Quinoline nucleus

This coupling works best when the halogen at the 7-position is bromine rather than chlorine or fluorine. This represents the first appUcation of this coupling reaction to the intact quinoline nucleus and thus represents an important advance in quinolone chemistry. 

In 1931 Ing pointed out that formula (II) and (III) do not contain methyl or potential methyl groups in j ositions 6 and 8 which they occupy in cytisoline. Further, a partially reduced quinoline ought to oxidise easily to a benzenecarboxylic acid and so far the only simple oxidation, products recorded from cytisine were ammonia, oxalic acid and isovaleric acid. Distillation of cytisine with zinc dust or soda-lime yields pyrrole and pyridine, but no quinoline. On these grounds Ing suggested that cytisine should be formulated without a quinoline nucleus, and that the reactions which indicate the presence of an aromatic nucleus in the alkaloid can be accounted for by an a-pyridone ring. This a-pyridone nucleus can... 

These results indicate that quinine and quinidine differ in structure from cinchonine and cinehonidine in containing a methoxyl group in position 6 in a quinoline nucleus. The identity of the other oxidation products, meroquinenine, cincboloiponic and loiponic acids, in all foiu" cases indicates that the second half of the molecule has the same structure in all four alkaloids. Further, this second half must be joined to the quinoline nucleus at position 4 by a group capable of conversion into carboxyl. 

These hydrolyses afford further evidence of the existence in the four alkaloids of a quinoline nucleus and of a second ring system containing a nitrogen atom. The formulae of the two alkaloids may, therefore, be extended thus Cinchonine, CgHjN. CiqHj5(OH)N Quinine,... 

In opocinchenine the hydroxyl group must, therefore, be in the ortho-position relative to the point of attachment of the benzene ring to the quinoline nucleus. The relative positions of the two ethyl groups are determined by the fact that apocincheninic acid ethyl ether on oxidation with lead peroxide and sulphuric acid gives the lactone of hydroxyopo-cincheninic acid ethyl ether (I), which, on oxidation by sodium hypo-bromite, yields quinolylphenetoledicarboxylic acid (II). 

These substances differ structurally from niquidine (VI) by the substitution in the latter of a propylidene chain at C. Ainley and King having already found that d- and Z-dihydroquinicinols (VIII) which are y-substituted piperidine derivatives, were inactive, it appeared from these two sets of results that the strongly basic centre should not be separated by more than two carbon atoms frorn the point of attachment to the quinoline nucleus. King and Work therefore prepared a series of... 

Work also prepared a series of carbinolamines and polyamines without a quinoline nucleus but, in other respects, conforming in type and range of molecular weight, with quinoline compounds known to possess plasmocidal activity. As none of these were active, it seems clear that the quinoline nucleus in the cinchona alkaloids and in certain synthetic anti-malarials is a potent factor in the production of plasmocidal action. Later the same author made (1942) a series of lepidylamine derivatives of the form R. Q. CHj. NH[CH2] . NEtj, which were found to be inactive, in spite of their similarity to the active examples of the type R. Q. NH[CH2] . NEt2 prepared by Magidson and Rubtzow. Rubtzow (1939) has also shown that an isomeride of dihydroquinine (II) with the quinuclidine nucleus attached via the carbinol group at C in the quinoline nucleus was inactive in an infection of Plasmodium prcecox in finches. 

During indolization of the 3, 6 and 7-quinolylhydrazones, formation of the new C-C bond occurs between the appropriate carbon atom of the ketone/aldehyde moiety and the 4, 5 and 8 carbon atoms of the quinoline nucleus. It is consistent with the mechanism of formation of the C-C bond during indolization and the direction of electrophilic substitution in the quinoline nucleus. °... 

The thalleiochin reaction for the specific detection of quinine alkaloids carrying an oxygen group at C-6 of the quinoline nucleus (e. g. quinine and quinidine) [17], or the... 

Abou-Ouf et al. [16] described a spectrophotometric method for the determination of primaquine phosphate in pharmaceutical preparation. Two color reactions for the analysis of primaquine phosphate dosage form, which are based on 2,6-dichlor-oquinone chlorimide and l,2-naphthoquinone-4-sulfonate, were described. The reactions depend on the presence of active centers in the primaquine molecule. These are the hydrogen atoms at position 5 of the quinoline nucleus and the primary amino group of the side chain. The method was applied to tablets of primaquine phosphate and a combination of primaquine phosphate and amodiaquine hydrochloride. 

Macrocyclic antibiotics also include a family of thiopeptides, of which thiostrepton (Figure 2.11) is the parent compound and the most complex member. Produced by Streptomyces azureus [59], thiostrepton includes 10 rings, 11 peptide bonds, extensive unsaturation, an imine functionality, a secondary amine, and 17 stereogenic centers [60] it also contains five thiazole rings and one quinoline nucleus. 

More recently, a catalyst-free aqueous version of this strategy was proposed with simple acyclic 1,3-dicarbonyls, formaldehyde, and styrene or anilines derivatives (Scheme 40) [131], In the first case (Scheme 40), the very reactive 2-methylene-1,3-dicarbonyl intermediate reacts smoothly at 80°C with a variety of substituted styrenes to give the corresponding dihydropyrans in moderate to good yields. Remarkably, when styrenes were replaced by A-ethylaniline, a novel five-component reaction involving twofold excess of both formaldehyde and 1,3-dicarbonyl selectively occurred (Scheme 41). The result is the formation of complex fused pyranoquinolines following a Friedel-Craft alkylation - dehydration sequence to furnish the quinoline nucleus, which suffers the Hetero-Diels-Alder cyclization in synthetically useful yields. 

The indole nucleus can change during the synthesizing reaction into quinoline nucleus (Figure 32). Moreover L-tryptophan, the precursor, provides both /3-carboline and pyrroloindole nuclei. Iboga, Corynanthe and Aspidosperma nuclei also originate from L-tryptophan (Figure 32). Alkaloids with nuclei derived from this amino acid tend to be very active compounds with a relatively widespread provenance in nature (Table 10). 

The quinoline nucleus sometimes serves as a surrogate for aromatic moieties this is illustrated by two NSAlDs that are closely related to the anthranUic acid fenac ... 

Consequently, Dehmlow and coworkers modified the cinchona alkaloid structure to elucidate the role of each ofthe structural motifs of cinchona alkaloid-derived chiral phase-transfer catalysts in asymmetric reactions. Thus, the quinoline nucleus of cinchona alkaloid was replaced with various simple or sterically bulky substituents, and the resulting catalysts were screened in asymmetric reactions (Scheme 7.2). The initial results using catalysts 8-11 in the asymmetric borohydride reduction of pivalophenone, the hydroxylation of 2-ethyl-l-tetralone and the alkylation of SchifF s base each exhibited lower enantiomeric excesses than the corresponding cinchona alkaloid-derived chiral phase-transfer catalysts [14]. 

Quinophthalone Dyes. Currently, 3 -hydroxyquinophthalone [7576-65-0] is employed extensively in a number of product lines used to dye synthetic fibers in greenish yellow hues with good lightfastness and generally sufficient sublimation-fastness. Suitable substitution in the phthalic acid residue or the quinoline nucleus may improve thermosetting fastness [29], An example is C.I. Disperse Yellow54, 47020 [7576-65-0] (10) ... 

Cava and coworkers demonstrated that ceric ammonium nitrate oxidation of 4,6,7-trimethoxytryptamines, followed by cyclization, can efficiently generate the pyrrolo[4,3,2-de]quinoline nucleus which forms the heterocyclic core of a group of marine alkaloids which includes the makaluvamines and discorhabins. <95JOC 1800> Previous studies in this area have shown that the methoxy group can subsequently be replaced by amines to provide the natural substances. 

By contrast, substitution in position 7 is much easier thanks to the well-known Minisci reaction, which involves a nucleophilic radical attack on a protonated quinoline [31]. Moreover, due to the unavailability of position 2 of the quinoline nucleus, the reaction shows complete regioselectivity. Minisci alkylation with an ethyl radical produced in situ by decarbonylation of propionaldehyde is a crucial step in the process of preparation of irinotecan (4) (Scheme 16.6) [32], whereas the same kind of reaction led to the semisynthesis (Scheme 16.7) of gimatecan (9)[33], silatecan (10)[34], and belotecan (ll)[35j. This last compound entered clinical practice in Korea in 2005. 

Disposition in the Body. Metabolised by 2 -hydroxylation of the quinoline nucleus followed by 2-hydroxylation of the quinucli-dine ring both 2 -hydroxycinchonidine and 2,2 -dihydroxycin-chonidine have been detected in urine. 

Using the approach of constructing the quinoline nucleus onto a triazole skeleton, 3-hydroxymethyl-l,2,4-triazolo-4-ylbenzophenone (233) was... 

BQC is derived from quinine, which is a member of the cinchona family of alkaloids. Ammonium salts derived from quinidine, a diastereomer of (1) at the hydroxyl substituent, have been used less frequently in catalysis than BQC. Quini-dinium salts often give rise to products with enantioselectivity opposite to that from (1). Other related compounds, such as those derived from cinchonine and cinchonidine (which lack the methoxy substituent on the quinoline nucleus), have found application in organic synthesis. The cinchona alkaloids, as well as salt derivatives in which the benzyl group bears various substituents, have also been studied. Results from polymer-bound catalysts have not been promising. ... 

Cinchona species (Rubiaceae) are sources of quinine and quinidine, containing a quinoline nucleus and derived through the extensive elaboration of strictosidine (Fig. 42). The intriguing history of the antimalarial quinine and its role in world politics over the past 350 years are legendary. It is frequently the only antimalarial drug to which patients are not resistant. Its widest use, however, is in the beverage industry in tonic water. Quinidine, an isomer of quinine, is used to treat cardiac arrythmias. 

The structural elucidation was completed by the use of NMR-spectro-scopy (7) to show that the Bz-methoxy group is attached at the 8-position of the quinoline nucleus, and that the side chain C3H7 is an isopropyl group, as would be expected on biogenetic grounds. Thus the alkaloids lunacrine and lunacridine are XXXIV and XXXV, respectively. 

---