Isocyanide attack

The mechanism leading to adduct G presents clear analogies with that of the well established Ugi MCR, in which the isocyanide attacks the electrophilic carbon of an iminium ion for this reason, this process could be called the Ugi-Reissert reaction (Scheme 31). However, in this transformation, the adduct arises after a final hydration of the nitrilium ion, instead of undergoing the Mumm rearrangement as in the traditional Ugi reaction [188]. The novelty here lies in the use of M-acylazinium salts as a new source of reactive iminium ions for Ugi-type processes. 

M, rearrangement, formal elimination of HF, and aromatization, to yield dipole 248. Yet another possibility is that the isocyanide attacks the anhydride to form the intermediate K, a direct precursor of the dipolar species L. This mode of activation for isocyanides has been investigated by El Kaim, who promoted a series of useful transformations based on this reactivity, leading to products such as trifluoropyruvamides 250 (R = F) [199-201]. 

Methanolysis of (108a) furnishes the thioxosulfonamide (145) as yellow crystals in quantitative yield (Scheme 53) <78AG(E)195>. n-Butyllithium and phenyllithium are commonly used as nucleophiles and attack the sulfur atom, but the lithium salts of isocyanides attack mainly the carbon atoms of the ring. Attack on the sulfur atom of the thiiranimine (108c) is observed in the reactions with the anion of diethyl malonate, a phosphorus ylide, /V-methylindole and enamines or ynamines (Scheme 54) <80JOC4366>. 

Isocyanides attack under the influence of aluminium chloride, thus introducing an imine unit directly. ... 

Ring closures which depend on the conversion of the heteroatom into an electrophile are mostly associated with the formation of thiophene, selenophene and tellurophene rings and some illustrative examples are shown in Scheme 17. The last example which concerns the conversion of reaction with isocyanides is of particular interest since it appears to entail the attack of an electrophilic nitrogen species on the aryl ring. 

Intramolecular attack of the carbenes shown in Scheme 30a provides benzo[6]cyclo-hepta[(5 ]-furans and -thiophenes, but the nitrogen analogue (X = NH) yields 9,10-dihydro-acridine 81AJC1037). Photolysis of 2-biphenyl isocyanide (Scheme 30b) (72JOC3571) and thermolysis of 2-biphenylsulfonyl diazomethane (Scheme 30c) (72CC893) also result in ring expansion. 

The mechanistic analogy to the Streckcr synthesis becomes obvious in the addition of the isocyanide to the imine to produce the a-amino nitrilium intermediate. Since all four components are involved in this step, it might be expected that every chiral component (chiral groups R1, R2, R3, R4) contributes to diastereofacial differentiation in the nucleophilic attack on the imine. However, in peptide syntheses by four-component condensation5, the chiral isocyanide or a chiral carboxylic acid component has only limited influence on the diastereoselectivity of the a-amino amide formation5. 

The stereocontrol observed in these reactions is rationalized on the basis of zinc complexes formed with the Schiff bases, as described in Section 1.4.4.2.2. The isocyanide, being a free and potent nucleophile, attacks this complex from the sterically less-hindered side, that is. from the side of the ring oxygen. 

Rh(OEP)H reacts with CNR (R = Me, n-Bu,) to give the adduct Rh(OEP)-(H)CNR (which has no parallel in CO chemistry) which then slowly transforms to the formimidoyl insertion product, Rh(OEP)C(H)=NR. The dimer Rh(OEP))2 reacts with CNAr (Ar = 2.6-Cf,H3Mc2) in aqueous benzene to give the carbamoyl product. Rh(OEP)C(0)NHAr (characterized by an X-ray crystal structure) together with the hydride, which it.self reacts further with the isocyanide. This is suggc.sted to form via a cationic carbene intermediate, formed by attack of HiO on coordinated CNAr in concert with disproportionation to Rh(III) and Rh(l). 

In analogy, Ugi et al. reported on a lactam formation by running a one-pot three components reaction the condensation of L-lysine 7, isobutyraldehyde and methyl isocyanide led to the corresponding a-amino-c-caprolactam 9, but the yield was not given. The authors presumed either a nucleophilic substitution of the ester 8 as the primary Ugi product by the amino function of the side chain or, alternatively, the nucleophilic attack of the NH2-group on an intermediately formed 0-acylamide and a subsequent rearrangement (Scheme 1) [4]. 

The reactions of nucleophilic reagents with cationic and uncharged metal carbonyl complexes have received much attention in the past, and it is not surprising that these studies have now been extended to isocyanide metal complexes. Different products in these reactions can arise by three general routes these include ligand substitution, reactions involving attack at a ligand, and reduction of the metal complex. All have been observed in reactions with metal isocyanide complexes. 

The susceptibility of a metal complex to nucleophilic attack is enhanced by a positive charge on the complex. This fact, and the fact that most metal isocyanide complexes are cationic, probably explains why no nucleophilic reactions of uncharged isocyanide complexes have yet been reported. It is... 

The diversity of the Ugi-MCR mainly arises from the large number of available acids and amines, which can be used in this transformation. A special case is the reaction of an aldehyde 9-26 and an isocyanide 9-28 with an a-amino acid 9-25 in a nucleophilic solvent HX 9-30 (Scheme 9.5). Again, initially an iminium ion 9-27 is formed, which leads to the a-adduct 9-29. This does not undergo a rearrangement as usual, but the solvent HX 9-30 attacks the lactone moiety. Such a process can be used for the synthesis of aminodicarboxylic acid derivatives such as 9-31 [3, 30],... 

The whole process, formation of the iminium ion by condensation of the aldehyde with an amine (1 min at 900 W in a domestic oven) then nucleophilic attack of the isocyanide (1 min at 450 W and 1 min cooling) takes 3 min to give yields ranging from 56 to 88% of the pure product. 

The 2,3-substituted indols are formed via a palladium-catalyzed coupling reaction of aryl halide, o-alkenylphenyl isocyanide, and amine (Equation (122)).481 Oxidative addition of an aryl halide, insertion of both the isonitrile and alkene moieties of o-alkenylphenyl isocyanide, and 1,3-hydrogen migration may form a 7r-allylpalladium species, which is then attacked by an amine to afford an indol. 

The p-functionalized 2-hydroxyphenyl isocyanide not only contains the isocyanide and the nucleophile within the same molecule, but both functional groups are also arranged in one plane for an intramolecular nucleophilic attack [176]. This arrangement, in addition to the aromaticity of the five-membered ring obtained after cyclization to the carbene ligand, particularly favors the intramolecular nucleophilic attack. In contrast to 2-hydroxyethyl isocyanide, free 2-hydroxyphenyl isocyanide is not stable [177]. The stable 2-trimethylsiloxyphenyl isocyanide [178] can serve as a synthon for 2-hydroxyphenyl isocyanide. Carbene complexes 63 with an NH,0-stabilized NHC ligand can be obtained from the complexes 62 with the... 

Hydrazine, MeN2H3, and PhN2Hj react with [Fe(CNMe)g] to give [(MeNC)4Fe(C4H9RNJ] (R = H, Me, or Ph) in which the hydrazine has attacked two isocyanide ligands, as above, to produce the complex (53) with two planar three-co-ordinate carbon atoms. "... 

Not only cyanide but also an isocyanide behaves as a nucleophile to attack a carbonyl compound or an imine that is prepared in situ from an carbonyl compound. " In these reactions, an isocyanide is a synthetic equivalent to an aminocarbonyl anion. Asymmetric version of this reaction appeared in 2003. Using a combination of Lewis acid SiCU and a Lewis base chiral bisphosphora-mide, the corresponding a-hydroxyamide is obtained in 96% yield with >98% ee (Scheme 4.23). 

Only at elevated temperatures is the isothiocyanate group also attacked by further addition of chlorine with simultaneous elimination of sulfur dichloride. It is thus converted into the isocyanide dichloride group, without isolation of an intermediate ... 

We have previously seen how cyclic lactams can be synthesized by installing a protected amine in one of the Ugi or Passerini components, followed by cyclization onto the isocyanide-derived amide, taking advantage of the particular reactivity of convertible isocyanides. The same type of compounds can be accessed through nucleophilic attack of the amine onto an ester moiety, suitably installed as additional function into another component. This strategy has been widely used for the preparation of diketopiperazines 104 (Fig. 22), a typical privileged structure, starting with... 

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