Azomethines stereochemistry

Similarly, for alkenes derived from saturated methyl ketones the regioselectivity is determined by starting hydrazone ( ) (Z) ratios in some solvents but not in others. Thus 2-octanone trisylhydrazone, which is an inseparable 85 15 mixture of ( )- and (Z)-isomers, gives an 85 15 ratio of l-octene 2-octene if vinyllithium formation is carried out in THF, but a 98 2 ratio of the same products when 10% TMEDA-hexane is the solvent. The implication of this observation is that in THF the regioselectivity is determined by azomethine stereochemistry but that in TMEDA-hexane it is not. Note, however, that in this case a iyn-directing effect does not occur in TMEDA, whereas in the previous example it does. Thus more than 10 years after it was asserted that a detailed explanation of the observed solvent dependencies...await further studies owing to the complexities of the reaction system. , little headway has been made. 

The high reactivity of azomethine ylides allows addition to aromatic systems (71TL481). For example, trans-aziridine (30) adds to phenanthrene to give the fran5-phenanthropyr-rolidine (31). The reversal of expected stereochemistry is again attributed to azomethine ylide interconversion being allowed by the low reactivity of the aromatic system. 

Aroylaziridines (32) and aromatic aldehydes react to give oxazolidines (33), the stereochemistry of which suggests reaction very largely through the trans-azomethine ylide, irrespective of the aziridine configuration (70JCS(C)2383). 

Copper(II) complexes of 2,6-lutidylphenylketone thiosemicarbazone, 38, have been prepared from copper(II) chloride and copper(II) bromide [186]. Similar to 2-pyridyl thiosemicarbazones, 38-H coordinates via the ring nitrogen, the azomethine nitrogen and the thiol sulfur based on infrared spectral assignments. Magnetic susceptibilities and electron spin resonance spectra indicate dimeric complexes and both are formulated as [Cu(38-H)A]2 with bridging sulfur atoms. The electronic spectra of both halide complexes show band maxima at 14500-14200 cm with shoulders at 12100 cm S which is consistent with a square pyramidal stereochemistry for a dimeric copper(II) center. 

Dipolar addition to nitroalkenes provides a useful strategy for synthesis of various heterocycles. The [3+2] reaction of azomethine ylides and alkenes is one of the most useful methods for the preparation of pyrolines. Stereocontrolled synthesis of highly substituted proline esters via [3+2] cycloaddition between IV-methylated azomethine ylides and nitroalkenes has been reported.147 The stereochemistry of 1,3-dipolar cycloaddition of azomethine ylides derived from aromatic aldehydes and L-proline alkyl esters with various nitroalkenes has been reported. Cyclic and acyclic nitroalkenes add to the anti form of the ylide in a highly regioselective manner to give pyrrolizidine derivatives.148... 

Stereochemistry was controlled by the stereodirecting phenyl group at position 3 and by the ortho-substituents of the aromatic ring at position 10 in the azomethine imines (Equation 101) <2007T991>. 

Corsaro and co-workers studied the reaction of pyridazine, pyrimidine, and pyrazine with benzonitrile oxide and utilized H NMR spectral analysis to determine the exact structure of all the cyclized products obtained from these reactions <1996T6421>, the results of which are outlined in Table 1. The structure of the bis-adduct product 21 of reaction of pyridazine with benzonitrile oxide was determined from the chemical shifts of the 4- and 5-isoxazolinic protons at 3.76 and 4.78 ppm and coupled with the azomethine H at 6.85 ppm and with the 5-oxadiazolinic H at 5.07 ppm, respectively. They determined that the bis-adduct possessed /(-stereochemistry as a result of the large vicinal coupling constant (9.1 Hz). Similarly, the relative stereochemistry of the bis-adducts of the pyrimidine products 22-25 and pyrazine products 26, 27 was determined from the vicinal coupling constants. 

At about the same time, Wenkert and c-workers (75) reported a similar smdy into the intramolecular 1,3-dipolar cycloaddition of 2-alkenoyl-aziridine derived azomethine ylides. Thermolysis of 231 at moderate temperature (85 °C) produced 232 as a single isomer in 58% yield. Similarly, 233 furnished 234 in 67% yield. In each case, the same stereoisomers were produced regardless of the initial stereochemistry of the initial aziridine precursors. However, the reaction proved to be sensitive to both the substituents of the aziridine and tether length, as aziridines 235 and 236 furnished no cycloadducts, even at 200 °C (Scheme 3.79). 

The stereochemistry of 1,3-dipolar cycloadditions of azomethine ylides with alkenes is more complex. In this reaction, up to four new chiral centers can be formed and up to eight different diastereomers may be obtained (Scheme 12.4). There are three different types of diastereoselectivity to be considered, of which the two are connected. First, the relative geometry of the terminal substituents of the azomethine ylide determine whether the products have 2,5-cis or 2,5-trans conformation. Most frequently the azomethine ylide exists in one preferred configuration or it shifts between two different forms. The addition process can proceed in either an endo or an exo fashion, but the possible ( ,Z) interconversion of the azomethine ylide confuses these terms to some extent. The endo-isomers obtained from the ( , )-azomethine ylide are identical to the exo-isomers obtained from the (Z,Z)-isomer. Finally, the azomethine ylide can add to either face of the alkene, which is described as diastereofacial selectivity if one or both of the substrates are chiral or as enantioselectivity if the substrates are achiral. 

Unactivated dipolarophiles readily participate in intramolecular azomethine ylide cycloadditions with a more reactive azomethine ylide. Thus, flash vacuum pyrolysis of aziridine (113) afforded a 67% yield of the 5,5-fused bicyclic pyrrolidine (Scheme 34).59 A singly stabilized azomethine ylide was the apparent intermediate. Similarly, cyclization of the azomethine ylides derived from (114a-c) gave the corresponding cw-fused 6,6-bicyclic pyrrolidines in 69%, 26% and 16% yield, respectively the original double bond stereochemistry was retained in the latter two cases. 

The 1,1-cycloaddition process also occurs in nonphotolytic reactions involving azomethine ylides. Thermolysis of oxazolinone (147) led to a 3,5-fused bicyclic dihydropyrrole in 80% yield.72 The alkene stereochemistry was maintained in the product, although subsequent photolysis scrambled the methyl and trideuteromethyl groups. Nondeuterated oxazolinone gave the cyclization product which was converted to a dihydropyridine on warming with acid.74... 

Azomethine imines which contain an intervening aromatic ring between the dipole and dipolarophile are accessible from aryl aldehydes and readily undergo cyclization. Thus, imine (154), where the dipolarophile is attached at the carbon of the dipole, afforded cis- and rrans-fused tricyclic pyrazolidines in which the alkene stereochemistry was retained (Scheme 48).78 ... 

The only concern is die cis stereochemistry of die cycloadduct O. If die planar azomethine ylide adopts the least sterically hindered W geometry, then the cis isomer will be produced as a pair of enantiomers. The use of d.v-stilbenc as the dipolarophile to obtain die all-cis geometry in one step would require that only die endo transition state produces product. Although endo transitions are favored in 1,3 dipolar cycloadditions, mixtures of diastereomers from the exo and endo transition states are usually formed. Catalytic hydrogenation has a higher facial selectivity and is much more likely to give a single diastereomer. 

From the viewpoint of stereochemistry the most interesting metal complexes are the octahedrally coordinated 1 2 chromium and cobalt complex dyes, which are medially metallized azo and azomethine compounds with functional groups in the o- and o -positions. Three types of isomerism can be discriminated geometrical, N-a, 3, and that arising from azo-hydrazone tautomerism. 

The influence of the R-substituent nature on the stereochemistry of ICC of type 868 is clearly displayed in complexes of hetaryl azomethinic ligands [15,100,130,134], These chelates are mostly obtained by the method of immediate interaction of ligands and metal salts [(4.48), route A], although some cases of application of template reactions for the same goals are known [(4.48), route B], In this respect, the syntheses (4.48) are representative, described in Refs. 174 and 175 for azo-methines of 3-hydroxybenzo[6]thiophene 878 and their azine analogues, leading to chelates 879 ... 

By evaluating the character of influence of an R1-substituent on the stereochemistry of ICC of azomethinic ligands of type 868, the following two effects are usually emphasized spatial, related to volume, and coordinatively-active, caused by the presence of additional donor centers. The first one causes, in the majority of cases, distortions of tetracoordinated polyhedra the second one increases the coordination number of a metal complex-former from 4 to 5 and later to 6. Guided by these considerations, it is possible to carry out the controlled synthesis of metal complexes with a programmed geometry of the coordination unit. 

Hollingsworth and Petrow, who assumed the trans-anil (134) structure for the condensation product of aniline and 2-hydroxy-methylenecyclohexanone, found that cyclization to 7,8,9,10-tetra-hydrophenanthridine could be achieved by heating with formic acid. Since this reagent reduces azomethine bonds, it was argued that favorable stereochemistry is achieved by reduction170 and, in fact, the secondary amine (135) can be isolated.171 However, later work has shown that the anil is, in fact, cis (136) and that cyclization to... 

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