Reaction with dihydropyridines

The Zincke reaction has also been adapted for the solid phase. Dupas et al. prepared NADH-model precursors 58, immobilized on silica, by reaction of bound amino functions 57 with Zincke salt 8 (Scheme 8.4.19) for subsequent reduction to the 1,4-dihydropyridines with sodium dithionite. Earlier, Ise and co-workers utilized the Zincke reaction to prepare catalytic polyelectrolytes, starting from poly(4-vinylpyridine). Formation of Zincke salts at pyridine positions within the polymer was achieved by reaction with 2,4-dinitrochlorobenzene, and these sites were then functionalized with various amines. The resulting polymers showed catalytic activity in ester hydrolysis. ... 

Utilizing the Zincke reaction of salts such as 112 (Scheme 8.4.38), Binay et al. prepared 4-substituted-3-oxazolyl dihydropyridines as NADH models for use in asymmetric reductions. They found that high purity of the Zincke salts was required for efficient reaction with R-(+)-l-phenylethyl amine, for example. As shown in that case (Scheme 8.4.38), chiral A-substituents could be introduced, and 1,4-reduction produced the NADH analogs (e.g. 114). 

The ability of 1,2 (or l,6)-dihydropyridines to undergo a Diels-Alder reaction with dienophiles such as methyl vinyl ketone, methyl acrylate, and acrylonitrile has been utilized in the synthesis of polyfunctional isoquinuclidine as a key intermediate in the synthesis of aspidosperma- and iboga-type alkaloids (66JA3099). 

Dihydropyridines 28 behave as enamines and undergo [2 - - 2] cycloaddition reactions with dienophiles such as acrylonitrile (29) and dimethyl acetylenedicar-boxylate (32). For instance, A -alkyl-l,4-dihydropyridine 28 reacts with 29 to give... 

Another example in which A-methyl-l,2-dihydropyridine (41a) behaves as an enamine rather than a diene is its reaction with methyl vinyl ketone (44) (64JCS2165). The product is a pyran 45, which is obtained in 100% yield, rather than an isoquinuclidine derivative (80JOC1657). 

Alkyl-1,4-dihydropyridines on reaction with peracids undergo either extensive decomposition or biomimetic oxidation to A-alkylpyridinum salts (98JOC10001). However, A-methoxycarbonyl derivatives of 1,4- and 1,2-dihydro-pyridines (74) and (8a) react with m-CPBA to give the methyl tmns-2- 2>-chlorobenzoyloxy)-3-hydroxy-1,2,3,4-tetrahydropyridine-l-carboxylate (75) and methyl rran.s-2-(3-chlorobenzoyloxy)-3-hydroxy-l,2,3,6-tetrahydropyridine-l-carboxylate (76) in 65% and 66% yield, respectively (nonbiomimetic oxidation). The reaction is related to the interaction of peracids with enol ethers and involves the initial formation of an aminoepoxide, which is opened in situ by m-chlorobenzoic acid regio- and stereoselectively (57JA3234, 93JA7593). 

Evidently, the reaction proceeds via the formation of bis-adduct 289 which undergoes cyclization to dihydropyridine 290. A similar reaction with methoxybutenone, but in the presence of ammonia, which is likely to involve replacement of methoxy group, has been described (80MI2). 

The key intermediate 124 was prepared starting with tryptophyl bromide alkylation of 3-acetylpyridine, to give 128 in 95% yield (Fig. 37) [87]. Reduction of 128 with sodium dithionite under buffered (sodium bicarbonate) conditions lead to dihydropyridine 129, which could be cyclized to 130 upon treatment with methanolic HC1. Alternatively, 128 could be converted directly to 130 by sodium dithionite if the sodium bicarbonate was omitted. Oxidation with palladium on carbon produced pyridinium salt 131, which could then be reduced to 124 (as a mixture of isomers) upon reaction with sodium boro-hydride. Alternatively, direct reduction of 128 with sodium borohydride gave a mixture of compounds, from which cyclized derivative 132 could be isolated in 30% yield after column chromatography [88]. Reduction of 132 with lithium tri-f-butoxyaluminum hydride then gave 124 (once again as a mixture of isomers) in 90% yield. 

Several reaction sequences have been reported in which Fischer-type carbene complexes are converted in situ into non-heteroatom-substituted carbene complexes, which then cyclopropanate simple olefins [306,307] (Figure 2.22). This can, for instance, be achieved by treating the carbene complexes with dihydropyridines, forming (isolable) pyridinium ylides. These decompose thermally to yield pyridine and highly electrophilic, non-heteroatom-substituted carbene complexes (Figure 2.22) [46]. 

Silylcuprates have been reported to undergo reactions with a number of miscellaneous Michael acceptors [65]. Conjugate addition to 3-carbomethoxy acyl pyri-dinium salts [65a] affords 4-silyl-l,4-dihydropyridines. Oxidation with p-chlorand generates a 4-acyl pyridinium salt that gives the 4-silylnicotinate upon quenching with water, and methyl 4-silyl-2-substituted dihydronicotinates upon quenching with nucleophiles (nucleophilic addition at the 6-position). The stabilized anion formed by conjugate addition to an a, j8-unsaturated sulfone could be trapped intramolecularly by an alkyl chloride [65b]. 

The most used route to pyridines is called the Hantzsch synthesis. This uses a 1,3-dicarbonyl compound, frequently a 1,3-keto ester [ethyl ace-toacetate (ethyl 3-oxobutanoate)], and an aldehyde, which are heated together with ammonia (Scheme 2.18). At the end of the reaction the dihydropyridine is oxidized to the corresponding pyridine with nitric acid (or another oxidant such as Mn02). The normal Hantzsch procedure leads to symmetrical dihydropyridines. Two different 1,3-dicarbonyl compounds may not be used as two enoiate anions might form, giving mixed products when reacted with the aldehyde. The aldehyde itself should preferably be non-enolizable, otherwise the chance of aldoliza-tion exists, but with care this can be avoided. 

Related to the above are the reactions of pyridinium ions with nucleophiles. It has been known for many years that pyridinium ions can undergo ring-opening reactions with primary amines (70JA5641). Studies on the mechanisms of these reactions indicate that the interconversion of the dihydropyridine (48) with the acyclic dianils (49) of glutacondialdehyde is a key step in these reactions. 

The reaction of iminium ions with dihydropyridines is a method, suggested from biosynthetic studies, for the formation of carbon-carbon bonds to these six-membered heterocycles. The 1,4-dihydropyridine (8), a presumed intermediate from the reaction of ammonia with glutaraldehyde, reacts with the cyclic iminium ion (159) to give, after oxidation, nicotine (160) (72CC1091). Another example of this reaction has provided a total synthesis of olivacine (163). The 1,2-dihydropyridine ring system in (161), generated from its chromium tricarbonyl complex, was observed to undergo an intramolecular cyclization... 

Although the reaction of dihydropyridinium ions produced by the electrophilic attack of dihydropyridines has promise in organic synthesis, this reaction has not been extensively exploited. Some examples of their potential are provided by the acid-catalyzed reactions with indoles (80TL2341). An application of this reaction for an efficient synthesis of ( )-deplancheine is shown in Scheme 25. An interesting feature of this reaction was the use of the alkoxy-substituted dihydropyridine as a carbonyl precursor. 

It was suggested in the discussion of Section 2.07.5.1 that an intramolecular Diels-Alder reaction between a dihydropyridine and a-indolyl acrylate could be an efficient route to indole alkaloids. Although this has proven to be a successful reaction with A2-piperideines (Section 2.07.5.1), all attempts, most of which have not been reported in the literature, to apply this concept to dihydropyridines have been unsuccessful (81JOC3293). 

There are some methods that are specific to HCHO. For example, the Hantzsch reaction of HCHO, collected with a diffusion scrubber, with ammonium acetate, acetic acid, and acetylacetone to form diacetyldihydrolutidine, which is measured using its fluorescence at 470 nm, has been applied to air measurements (Dasgupta et al., 1988, 1990 Kleindienst et al., 1988a,b Lawson et al., 1990 Khare et al., 1997). Reaction with 1,3-cyclohexanedione and ammonium acetate to form a dihydropyridine derivative that is measured by fluorescence has been used in conjunction with a diffusion scrubber (Fan and Dasgupta, 1994). Enzymatic methods have been used in which formaldehyde dehydrogenase catalyzes the oxidation of HCHO to HCOOH in the presence of -nicotinamide adenine dinucleotide, NAD+, which is reduced to NADH. The latter is measured by fluorescence at 450 nm (Lazrus et al., 1988 Ho and Richards, 1990). 

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