Hantzsch dihydropyridine ester

Khadilkar, B.M., Gaikar, V.G. and Chitnavis, A.A., Aqueous hydrotrope solution as a safer medium for microwave enhanced Hantzsch dihydropyridine ester synthesis, Tetrahedron Lett., 1995, 36, 8083-8083 Khadilkar, B.M. and Chitnavis, A.A., Rate enhancement in the synthesis of some 4-aryl- 1,4-dihydropyridines using methyl 3-aminocrotonate, under microwave irradiation, Indian J. Chem., Sect. B, 1995, 34, 652-653. 

Khadilkar BM, Gaikar VG, Chitnavis AA (1995) Aqueous hydrotrope solution as a safer medium for microwave enhanced Hantzsch dihydropyridine ester synthesis. Tetrahedron Lett 36 8083-8086... 

Hantzsch dihydropyridine synthesis. The original Hantzsch synthesis2 involves condensation of two equivalents of a keto ester with an aldehyde in the presence of ammonia. In an enantioselective version.5 the chirality is introduced by use of a chiral hydrazone (2) of an alkyl acetoacetate prepared from 1. The anion of 2 is then treated with Michael acceptors to form adducts (3), which cyclize to 4-aryl-l,4-dihydropyridines (4), in 64-72% overall yield and in 84-98% ee. 

Inspired by the recent observation that imines are reduced with Hantzsch esters in the presence of achiral Lewis or Brpnsted acid catalysts (Itoh et al. 2004), we envisioned a catalytic cycle for the reductive amination of ketones which is initiated by protonation of the in situ generated ketimine 10 from a chiral Brdnsted acid catalyst (Scheme 13). The resulting iminium ion pair, which may be stabilized by hydrogen bonding, is chiral and its reaction with the Hantzsch dihydropyridine 11 could give an enantiomerically enriched amine 12 and pyridine 13. 

With the chiral BINOL-phosphates in hand we started to examine the enantioselective transferhydrogenation of ketimines 1. After reaction optimization, including a survey of different solvents, temperatures, BINOL-phosphates, and Hantzsch dihydropyridines, we found that indeed enantioselectivities are observed and the best selectivities are obtained with Brpnsted acid 5a and Hantzsch ester 2a (Table 2). In general, for the first time, high enantioselectivities and good yields are observed in this newly developed metal-free reduction procedure (Rueping et al. 2005b Hofmann et al. 2005 Storer et al. 2006). 

A new strategy for the synthesis of heterocyclic a-amino acids utilizing the Hantzsch dihydropyridine synthesis was developed in the laboratory of A. Dondoni." ° The enantiopure oxazolidinyl keto ester was condensed with benzaldehyde and fert-butyl amino crotonate in the presence of molecular sieves in 2-methyl-2-propanol to give a 85% yield of diastereomeric 1,4-dihydropyridines. The acetonide protecting group was removed and the resulting amino alcohol was oxidized to the target 2-pyridyl a-alanine derivative. 

Dihydropyridines can be prepared via the three-eomponent coupling of cinnamaldehyde, aniline and p-keto esters under solvent-free conditions by means again of L-Pro as catalyst in the transformation. The three-component reaction of 1,3-indanedione, isatins and enamines as the nucleophiles is also possible in the presence of L-Pro for the one-pot synthesis of highly functionalised spirooxindoles derivatives. While only some examples are highlighted here, ° ° the possibilities of L-Pro in multicomponent reactions are tremendous. It has also shown good catalytie activity in classic multicomponent reactions such as Biginelli reactions and Hantzsch dihydropyridine synthesis. 

A new approach to stereoselective transfer hydrogenation of imines was the application of chiral phosphoric acid esters as organocatalysts [50-52]. The mechanism is based on the assumption that the imine is protonated by a chiral Bronsted acid, which acts as the catalyst. The resulting diastereomeric iminium ion pairs, which may be stabilized by hydrogen bonding, react with the Hantzsch dihydropyridine at different rates to give an enantiomerically enriched amine and a pyridine derivative [50-52]. The exact mechanism is still under discussion however computational density functional theory (DFT) studies ]53, 54] suggest a three-point contact model. ... 

Based on previous studies where the imines were reduced with Hantzsch dihydropyridines in the presence of achiral Lewis [43] or Brpnsted acid catalysts, [44] joined to the capacity of phosphoric acids to activate imines (for reviews about chiral phosphoric acid catalysis, see [45-58]), the authors proposed a reasonable catalytic cycle to explain the course of the reaction (Scheme 3) [41]. A first protonation of the ketimine with the chiral Brpnsted acid catalyst would initiate the cycle. The resulting chiral iminium ion pair A would react with the Hantzsch ester lb giving an enantiomerically enriched amine product and the protonated pyridine salt B (Scheme 3). The catalyst is finally recovered and the byproduct 11 is obtained in the last step. Later, other research groups also supported this mechanism (for mechanistic studies of this reaction, see [59-61]). 

Aqueous solutions of hydrotropes (e.g. NaBMGS, sodium methylcello-solve sulfate) have been used in the Hantzsch dihydropyridine synthesis, a tandem Knoevenagel and Michael reaction, in which acetoacetic ester reacts with benzaldehydes and methyl aminocrotonate or aqueous ammonia at room temperature or heated with microwaves (MW) [16,17] ... 

Further adaptation of the Hantzsch dihydropyridine synthesis has opened up synthetic routes to annelated 1,4-dihydropyridines, e.g. (25), in which the nitrogen is at a bridgehead position, " and to 2-amino-l,4-dihydropyridine-3,5-dicarboxylates of type (26)/ The former are prepared by Michael addition of /3-amino-acrylates (27) to alkylideneacetoacetic esters R CH=C(C02Me)C0CH3, whereas the latter involve a similar reaction of the acetoacetate with an amidinoacetic ester (NH2)2C=CHC02R. ... 

With 8-keto esters HCHO is known to undergo Knoevenagel reaction to give 2-acylacrylates, key intermediates in the Hantzsch dihydropyridine synthesis. Application... 

The Hantzsch pyridine synthesis involves the condensation of two equivalents of a 3-dicarbonyl compound, one equivalent of an aldehyde and one equivalent of ammonia. The immediate result from this three-component coupling, 1,4-dihydropyridine 1, is easily oxidized to fully substituted pyridine 2. Saponification and decarboxylation of the 3,5-ester substituents leads to 2,4,6-trisubstituted pyridine 3. 

An obvious outcome of the Hantzsch synthesis is the symmetrical nature of the dihydropyridines produced. A double protection strategy has been developed to address this issue. The protected chalcone 103 was reacted with an orthogonally protected ketoester to generate dihydropyridine 104. Selective deprotection of the ester at C3 could be accomplished and the resultant acid coupled with the appropriate amine. Iteration of this sequence with the C5 ester substituent ultimately gave rise to the unsymmetrical 1,4-dihydropyridine 105. 

A modihed Hantzsch synthesis has been utilized for the preparation of 1,4-dihydropyridines (Scheme 66). Thus, condensation of formylfurazans 116 with an acetoacetic ester and aminocrotonic acid ester in isopropanol at reflux led to 1,4-dihydropyridine derivatives 117 in about 70% yield (92AE921). Both isomeric furoxan aldehydes reacted in a similar way. 

The first synthesis of a 1,4-dihydropyridine, which is known as the Hantzsch ester, is attributed to Arthur Hantzsch (1882LA1, 1885CB1744). Since then,... 

Hantzsch cyclization of 214 to dihydropyridines 216 can be accomplished by treating 215 with 214 in the presence of NaOEt (Equation 29). Under these conditions, dihydropyridines 216 are obtained in 41-64% yields. A three-component Hantzsch reaction using 214, aldehyde 217, and /3-keto ester 218 under similar conditions affords 219 in 51% yield (Equation 30) <2005JOC5331>. 

When some dihydropyridines were prepared by the Hantzsch one-pot synthesis from alkyl 3-aminocrotonates (85CPB3787), the same type of products were formed by Michael addition of esters of amidinoacetic acid to aralkylidene-/3-ketoesters (81AF1173). 

Franke PT, Johansen RL, Bertelsen S, Jorgensen KA (2008) Organocatalytic enantioselective one-pot synthesis and application of substituted 1,4-dihydropyridines - Hantzsch ester analogues. Chem Asian J 3 216—224... 

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. 

Correlations with Hantzsch esters) (70) (77BSB267). This latter type of compound is of interest as an effective model for the NAD/NADH coenzyme system, and this work provides detailed analysis of H and 13C NMR of such compounds. 

The classical Hantzsch reaction, the formation of dihydropyridines from an aldehyde, a 5-keto ester and an amine, was first described in 18826. In the 1940s, the interest for this substance class increased due to its pharmacological activity, for example, 4-aryl-1,4-dihydropyrdines form an important class of calcium channel antagonists such as Nifedipin. 

Another important reaction of diketene derivatives is the Hantzsch pyridine synthesis (101). This synthesis is the preparation of 1,4-dihydropyridines (14) starting either from two acetoacetic esters, which react with an aldehyde and ammonia or a primary amine or from 3-aminocrotonates and 2-alkylidene acetoacetic esters, both diketene derivatives. Several such dihydropyridines such as nifedipine [21829-25-4] (102), nimodipine [66085-59-4], and nicardipine [55985-32-5] exhibit interesting pharmaceutical activity as vasodilators (blood vessel dilation) and antihypertensives (see Cardiovascularagents). 

Keywords aldehyde, /Tkctonic ester, urea, Hantzsch synthesis, microwave irradiation, 1,4-dihydropyridine... 

The preparation of (83) (Expt 8.29) is an example of the Hantzsch pyridine synthesis. This is a widely used general procedure since considerable structural variation in the aldehydic compound (aliphatic or aromatic) and in the 1,3-dicarbonyl component (fi-keto ester or /J-diketone) is possible, leading to the synthesis of a great range of pyridine derivatives. The precise mechanistic sequence of ring formation may depend on the reaction conditions employed. Thus if, as implied in the retrosynthetic analysis above, ethyl acetoacetate and the aldehyde are first allowed to react in the presence of a base catalyst (as in Expt 8.29), a bis-keto ester [e.g. (88)] is formed by successive Knoevenagel and Michael reactions (Section 5.11.6, p. 681). Cyclisation of this 1,5-dione with ammonia then gives the dihydropyridine derivative. Under different reaction conditions condensation between an aminocrotonic ester and an alkylidene acetoacetate may be involved. 

To a stirred solution of a,/ -unsaturated aldehyde (0.5 mmol) in dioxane (7 mL) at 13 °C was added catalyst (20.4 mg, 0.05 mmol, 10 mol%) and, after a further 5 min, crystalline dihydropyridine (Hantzsch ester, 129.2 mg, 0.51 mmol). After a reaction time of 48 h the mixture was poured into distilled water (20 mL) and extracted with DCM (2 x 125 mL). The combined organic layers were dried (MgSCh), filtered, and concentrated. The product was isolated by FC (Si02, ethyl acetate/hexane) to give the saturated aldehyde. Enantiomeric excess was measured by chiral stationary phase GC-analysis. 

As well as being intermediates for the synthesis of pyridines, these dihydropyridines are themselves an important class of heterocycles. For instance, dihydropyridine 5.14 is a drug for lowering blood pressure. In the synthesis of 5.14 note that carrying out the Hantzsch synthesis stepwise allows for the preparation of an unsymmetrical dihydropyridine, having both a methyl and an ethyl ester. 

MISCELLANEOUS REACTIONS OF DIHYDROPYRIDINES Additional tests for net hydride transfers initiated by single-electron transfer include the use of substrates in which such pathways would necessarily involve readily ring-opened cyclopropylmethyl or readily cyclized 5-hexenyl radicals. Products from these radical reactions are not formed in NAD+/ NADH dependent enzymic reductions or oxidations (Maclnnes et al., 1982, 1983 Laurie et al., 1986 Chung and Park, 1982). Such tests have also been applied in non-enzymic reductions. Thus cyclopropane rings in cyclopropyl 2-pyridyl ketones, or imines of formylcyclopropane (van Niel and Pandit, 1983, 1985 Meijer et al., 1984) survive Mg+2 catalysed reduction by BNAH or Hantzsch esters but are opened by treatment with tributylin hydride. 

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