Activation Mannich reaction

The Mannich Reaction involves the condensation of formaldehyde with ammonia or a primary or secondary amine and with a third compound containing a reactive methylene group these compounds are most frequently those in which the methylene group is activated by a neighbouring keto group. Thus when acetophenone is boiled in ethanolic solution with paraformaldehyde and dimethylamine hydrochloride, condensation occurs readily with the formation of... 

In a second attempt to extend the scope of Lewis-acid catalysis of Diels-Alder reactions in water, we have used the Mannich reaction to convert a ketone-activated monodentate dienophile into a potentially chelating p-amino ketone. The Mannich reaction seemed ideally suited for the purpose of introducing a second coordination site on a temporary basis. This reaction adds a strongly Lewis-basic amino functionality on a position p to the ketone. Moreover, the Mannich reaction is usually a reversible process, which should allow removal of the auxiliary after the reaction. Furthermore, the reaction is compatible with the use of an aqueous medium. Some Mannich reactions have even been reported to benefit from the use of water ". Finally, Lewis-acid catalysis of Mannich-type reactions in mixtures of organic solvents and water has been reported ". Hence, if both addition of the auxiliary and the subsequent Diels-Alder reaction benefit from Lewis-acid catalysis, the possibility arises of merging these steps into a one-pot procedure. 

Conversion of the C-2 amide to a biologically inactive nitrile, which can be further taken via a Ritter reaction (29) to the corresponding alkylated amide, has been accomphshed. When the 6-hydroxyl derivatives are used, dehydration occurs at this step to give the anhydro amide. Substituting an A/-hydroxymethylimide for isobutylene in the Ritter reaction yields the acylaminomethyl derivative (30). Hydrolysis affords an aminomethyl compound. Numerous examples (31—35) have been reported of the conversion of a C-2 amide to active Mannich adducts which are extremely labile and easily undergo hydrolysis to the parent tetracycline. This reverse reaction probably accounts for the antibacterial activity of these tetracyclines. 

A -l,3,4-Oxadiazoline-5-thione, 2-phenyl-alkylation, 6, 440 Oxadiazolinethiones acylation, 6, 432 Mannich reaction, 6, 431 pK 6, 435 ring cleavage, 6, 433 Oxadiazoline-5-thiones acidity, 6, 435 stability, 6, 431 A -Oxadiazoline-5-thiones biological activity, 6, 445 synthesis, 6, 441 A -1,3,4-Oxadiazoline-5-thiones... 

Mannich reaction is the condensation between formaldehyde, ammonia, or a primary or secondary amine (preferably as the hydrochloride), and a compound containing at least one active hydrogen atom... 

This ring system was prepared by treatment of quinoline derivative 786 with antimonyl chloride to give 787. Quinoline derivative 786 was prepared by Mannich reaction on 2,8-dihydroxylepidine with diethylamine and formaldehyde to afford the respective diethylaminomethyl derivative that followed by subsequent nitration. The schistosomicidal activity of 787 was studied (80MI66) (Scheme 138). 

The Mannich reactions plays an important role in pharmaceutical chemistry. Many /3-aminoalcohols show pharmacological activity. The Mannich reaction can take place under physiological conditions (with respect to pH, temperature, aqueous solution), and therefore can be used in a biomimetic synthesis e.g. in the synthesis of alkaloids. 

The presence of unsaturation in the side chain is also compatible with antihistaminic activity. Mannich condensation of p-chloroacetophenone with formaldehyde and pyrollidine affords the amino ketone, 109. Reaction with an organometallic reagent from 2-bromopyridine gives 110. Dehydration leads to triproli-dine (111). ... 

Inclusion of the carbon atoms of an aromatic ring in the side chain sequence is apparently quite consistent with antlmalarial activity. Thus, reaction of p-acetamidophenol with formaldehyde and diethylamine affords the Mannich product, 79. This is then converted to the diamine (80) by saponification. Alkylation with the chloroquinoline, 70, affords amidoquine (81). The same sequence starting with the Mannich product in which pyrrolidine has been used as the amine (82) gives amopyroquine (83). 

Phenols, secondary and tertiary aromatic amines, pyrroles, and indoles can be aminomethylated by treatment with formaldehyde and a secondary amine. Other aldehydes have sometimes been employed. Aminoalkylation is a special case of the Mannich reaction (16-15). When phenols and other activated aromatic compounds are treated withA-hydroxymethylchloroacetamide, amidomethylation takes place " ... 

The condensation of nitro compounds and imines, the so-called aza-Henry or nitro-Mannich reaction, has recently emerged as a powerful tool for the enantioselective synthesis of 1,2-diamines through the intermediate /3-amino nitro compounds. The method is based on the addition of a nitronate ion (a-nitro carbanion), generated from nitroalkanes, to an imine. The addition of a nitronate ion to an imine is thermodynamically disfavored, so that the presence of a protic species or a Lewis acid is required, to activate the imine and/or to quench the adduct. The acidic medium is compatible with the existence of the nitronate anion, as acetic acid and nitromethane have comparable acidities. Moreover, the products are often unstable, either for the reversibility of the addition or for the possible /3-elimination of the nitro group, and the crude products are generally reduced, avoiding purification to give the desired 1,2-diamines. Hence, the nitronate ion is an equivalent of an a-amino carbanion. 

Even if organocatalysis is a common activation process in biological transformations, this concept has only recently been developed for chemical applications. During the last decade, achiral ureas and thioureas have been used in allylation reactions [146], the Bayhs-Hillman reaction [147] and the Claisen rearrangement [148]. Chiral organocatalysis can be achieved with optically active ureas and thioureas for asymmetric C - C bond-forming reactions such as the Strecker reaction (Sect. 5.1), Mannich reactions (Sect. 5.2), phosphorylation reactions (Sect. 5.3), Michael reactions (Sect. 5.4) and Diels-Alder cyclisations (Sect. 5.6). Finally, deprotonated chiral thioureas were used as chiral bases (Sect. 5.7). 

Lignin amines with high nitrogen content are water soluble at both alkaline and acidic pH values. The lignin amines have various useful properties. For example, they are active as flocculants, filtration aids, scale inhibitors, fluid loss additives, oil well cement additives, and corrosion inhibitors among other potential uses. The nitrogen is introduced into the lignins with the Mannich reaction [1570]. 

Other types of catalysts that are active in Mannich reactions include the Cu-bis-oxazolines.195 Most of the cases examined to date are for relatively reactive imines, such as those derived from glyoxylate or pyruvate esters. 

Isayama described the coupling reaction of N-methylimine 157 and ethyl crotonate catalyzed by Co(acac)2 and mediated by PhSiH3 to produce Mannich product 158 in 82% with syn-selectivity (Scheme 41) [71]. The (i-laclam 159 was readily synthesized by heating 158. In 2002, Matsuda et al. reported cationic Rh complex [Rh(COD) P(OPh)3 2]OTf (1 mol%) as an active catalyst for the reductive Mannich reaction [72]. N-Tosylaldiminc 160 was coupled with methyl acrylate and Et2MeSiH (200 mol%) at 45 °C to give the b-amino ester 161 in 96% with moderate anti-selectivity 68%. 

Inclusion of an acetylenic linkage as part of the side chain is apparently consistent with antidepressant activity. Reaction of propargyl magnesium bromide with dibenzocycloheptadieneone leads to carbinol 82. A Mannich reaction with formaldehyde and dimethylamine leads to 83 which, upon dehydration... 

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). 

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