Imines acyclic

Acyclic Imines 1.4.1.1.1.1. Substrate-Induced Diastereoselection Stereogenic Center at Carbon... 

Induction of asymmetry into the /J-lactam-forming process was inefficient with acyclic imines having chiral groups on the nitrogen [19] but efficient with rigid, cyclic chiral imines (Table 3). One of these was used as a chiral template to produce highly functionalized quaternary systems (Eq. 5) [34]. 

Scheme 36. The urea derivative gave similar results to the thiourea compound. Acyclic imines (mainly E isomers) and Z cyclic imines could also be used for this process (Scheme 40,91% ee) [148,152,154].

The asymmetric hydrogenation of acyclic imines with the ansa-titanocene catalyst 102 gives the chiral amines in up to 92% ee.684,685 This same system applied to cyclic imines produces the chiral amines with >97% ee values.684,685 The mechanism of these reductions has been studied 686... 

Formation of nitrones can be achieved in the first stage of a Krohnke type reaction in which p-n trosodi methy 1 an dine reacts with 2-oo-bromoacetylphenoxathiin in alkaline medium (336). The synthesis of a series of cyclic nitrones of structure (182) has been achieved by regioselective, and by an unusual [3 + 2] cycloaddition of a-nitrosostyrenes (181) to 1,3-diazabuta-l,3-dienes (180) (Scheme 2.64) (337a). Theoretical studies of the substitution effect at the imine nitrogen on the competitive [3 + 2] and [4 + 2] mechanisms of cycloaddition of simple acyclic imines with nitrosoalkenes have been reported (337b). 

A theoretical analysis of the reactions of acyclic imines with nitrosoalkenes has been presented (347). 

This catalytic system can be used for the kinetic resolution of di-substituted 1-pyrrolines, for which high ee-values are achieved for both the amine and the recovered materials, especially when they are substituted in positions 2 and 5 (Table 6.6) [111]. Moreover, it should be noted that acyclic enamines are converted with high ee-values into their corresponding amines (89-98% ee Table 6.7), which is in sharp contrast to what is obtained for acyclic imines (vide supra) [112]. 

Cyclic imines do not have the problem of syn/anti isomerism and therefore, in principle, higher enantioselectivities can be expected (Fig. 34.8). Several cyclic model substrates 6 were hydrogenated using the Ti-ebthi catalyst, with ee-val-ues up to 99% (Table 34.5 entry 5.1), whereas enantioselectivities for acyclic imines were <90% [20, 21]. Unfortunately, these very selective catalysts operate at low SCRs and exhibit TOFs <3 h-1. In this respect, iridium-diphosphine catalysts, in the presence of various additives, seem more promising because they show higher activities. With several different ligands such as josiphos, bicp, bi-... 

The Brintzinger-type C2-chiral titanocene catalysts efficiently promote asymmetric hydrogenation of imines (Figure 1.30). A variety of cyclic and acyclic imines are reduced with excellent enantioselectivity by using these catalysts. The active hydrogenation species 30B is produced by treatment of the titanocene binaphtholate derivative 30A with n-butyllithium followed by phenylsilane. 

In order to test the capability of the novel P,N-ligands 97 in asymmetric catalyses, a challenging reductive transformation, the enantioselective hydrogenation of acyclic imines [79], was chosen. Based on previous work [76], iridium was... 

Later, Olsson and coworkers proposed a general method to prepare simple acyclic imines from amides according to a two-step procedure (Scheme 37). 

A Schiff base is the common name for the (usually acyclic) imine product of the reaction of a primary aryl amine with an aldehyde or ketone. These imines are stable if there is at least one aryl group on the imino nitrogen or on the imino carbon (54). A cyclidene is generically a cyclic, multidentate imine. 

The reaction of ketocarbenoids with pyrroles leads to either substitution or cyclopropanation products, depending on the functionality on nitrogen. With N-acylated pyrrole (209) reaction of ethyl diazoacetate in the presence of copper(I) bromide generated the 2-azabicyclo[3.1.0]hex-3-ene system (210) and some of the diadduct (211 Scheme 44).162163 On attempted distillation of (210) in the presence of copper(I) bromide rearrangement to the 2-pyrrolylacetate (212) occurred, which was considered to proceed through the dipolar intermediate (213). In contrast, on flash vacuum pyrolysis (210) was transformed to the dihydropyridine (214). A plausible mechanism for the formation of (214) involved rearrangement of (210) to the acyclic imine (215), which then underwent a 6ir-electrocyclization. 

Keywords Asymmetric hydrosilylation, optically active alcohols, amines, Chiral Titanocene Catalysts, Acyclic Imines, Cyclic Imines, Chiral Rhodium Catalysts, aromatic ketones... 

Cyclic imines furnished trans products whereas acyclic imines possessing trans geometry gave cis products. 

Metalation of unsymmetrical mines. Pioneering studies on the metalation and subsequent alkylation of unsymmetrical imines indicated that the reaction occurs predominantly at the less substituted a-position.5 This pattern has since been observed generally with lithium diethylamide, LDA, and ethylmagnesium bromide. Recent studies6 indicate that the site of alkylation is independent of the alkylating group but is dependent on the substituent on the imine and particularly on the basicity of the base. Butyllithium ( -, sec-, and /-) can abstract a proton from the more substituted a-carbon of the acyclic imine 1 to some extent. In the case of the cyclic imine 2, alkylation at the more substituted position is actually the main reaction. However, only substitution at the less substituted position of the dimethylhydrazone of 2-methylcyclohexanone is observed with either LDA or jcc-butyllithium (7,126-128). 

Jacobsen et al. have also demonstrated the usefulness of this method for asymmetric hydrocyanation of cyclic imines [10]. An example is the efficient synthesis of (R)-14 in 88% yield and with 91% ee (Scheme 5.7). Thus, in addition to the hydrocyanation of acyclic imines which are mainly fc-isomcrs, Z-i mines can also be used efficiently. 

The asymmetric catalytic hydrophosphonylation is an attractive approach for the synthesis of optically active a-amino phosphonates [84]. The first example of this type of reaction was reported by the Shibasaki group in 1995 using heterobimetal-lie lanthanoid catalysts for the hydrophosphonylation of acyclic imines [85a]. This concept has been extended to the asymmetric synthesis of cyclic a-amino phosphonates [85b—d]. Very recently, the Jacobsen group developed the first organocatalytic asymmetric hydrophosphonylation of imines [86], In the presence of 10 mol% of thiourea-type organocatalyst 71, the reaction proceeds under formation of a-amino phosphonates 72 in high yield (up to 93%) and with enantioselectivity of up to 99% ee [86], A selected example is shown in Scheme 5.42. Di-o-nitrobenzyl phosphite 70 turned out to be the preferred nucleophile. 

The nature of the iminic nitrogen substituent influences the cycloaddition pathway (4 + 2 versus 3 + 2) followed in the reactions of a-nitrosoalkenes with alkyl/aryl-substituted acyclic imines.4 The problem of rotamer control in Lewis acid-catalysed 3 + 2- and 4 + 2-cycloaddition reactions of a./S-disubstituted acryloylimides was solved by the use of N-H imide templates.5... 

Marcus treatment does not exclude a radical pathway in lithium dialkyl-amide reduction of benzophenone. It does, however, seem to be excluded (Newcomb and Burchill 1984a,b) by observations on the reductions of benzophenone by N-lithio-N-butyl-5-methyl-l-hex-4-enamine in THF containing HMPA. Benzophenone is reduced to diphenylmethanol in good yield, and the amine yields a mixture of the acyclic imines no cyclic amines, expected from radical cyclization of a putative aminyl radical, were detected. An alternative scheme (17) shown for the lithium diethylamide reduction, accounts for rapid formation of diphenylmethoxide, and for formation of benzophenone ketyl under these conditions. Its key features are retention of the fast hydride transfer, presumably via the six-centre cyclic array, for the formation of diphenylmethoxide (Kowaski et al., 1978) and the slow deprotonation of lithium benzhydrolate to a dianion which disproportion-ates rapidly with benzophenone yielding the ketyl. The mechanism demands that rates for ketyl formation are twice that for deprotonation of the lithium diphenylmethoxide, and, within experimental uncertainty, this is the case. 

When the hetarene was replaced by an acyclic imine partially saturated pyrimido[4,5-t/]pyrim-idines (110) were obtained (Equation (15)) <93H(35)1055). 

Treatment of lithiated sulfoximines 48a and 49 with N-benzylideneaniline BF3 complex gave the desired adducts with only moderate to good diastereoselectivity (Table 8).49 The lithiated sulfoximine 49 failed to give adducts with other acyclic imines even when the imines were precomplexed with BF3 etherate. This is possibly a consequence of the increased steric demand and the resonance stabilizing effect of the 5-phenyl group of 49. 

The alkylation of acyclic imines with electrophilic alkenes such as acrylonitrile, methyl acrylate or phenyl vinyl sulphone is also sensitive to steric effects and again, as a consequence, only mono-alkylation occurs398. The regioselectivity of the reaction in methanol varied from 100% attack at the more substituted a-position to 70% attack at the less substituted a -position depending upon the steric inhibition manifested and the stabilization of the competing secondary enamine tautomers (vide infra) (Scheme 204). In contrast, the reaction of butanone and other methyl ketone imines with phenyl vinyl ketone occurs twice at the more substituted a-position but this is then followed by a double cyclization process (Scheme 205). Four carbon-carbon bonds are formed sequentially in this one-pot synthesis of the bicyclo[2.2.2]octanone 205 from acyclic precursors399,400. 

Similarly, (/ ,i )-f-binaphthane 103 and (7 ,i )-binaphthane 104 were obtained in one step directly from 2,2 -bis(chloromethyl)-1,1 -binaphthyl 101 and corresponding phosphines. These molecules were shown to be highly efficient chiral auxiliaries in the enantioselective hydrogenation of acyclic imines <2001AGE3425, 19990L1679>. 

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