1,2-Dihydropyridines

The great majority of 1,4-dihydropyridines are prepared using classical Hantzsch pyridine synthesis or one of its variants. The first dihydropyridine was in fact isolated back in 1882 as a stable intermediate from that method. In its simplest form, the synthesis involves heating an aldehyde such a orf/io-nitrobenzaldehyde (12-1) with ethyl acetoacetate (12-2) and ammonia. The reaction almost certainly involves, as the first 

aldol condensation to form the benzylidene derivative (12-3). Conjugate addition of a second mole of acetoacetate would then afford the 1,5-diketone (12-4). Reaction of the carbonyl groups with ammonia will lead to the formation of the dihydropyridine ring. Alternatively, acetoacetate may go on to form the imine (12-5) reaction of this with the aldol product (13-3) will give the same dihydropyridine. The product, nifedipine (12-6) [13], has been used extensively for the treatment of angina and hypertension. 

Extensive stmcture activity relationship (SAR) studies in this series revealed that unsymmetrical substitution on the heterocyclic ring and hence the introduction of chirality on the central carbon atom led to increased potency. Such asymmetrical dihydro-pyridines can be prepared by stepwise variation of the Hantzsch synthesis, based on the hypothetical alternate route to nifedipine. Thus, aldol condensation of methyl acetoacetate with 2,3-dichlorobenzaldehyde (13-1) gives the cinnamyl ketone (13-2). Reaction of that with the enamine (13-3) from ethyl acetoacetate gives the calcium channel blocker felodipine (13-4) [14]. 

The key acetoacetate (14-2) for the synthesis of nimodipine (14-5) is obtained by alkylation of sodium acetoacetate with 2-methoxyethyl chloride. Aldol condensation of meffl-nitrobenzene (14-1) and the subsequent reaction of the intermediate with eneamine (14-4) give nimodipine (14-5) [15]. 

The product (15-2) from aldol condensation of meto-nitrobenzaldehyde with the dimethyl acetal from ethyl 4-formylacetoacetate (15-1) provides the starting material for a dihydropyridine in which one of the methyl groups is replaced by a nitrile. Reaction of (15-2) with the eneamine from isopropyl acetoacetate gives the corresponding dihydropyridine hydrolysis of the acetal function with aqueous acid affords the aldehyde (15-3). That function is then converted to its oxime (15-4) by reaction with hydroxylamine. Treatment of that intermediate with hot acetic acid leads the oxime to dehydrate to a nitrile. There is this obtained nilvadipine (15-5) [16]. 

In 1882, Hantzsch achieved the synthesis of symmetrically substituted dihydropyridines (DHPs) by reacting ammonia, aldehydes, and two equivalents of yS-ketoest-ers [27]. Since then, interest in these types of compound has grown, because of their pharmacological activity [28]. The Hantzsch reaction has successfully been used for synthesis of a wide range of DHPs and is still a popular tool for the construction of members of this class of heterocycles [29]. The classical multicomponent synthesis may require extended reaction times and yields can be low if sterically hindered aldehydes are used [30]. 

Although not shown here, the mechanism for the formation of pyrazolopyri-dines 7 is similar [38]. 

The reaction was performed on four different solid supports (silica gel, acidic alumina, montmorUlonite K-10, and zeolite HY). The best results were obtained by use of silica gel. 

CFTR potentiator (F508del-CFTR Ka= 0.11 pM, G551D-CFTR Ka= 1.2 pM) with 250-fold selectivity over the L-type voltage-dependent Ca2+ channel [52,53], 

A series of 6-phenylpyrrolo[2,3-fc]pyrazines, initially described as CDK/GSK-3 inhibitors, were also shown to potentiate CFTR (wt, F508del, and G551D) [54]. Compound 10 was shown to potentiate multiple CFTR mutants with submicromolar affinity (140-152 nM on wt-CFTR (calu-3 and CHO cells), 1.5 nM on G551D (CHO cells), and lllnM on F508del-CFTR (temperature corrected CF15 cells)) and to stimulate trans-epithelial ion transport in the proximal colon of mice (wt) under short-circuit conditions with an affinity of 90 nM. 

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When pyridine is treated with zinc dust and acetic anhydride, a type of reductive coupling occurs and the product is diacetyltetrahydrodipyridyl (I) this undergoes a curious change on heating yielding pyridine and a new diacetyl compound, 1 4 diacetyl 1 4-dihydropyridine (II). The latter is reduced by zinc and acetic acid to 4-ethylpyridine (III). 

Specialtyydmines. Some substituted nitrogenous compounds can provide similar benefits. Esters of 2-aminocrotonate and bis-2-aminocrotonate, and appropriately substituted dihydropyridines, eg, 3,5-his-lauryloxycarhoxy-2,6-dimethyl-1,4-dihydropyridine [37044-66-7] and... 

Another important reaction of diketene derivatives is the Hant2sch 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-alkyhdene 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). 

Hansa Yellows, 1, 334 5, 299 Hantzsch synthesis, 2, 87-88 1,4-dihydropyridine, 2, 482 thiazoles, 6, 294-299 A -thiazolines, 6, 314 Hantzsch-Widman names parent names, 1, 35 stem suffixes, 1, 12 Hantzsch-Widman system nomenclature, 1, 11-12 Hardeners in photography... 

Even more highly selective ketone reductions are earned out with baker s yeast [61, 62] (equations 50 and 51) Chiral dihydronicotinamides give carbonyl reductions of high enantioselectivity [63] (equation 52), and a crown ether containing a chiral 1,4-dihydropyridine moiety is also effective [64] (equation 52). 

Analogous to DPNH (144-146), 1,4-dihydropyridines (147) act as reducing agents. For instance, the conversion of aromatic nitro compounds to amines (148) and reduction of enones to ketones (749) has been achieved. 

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. 

Once formed, 7 and 8 undergo a Michael reaction that gives rise to ketoenamine 9. Ring closure, to form 10, and loss of water then afforded 1,4-dihydropyridine 11. The presence of 9 and 10 could not be detected thus ring closure and dehydration were deduced to proceed faster than the Michael addition. This has the result of making the Michael addition the rate-determining step in this sequence. Conversely, if the reaction is run in the presence of a small amount of diethylamine, compounds related to 10 could be isolated. Diol 20 has been isolated in an unique case (R = CFb). Attempts to dehydrate this compound under a variety of conditions were unsuccessful. Stereoelectronic effects related to the dehydration may be the cause. In related heterocyclic ring formations, it has been determined that dehydration (20 —> 10) is about 10 times slower than diol formation (19 —> 20). Therefore, one would expect 20 to... 

Subsequent to Hantzsch s communication for the construction of pyridine derivatives, a number of other groups have reported their efforts towards the synthesis of the pyridine heterocyclic framework. Initially, the protocol was modified by Beyer and later by Knoevenagel to allow preparation of unsymmetrical 1,4-dihydropyridines by condensation of an alkylidene or arylidene P-dicarbonyl compound with a P-amino-a,P-unsaturated carbonyl compound. Following these initial reports, additional modifications were communicated and since these other methods fall under the condensation approach, they will be presented as variations, although each of them has attained the status of named reaction . 

It has been shown that TMSI is capable of mediating the reaction at room temperature. The classical three component coupling was carried out using aldehyde 82 and ketoester 83 with ammonium acetate in acetonitrile at room temperature with in situ generated TMSI. This gave a 73-80% yield of 1,4-dihydropyridines 84 in 6-8 h. The best results were obtained with 1 equivalent of TMSCl and 1 equivalent of Nal. 

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. 

Two- and three-component Hantzsch reactions using C-glycosylated reagents have been reported as an alternate method for conducting asymmetric syntheses of 1,4-dihydropyridines." ° Reaction of 109, 110 and 97 generate 111 with Ri = sugar. Alternatively, 112 and 113 produce 111 with Ri = sugar. While the yields were acceptable (60-90%), the diastereomeric ratio varied from 30-60%. 

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. ... 

An interesting result has been observed when 4-formylantipyrine 89 was converted into the corresponding pyridinium salt 90 and reacted with alkyl 3-aminobut-2-enoates. Tire expected 1,4-dihydropyridines 91 are transient species in these syntheses and readily lose the 4-substituent (antipyrine, 93) so that dialkyl 2,6-dimethylpyridine-3,5-dicarboxylates 92 are obtained (85-95%) (94H815). Protonation of the pyrazole ring by the evolved hydrochloric acid accounts for this particular behavior (Scheme 29). 

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,... 

Dihydropyridines 8 react with dienophiles such as A -phenyl maleimide (2) and l,2,4-triazoline-3,5-dione 9 to give the Diels-Alder adducts 10 and 11, respectively (76JHC481). Fowler observed that when a mixture of 1,2- and 1,4-dihydropyridines was treated with maleic anhydride (12), only 1,2-dihydro-pyridines yielded the Diels-Alder adducts 13, whereas the 1,4-dihydropyridines showed no reactivity with 12 (72JOC1321) (Scheme 1). 

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... 

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). 

The iminium salt 165, derived from acid treatment of 1,4-dihydropyridine 164, on intramolecular cyclization on the indole nucleus gave pentacyclic compound 166 (83T3673). The tmns stereochemistry of H3 and H9 in 166 (biogenetic... 

The methodology based on the addition of nucleophiles at the a- and y -positions of A -alkylpyridinium salts to give substituted 1,2- and 1,4-dihydropyridines (often not isolated) as intermediates, respectively, which can be further elaborated into complex polycyclic alkaloids, was reviewed by Joan Bosch and M.-Lluiesa Bennasar in 1995 (95SL587). 

The iodocyclization of 1,4-dihydropyridines was used as the key step for the formal total synthesis of Sempervirine (327) as shown in Scheme 102 (99JOC2997). 

Reaction of 1 mole of aminals 352 with 4 mol of methyl 3-aminocrotonate in the presence of the solid acids montmorillonte clay (Kio) and ZF520 zeolite as strong Bronsted acidic catalysts, gave 1,4-dihydropyridines 353 and 2-methyl-4//-pyrido[l, 2-n]pyrimidin-4-one (99MI8). 

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