Azomethine imines generation

Pyrrolo annulated triazine 77 was prepared (88TL4415) by the [6 + 4]-cycloaddition of azoniafulvene ion 76 with azomethine imines generated from benzylidene phenylhydrazone (Scheme 19). 

Similarly, Yli-Kauhaluoma and co-workers have studied the 1,3-dipolar cycloaddition of polymer-bound alkynes to azomethine imines, generated in situ from A-ami nopyridine iodides, in the synthesis of pyrazolopyridines <06JCC344>. 

A convenient one-step transformation of primary and secondary amines into the corresponding unprotected guanidines using 4-benzyl-3,5-dimethyl-l/f-pyrazole-l-carboxamidine 90 and its polymer-bound variant were described <06S461>. 1,3-Dipolar cycloaddition of polymer-bound alkynes to azomethine imines generated in situ from N-aminopyridine iodides followed by aromatization of the cycloadducts gave polymer-bound pyrazolopyridines that were released from the resin as carboxylic acids with trifluoroacetic acid or as methyl esters with sodium methoxide <06JCO344>. 

Another approach is based on using the 1,3-azomethine imines, generated by deprotonation of the corresponding triazolo[4,3- ][l,2,4]-triazine aryliminium salts. These 1,3-dipoles are capable of reacting with fumaric and maleic esters to give the expected 1,3-cycloadducts in a stereoselective manner (Scheme 101) <2005H(65)1889>. 

Pyrazolopyridines were synthesized from various resin-bound alkynes and azomethine imines generated in situ in solution (Scheme 11.20). Ester-linked products were cleaved with trifluoroacetic acid or sodium methoxide, and the products were obtained as carboxylic acids or methyl esters, respectively. 

Maruoka and co-workers reported the first catalytic asymmetric three-component 1,3-dipolar cycloaddition of terminal alkynes with acyclic azomethine imines generated in situ from the corresponding aldehydes and hydrazides, which was realized using CuOAc/Ph-pybox and axially chiral dicarboxylic acid cocatalysts (Scheme 27) [48]. This transformation has abroad tolerance with regard to the substrates, affording diverse chiral 3,4-disubstituted pyrazolines with high enantioselectivities. The role of the axially chiral dicarboxylic acid is to generate the protonated acyclic azomethine imine, which then reacts with chiral Cu-acetylide. 

Scheldt and Chan have shown that NHC promoted homoenolate formation and addition to azomethine imines 37 generates pyridazinones 41 with high diastereoselectivity, via a proposed highly organised transition state 40 due to a key hydrogen bonding interaction (Scheme 12.6) [12]. 

Addition of A-mesityl benzimidazolyl carbene 720 to an a,/3-unsaturated aldehyde generates a homoenolate intermediate that undergoes an addition/acylation sequence with azomethine imine 719 to afford (3R, 5S, 6S )-177-pyrazolo[l,2- ]pyridazine-l,8(5//)-diones 721 with excellent diastereoselectivity. Compound 721 (Ar = R = Ph) treated with sodium hydoxide in methanol or benzylamine provided nearly quantitatively, ring-opened products 722a and 722b, respectively (Scheme 116) <2007JA5334>. 

The scope of these reactions has not yet been thoroughly investigated. The examples listed in Table 4.17 suggest that azomethine ylides generated by intramolecular, carbene-mediated N-alkylation of imines enable convergent and fast... 

In situ generation of azomethine imines from furan-3-carbaldehyde and ]V,N -disubstituted hydrazines followed by cycloaddition to N-methylmaleimide results in a 2.8 1 mixture of pyrazolidines 94 and 95 (X = O) separatable by chromatography. Eurther Pd(0) catalyzed cyclization involving the aldehyde and hydrazine moieties leads to the formation of benzoxepines 96 and 97 (X = O) in good yield (Scheme 17 (2003X4451)). 

Alkylidene-phosphapyrazolines 98-101 are much more thermally stable than their relatives 88, which do not possess the exo-methylene substitution. Dediazo-niation of 98 required heating in toluene at 110°C and gave one or more of the following products, probably via intermediate diphenylmethylene(vinylidene)phos-phoranes methylenephosphiranes, (2-siloxyvinyl)phosphanes, 2//-l,3-oxaphos-pholes, and l-alkylidene-2,3-dihydro-l//-benzo[c]phospholes (169). Thermolysis of 100 ( R = t-Bu, 1-adamantyl) afforded isolable 2-phosphabutadienes (169). The photochemical elimination of N2 from 98 generated cyclic azomethine imine dipoles 104 (Scheme 8.24), which rearrange to compounds 105 and 106 that could be further trapped with DMAD to form 107 (170). 

The use of lithium amides to metalate the a-position of the N-substituent of imines generates 2-azaallyl anions, typically stabilized by two or three aryl groups (Scheme 11.2) (48-62), a process pioneered by Kauffmann in 1970 (49). Although these reactive anionic species may be regarded as N-lithiated azomethine ylides if the lithium metal is covalently bonded to the imine nitrogen, they have consistently been discussed as 2-azaallyl anions. Their cyclization reactions are characterized by their enhanced reactivity toward relatively unactivated alkenes such as ethene, styrenes, stilbenes, acenaphtylene, 1,3-butadienes, diphenylacetylene, and related derivatives. Accordingly, these cycloaddition reactions are called anionic [3+2] cycloadditions. Reactions with the electron-poor alkenes are rare (54,57). Such reactivity makes a striking contrast with that of N-metalated azomethine ylides, which will be discussed below (Section 11.1.4). 

Garner et al. (90,320) used aziridines substituted with Oppolzer s sultam as azomethine ylide precursors. The azomethine ylide generated from 206 added to various electron-dehcient alkenes, such as dimethyl maleate, A-phenylmalei-mide, and methyl acrylate, giving the 1,3-dipolar cycloaddition product in good yields and up to 82% de (for A-phenylmaleimide). They also used familiar azomethine ylides formed by imine tautomerization (320). Aziridines such as 207 have also been used as precursors for the chiral azomethine ylides, but in reactions with vinylene carbonates, relatively low de values were obtained (Scheme 12.59) (92). 

Azomethine imines were generated by cleavage of certain 1,3,4-oxadia-zolidines (42) and subsequently trapped with dipolarophiles such as styrene and stilbene affording pyrazolidine heterocycles (96TL4323). 

Mesoionic compounds have been known for many years and have been extensively utilized as substrates in 1,3-dipolar cycloadditions.158-160 Of the known mesoionic heterocycles, munchnones and sydnones have generated the most interest in recent years. These heterocyclic dipoles contain a mesoionic aromatic system i.e. 206) which can only be depicted with polar resonance structures.158 Although sydnones were extensively investigated after their initial discoveiy in 1935,160 their 1,3-dipolar character was not recognized until the azomethine imine system was spotted in the middle structure of (206). C-Methyl-N-phenylsydnone (206) combines with ethyl phenylpropiolate to give the tetrasub-... 

Azomethine imine cycloadditions provide access to pyrazolidines, pyrazolines and pyrazoles. Intramolecular cyclizations were first reported in 1970.78 The main method for generation of azomethine im-ines involves reaction of a 1,2-disubstituted hydrazine with an aldehyde or an aldehyde precursor. 

The azomethine imine (151), having the alkene attached to the terminal dipole nitrogen, was generated in situ from the corresponding hydrazine by reaction with benzaldehyde (Scheme 47).79 As is typical in these reactions, condensation at the more basic benzyl-substituted nitrogen occurred, rather than at the acyl-substituted nitrogen. Cyclization of (151) afforded the 5,5-fused pyrazolidine and no bridged product. 

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