excellent reliability for protein alkylation between pH 5 and 7.4. 

One of the chief values of imines is that the carbon-nitrogen double bond can be reduced to a carbon-nitrogen single bond by hydrogen in the presence of a nickel or other transition metal catalyst. By this two-step reaction, called reductive amination, a primary amine is converted to a secondary amine by way of an imine, as illustrated by the conversion of cyclohexylamine to dicyclohexylamine ... 

Conversion of an aldehyde or a ketone to an amine is generally carried out in one laboratory operation by mixing together the carbonyl-containing compound, the amine or ammonia, hydrogen, and the transition metal catalyst. The imine intermediate is not isolated. 

The carbon-nitrogen double bond of an imine can be reduced by hydrogen in the presence of a transition metal catalyst to a carbon-nitrogen single bond ... 

Recently, Iwasawa established a set of transition metal-catalyzed protocols for an efficient construction of N l-C2-fused polycydic indole skeletons via a cycloisomerization-cycloaddition domino reaction of alkynyl imines 172 [222-224]. It was shown that the latter substrates, upon activation with transition metal catalysts, such as W(0), Pt(II), and Au(III), generate reactive azomethine ylide intermediates 174 similar to 166 (Scheme 9.64). Interception of such yUdes with a variety of suitably substituted alkenes 17S via a [3 - - 2]-cydoaddition affords fused indole products 177 through a transient formation of the corresponding metallocarbenoids 176. Transformation of terminal alkynyl imines proceeds with a 1,2-H shift in the 176, whereas... 

Asymmetric hydrosilylation of ketones and ketoimines has been demonstrated in the absence of transition metal catalysts. Using catalytic amounts of chiral-alkoxide Lewis bases such as binaphthol (BINOL), Kagan was able to facilitate the asymmetric reduction of ketones (eq 19). This process is believed to arise from activation of the triethoxysilane by mono-alkoxide addition to give an activated pentavalent intermediate, which can undergo coordination of an aldehyde. This highly ordered hexacoordinate transition state directs reduction in an asymmetric manner, with subsequent catalyst regeneration. Brook was able to facilitate a similar tactic for asymmetric reduction by employing histidine as a bi-dentate Lewis base activator of triethoxysilane. A similar chiral lithium-alkoxide-catalyzed asymmetric reduction of imines was demonstrated by Hosomi with the di-lithio salt of BINOL and trimethoxysilane. ... 

Due to the high electrophilic nature of arynes, they are excellent dipolarophiles and can add to various 1,3-dipoles, leading to the construction of a range of benzo-fused five-membered heterocycles (Scheme 2). The commonly used 1,3-dipoles are nitrones, nitrile oxides, nitrile imines, azomethine imines, azides, diazo compoxmds, etc. Most of these reactions work under mild conditions in the absence of any transition-metal catalyst. 

A variety of electrophiles are employed for carbonyl alkenylation and arylation that proceed through transmetalation from silicon to transition metal catalysts. For example, addition of alkenylsilanes and aryl(trimethoxy)si lanes to aldehydes is catalyzed by copper/DTBM-SEGPHOS, which mediates transmetalation from silicon to copper to give a wide variety of chiral alcohols with high degree of % ee (Scheme 3-144). The enantioselective alkenylation of imines using 2-(hydroxylmethyl)phenyl-substituted propen-2-ylsilane is catalyzed by a rhodium/chiral diene complex. ... 

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