Cascade reactions amine compounds

Nonetheless, it was a fairly short step from octopus compounds to dendrimers, and the step was taken by Vogtle in the late 1970s when he attempted to use a cascade reaction to prepare a molecule of the dendrimer type that would now be considered a dendron rather than a fully developed dendrimer. It began with the addition of acrylonitrile to an anfine, followed by reduction of the nitrile to amine. This was followed by a further reaction with acrylonitrile, and the process was repeated several times to yield highly branched macromolecules. There were initially problems with the reduction step but these were overcome, and the preparation of these poly(propylene imine) dendrimers was later commercialized. 

Keywords Absolute configuration, Amines, Amino acids, Carbenes, Cascade reactions, 2-chloro-2-cyclopropylideneacetates. Combinatorial libraries. Cycloadditions, Cyclobutenes, Cyclopropanes, Diels-Alder reactions. Heterocycles, Michael additions. Nitrones, Nucleophilic substitutions, Peptidomimetics, Palladium catalysis. Polycycles, Solid phase synthesis, Spiro compounds. Thiols... 

Furans are also useful 4ji components for tandem Ugi condensation/intra-molecular Diels-Alder cascade reactions. For example, stirring a methanolic mixture of compounds 127-129 and benzylamine at rt provided the Ugi condensation product 130 that underwent a subsequent intramolecular Diels-Alder cycloaddition to furnish 131 in 70-90% yield (Scheme 23) (99TL1851). This methodology also allowed for a solid phase synthesis by using an ArgoGel-Rink resin as the amine component, providing cycloadducts 131 (after cleavage from the resin) in ca. 90-95% yields. 

H-pyrane] derivatives in the presence of isatins, malononitrile, and acetylacetone/ethyl 3-oxobutanoate [103]. Yan and coworkers showed in 2012 that chiral tertiary amine-thiourea (158) derived from quinine can catalyze a three-component reaction between isatins 118, malononitrile (119), and a-phenyl-isocyanoacetate (217) (Scheme 2.75) [104]. The process affords dihydropyrryl-spirooxindoles 218 and involves an initial Knoevenagel condensation of 118 and 119 followed by the nucleophilic anion attack of 217 (see the key transition state intermediate on Scheme 2.75). Final intramolecular cyclo-addition affords the expected compounds where H bond interactions are supposed to direct the attack of isocyanate anion and, consequently, contfol the enantioselectivity. One year later, Xu s group used a bifunctional cinchona-based squaramide to catalyze multicomponent cascade reaction to synthesize spiro[pyrrolidin-3,2 -oxindoles] via 1,3-proton shift and [3h-2]... 

The second one-pot cascade reaction was used to complete the synthesis of the natural product from acid 69. Reduction of the two azide groups of 69 produced the highly polar diamine 70, which was treated with EDC and HOBt to induce an intramolecular lactam cyclization and deliver the macro-palau amine 71. When the crude reaction mixture of 71 was heated in TEA, compound 72, proceeding through amidine tautomer 71, elicited the key transannular cyclization and delivered the palau amine in 17% overall yield from 69. The outcome stereochemistry was all in the control of the stereocenters within the substrate. 

Using 2-iodmybenzoic acid (IBX) as the oxidant, Wang et al. achieved one-step formal conjugate addition of active methylene compounds in moderate yield with excellent enantioselectivity (Scheme 7.20). In a related study, Enders applied this p-activation of saturated aldehydes with IBX to amine-catalyzed cascade reactions for the synthesis of cyclohexene derivatives. Furthermore, Xu et al. succeeded in replacing stoichiometric oxidants with dio q gen by combining enamine catalysis with Pd-catalyzed aerobic oxidation. ... 

Inspired by the success of intramolecular addition and tautomerization of aldehydes with a pendant alkyne through cooperative catalysis of a secondary amine and an An complex, in 2008, Yang et al. reported a cascade reaction with the combination of a copper complex and an achiral secondary amine catalyst for the synthesis of attractive carbocycles [48]. This chemistry merged a pyrrolidine-promoted Michael addition via iminium ion intermediates and a Cu-catalyzed cycloisomerization protocol (Scheme 9.54). Various ketones and alkyne-tethered active methylene compounds could be converted into densely functionalized cyclopentene derivatives. Although the asymmetric version was not given, the chemistry described here was amenable for the implementation of asymmetric synthesis of such functionalized molecules by a combination of chiral amines and suitable Au complexes. 

Two years later, enantioselective variants of this type of cascade reaction were achieved by replacing the enones with relatively more active enals. Zhao et al. reported a cascade Michael/annulation process combining amino and palladium catalysis [49] to furnish cyclic products with improved complexity and diversity (Scheme 9.55). First, a secondary amine catalyst promoted Michael addition of alkyne-tethered active methylene compounds to a, 3-unsaturated aldehydes to produce optically active chiral aldehydes... 

AMINE-CATALYZED CASCADE REACTIONS OF KETOSES WITH 1,3-DICARBONYL COMPOUNDS... 

SCHEME 2.29 Amine-catalyzed cascade reactions of hydroxyacetone with 1,3-dicarbonyl compounds. 

Similar to AAOs, MAO can also be employed either in the stereoinversion starting from an enantiopure amine or in the deracemization starting from the racemate vide supra) [18]. Both approaches have been proven to be remarkably efficient for chiral amine synthesis, in particular for cyclic secondary and tertiary structures. Conversely, for acyclic imine intermediates, a competing hydrolysis reaction toward the carbonyl compound is often observed, thus leading to a diminished product yield. This spontaneous hydrolysis was recently exploited for the deracemization cascade reaction combining an (S)-selective MAO with an (R)-selective co-TA (Scheme 2.44) [149]. 

Fig. 9.8 presents another, more complex type of phosphate prodrugs, namely (phosphoryloxy)methyl carbonates and carbamates (9-26, X = O or NH, resp.) [84], Here, the [(phosphoryloxy)methyl]carbonyl carrier appears quite versatile and of potential interest to prepare prodrugs of alcohols, phenols, and amines. The cascade of reactions leading from prodrug to drug as shown in Fig. 9.8 involves three steps, namely ester hydrolysis, release of formaldehyde, and a final step of carbonate hydrolysis (X = O) or A-decar-boxylation (X = NH). Three model compounds, a secondary alcohol, a primary aliphatic amine, and a primary aromatic amine, were derivatized with the carrier moiety and examined for their rates of breakdown [84], The alcohol, indan-2-ol, yielded a carrier-linked derivative that proved relatively... 

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