Mannich reaction heterocycles

Organocatalytic asymmetric Mannich reactions (heterocycles as chiral ligands and products) 07EJO5797. 

Nagata K, Nishimnra K, Yokoya M, Itoh T (2006) Enantioselective Syntheses of ent-Sedridine and (+)-Coniine via Proline-Catalyzed Mannich Reaction. Heterocycles 70 335... 

The benzo[6] heterocycles are generally less reactive than their monocyclic counterparts. Thus benzo[6]thiophene unlike thiophene does not undergo Vilsmeier formylation or the Mannich reaction. 

Heterocycles as reagents and substrates in modem modifications of the Mannich reaction 98AG(E)1045. 

The wide latitude of structural variation consistent with bioactivity in this series is illustrated by the observation that antiinflammatory activity is maintained even when the second aromatic group is attached directly to the pyrrole nitrogen rather than to the heterocyclic ring via a carbonyl group as in the previous case. Condensation of p-chloroaniline with hexane-2,5-dione (or its dimethoxy-tetrahydrofuran equivalent) affords pyrrole 7. The acetic acid side chain is then elaborated as above. Thus, Mannich reaction leads to the dimethylaminomethyl derivative 8, which is in turn methylated (9) the quaternary nitrogen replaced by cyanide to afford 10. Hydrolysis of the nitrile then gives clopirac (11). 

HETEROCYCLIC NITRAMINES DERIVED FROM MANNICH REACTIONS... 

The Mannich reaction has been used to synthesize numerous heterocyclic nitramine explosives. Adolph and Cichra prepared a number of A-heterocycles containing ferf-butyl A-blocking groups. The nitrolysis of these f-butyl groups provides the corresponding A-nitro derivatives in excellent yields (Section 5.6.2.2). Some of the nitramine products from these reactions are powerful, energetic explosives with attractive properties. 

Keywords 1,3-Dicarbonyls, Biginelh reaction, Hantzsch reaction, Heterocyclic chemistry, Knoevenagel condensation, Mannich reaction, Michael addition, Multi-component reactions... 

The Mannich reaction consists on the condensation of a CH-activated compound with a primary or a secondary amine and a non-enolizable aldehyde or ketone to afford p-aminocarbonyl derivatives known as Mannich bases (Scheme 20). This sequence is of great use for the constmction of heterocyclic targets, as illustrated for example by the Robinson-Schopf synthesis of tropinone in 1937 or by the preparation of some azabicyclo[3.3.1]nonanones or pyranocoumarine derivatives (Fig. 1) [100]. In the following, representative recent examples of the formation of five- to seven-membered ring heterocycles will be presented. 

A The Mannich reaction proceeds through the intervention of the N,A dimethylmethyleniininium cation [Me N =CHJ, This is insufficiently electrophilic to react with the benzene ring under the mild reaction conditions. Similarly, were the electrophile to react with the carbonyl oxygen atom of the heterocycle, this reaction would be reversible, as an aminomethyl ether is relatively unstable in acidic media. Thus, it seems plausible that the chromone utilizes enol or enolate character to trap the electrophile at C-3, followed by deprotonation of the adduct to reform the chromone ring system ( heme 5.9). 

Nucleophiles other than hydride can be added to support-bound imines to yield amines. These include C,H-acidic compounds, alkynes, electron-rich heterocycles, organometallic compounds, boronic acids, and ketene acetals (Table 10.9). When basic reaction conditions are used, stoichiometric amounts of the imine must be prepared on the support (Entries 1-3, Table 10.9). Alternatively, if the carbon nucleophile is stable under acidic conditions, imines or iminium salts might be generated in situ, as, for instance, in the Mannich reaction. Few examples have been reported of Mannich reactions on insoluble supports, and most of these have been based on alkynes as C-nucleophiles. 

In 1997, the first truly catalytic enantioselective Mannich reactions of imines with silicon enolates using a novel zirconium catalyst was reported [9, 10]. To solve the above problems, various metal salts were first screened in achiral reactions of imines with silylated nucleophiles, and then, a chiral Lewis acid based on Zr(IV) was designed. On the other hand, as for the problem of the conformation of the imine-Lewis acid complex, utilization of a bidentate chelation was planned imines prepared from 2-aminophenol were used [(Eq. (1)]. This moiety was readily removed after reactions under oxidative conditions. Imines derived from heterocyclic aldehydes worked well in this reaction, and good to high yields and enantiomeric excesses were attained. As for aliphatic aldehydes, similarly high levels of enantiomeric excesses were also obtained by using the imines prepared from the aldehydes and 2-amino-3-methylphenol. The present Mannich reactions were applied to the synthesis of chiral (3-amino alcohols from a-alkoxy enolates and imines [11], and anti-cc-methyl-p-amino acid derivatives from propionate enolates and imines [12] via diastereo- and enantioselective processes [(Eq. (2)]. Moreover, this catalyst system can be utilized in Mannich reactions using hydrazone derivatives [13] [(Eq. (3)] as well as the aza-Diels-Alder reaction [14-16], Strecker reaction [17-19], allylation of imines [20], etc. 

Alternative synthetic techniques towards TB derivatives were reported by Becker (93TL1889) and Cekavicus (01TL4239). Becker prepared a highly functionalized TB derivative by heating methyl 5-chloro-4-[(ethoxyoxoacetyl)amino]-2-methoxybenzo-ate in DMSO at 180°C. Cekavicus reported that the novel heterocyclic system 3 arose via the intermolecular Mannich reaction of l,l-dioxo-l,2-dihydro-ben-zo[i]thiophen-3-one (Scheme 4). 

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