Quinine alkaloids

Subs tituted-1,2,3-oxadiazolo[4,5-/]quinoline 47 originated after nitration, reduction, and diazotization of alkaloid quinine during the study of its stmcture and reactions (53RZC495, 54RZC61). 

The oldest effective drug for the treatment of this disease is indisputably quinine. Although the antipyretic activity of cinchona bark was known to the Incas, it remained for the Jesuit missionaries to uncover its antimalarial properties in the early seventeenth century. The advance of organic chemistry led to the isolation and identification of the alkaloid, quinine, as the active compound at the turn of this century. The emerging clinical importance of this drug led up to the establishment of cinchona plantations in the Dutch East Indies. This very circum-... 

Quinine alkaloids (quinine, cinchonine), barbiturate derivatives, retinol, calciferol and chole-calciferol... 

C18-0138. Quinine, an alkaloid derived from a free that grows in tropical rain forests, is used in the treatment of malaria. Like all alkaloids, quinine is a sparingly soluble weak base 1.00 g of quinine will dissolve in 1.90 X 10 L of water, (a) What is the pH of a saturated solution of quinine (b) A 100.0-mL sample of saturated quinine is titrated with 0.0100 M HCl solution. What is the pH at the stoichiometric point of the titration ... 

Cinchona alkaloids have been used as drugs for the treatment of several diseases. Quinine is very popular as an antimalarial drug against the erythrocyte stage of the parasite [34]. Recently, Shibuya et al. (2003) reported the microbial transformation of four Cinchona alkaloids (quinine, quini-dine, cinchonidine, and cinchonine) by endophytic fungi isolated from Cin-... 

Fig. 3 Structiu-es of Cinchona alkaloids (quinine, quinidine, cinchonidine, and cinchonine) transformed into their corresponding 1-N-oxide derivatives [34]...

Another microwave-mediated intramolecular SN2 reaction forms one of the key steps in a recent catalytic asymmetric synthesis of the cinchona alkaloid quinine by Jacobsen and coworkers [209]. The strategy to construct the crucial quinudidine core of the natural product relies on an intramolecular SN2 reaction/epoxide ringopening (Scheme 6.103). After removal of the benzyl carbamate (Cbz) protecting group with diethylaluminum chloride/thioanisole, microwave heating of the acetonitrile solution at 200 °C for 2 min provided a 68% isolated yield of the natural product as the final transformation in a 16-step total synthesis. 

The first attempt to effect the asymmetric cw-dihydroxylation of olefins with osmium tetroxide was reported in 1980 by Hentges and Sharpless.54 Taking into consideration that the rate of osmium(VI) ester formation can be accelerated by nucleophilic ligands such as pyridine, Hentges and Sharpless used 1-2-(2-menthyl)-pyridine as a chiral ligand. However, the diols obtained in this way were of low enantiomeric excess (3-18% ee only). The low ee was attributed to the instability of the osmium tetroxide chiral pyridine complexes. As a result, the naturally occurring cinchona alkaloids quinine and quinidine were derived to dihydroquinine and dihydroquinidine acetate and were selected as chiral... 

FIGURE 1.1 Chemistry and stereochemistry of the native cinchona alkaloids quinine, quinidine, cmchonidme, and cinchonine as well as their corresponding C9-epimeric compounds. 

The first silica-supported CSP with a cinchona alkaloid-derived chromatographic ligand was described by Rosini et al. [20]. The native cinchona alkaloids quinine and quinidine were immobilized via a spacer at the vinyl group of the quinuclidine ring. A number of distinct cinchona alkaloid-based CSPs were subsequently developed by various groups, including derivatives with free C9-hydroxyl group [17,21-27] or esterified C9-hydroxyl [28,29]. All of these CSPs suffered from low enantiose-lectivities, narrow application spectra, and partly limited stability (e.g., acetylated phases). 

It is also worthwhile to outline at this place the immobilization procedure that was used for the preparation of type I CSPs A bifunctional linker with a terminal isocyanate on one side and a triethoxysilyl group on the other end (3-isocyanatopropyl triethoxysilane) was reacted with the native cinchona alkaloids quinine and quinidine and subsequently the resultant carbamate derivative in a second step with silica [30], Remaining silanols have been capped with silane reagents, yet, are less detrimental for acidic solutes because of the repulsive nature of such electrostatic interactions. CSPs prepared in such a way lack the hydrophobic basic layer of the thiol-silica-based CSPs mentioned earlier, which may be advantageous for the separation of certain analytes. 

Buffered mobile phases are inherently used to adjust and control the adsorption-desorption process. These CSPs are especially useful for the separation of very polar charged analytes, such as sulphonic acids. Chiral anion-exchangers are the most successful CSPs and among them the cinchona alkaloids, quinine and quinidine (Figure... 

Quinidine Quinidine, (5-vinyl-2-quinychdinyl)-(6-methyoxy-4-quinolyl)-methanol (18.1.1) is the dextro-isomer of the alkaloid quinine and is one of the four most important alkaloids, which are isolated from the bark of the cinchona tree [1-3]. Quinidine is a secondary alcohol. 

The Soos group, in 2005, prepared the first thiourea derivatives from the cinchona alkaloids quinine QN (8S, 9R-121), dihydroquinidine DHQD (8S, 9S-122), C9-epi-QN (8S, 9P-123), and quinidine QD (SR, 9R-124) via an experimentally simple one-step protocol with epimerization at the C9-position of the alkaloid starting material (Figure 6.39) [278]. The catalytic efficiency of these new thiourea derivatives and also of unmodified QN and C9-epi-QN was evaluated in the enan-tioselective Michael addition [149-152] of nitromethane to the simple model chal-cone 1,3-diphenyl-propenone resulting in adduct 1 in Scheme 6.119. After 99h reaction time at 25 °C in toluene and at 10 mol% catalyst loading QN turned out to be a poor catalyst (4% yield/42% ee (S)-adduct) and C9-epi-QN even failed to accelerate the screening reaction. In contrast, the C9-modified cinchona alkaloid... 

V. Cinchona alkaloids Quinine (as suiphate) 600 mg/day, oral TDS or 10 mg/kg with 5% glucose IV infusion TDS (for cerebral malaria) for 7 days... 

Quinine is derived from the bark of the cinchona tree, a traditional remedy for intermittent fevers from South America. The alkaloid quinine was purified from the bark in 1820, and it has been used in the treatment and prevention of malaria since that time. Quinidine, the dextrorotatory stereoisomer of quinine, is at least as effective as parenteral quinine in the treatment of severe falciparum malaria. After oral administration, quinine is rapidly absorbed, reaches peak plasma levels in 1-3 hours, and is widely distributed in body tissues. The use of a loading dose in severe malaria allows the achievement of peak levels within a few hours. The pharmacokinetics of quinine varies among populations. Individuals with malaria develop higher plasma levels of the drug than healthy controls, but toxicity is not increased, apparently because of increased protein binding. The half-life of quinine also is longer in those with severe malaria (18 hours) than in healthy controls (11 hours). Quinidine has a shorter half-life than quinine, mostly as a result of decreased protein binding. Quinine is primarily metabolized in the liver and excreted in the urine. 

The tetracyclic alkaloid quinine 1 and the diastereomeric alkaloid quinidine 2 share a storied history. Eric Jacobsen of Harvard recently completed (J. Am. Chem. Soc. 2004, 126, 706) syntheses of enantiomerically-pure 1 and of 2. For each synthesis, the key reaction for establishing the asymmetry of the target molecule was the enantioselective conjugate addition developed by the Jacobsen group. 

A cursory examination of the Cinchona catalysts used in O Donnell-type alkylation [90] of methyl (diphenylimino)glycinate (Appendix 7.A) reveals that only minor modifications to the Cinchona scaffold are required for the synthesis of a catalyst the 8-substituent on the quinuclidine core may either be a vinyl group (as in the parent alkaloids, quinine and quinidine) or can be an ethyl substituent, introduced by hydrogenation. The quinoline system at the 2-position ofthe quinuclidine ring can be unsubstituted if the catalyst is derived from quinine or quinidine, but can contain a 6-methoxy group ifit is derived from cinchonine or cinchonidine. The 3-position ofthe quinuclidine ring may contain either a hydroxy group or else a vinyloxy or benzyloxy... 

Some of the most remarkable examples of terpenoid indole alkaloid modifications are to be found in the genus Cinchona (Rubiaceae), in the alkaloids quinine, quinidine, cinchonidine,... 

The alkaloid quinine occurs naturally in the bark of the Cinchona tree. Apart from its continued usefulness in the treatment of malaria, it can also be taken for the relief of nocturnal leg cramps (see Chapter 22). 

Following the development of synthetic antimalarial agents, such as chloroquine and mefloquine, the use of Cinchona alkaloid quinine declined. However, with the emergence of chloroquine-resistant and multiple-drug-resistant strains of malarial parasites, its use has become firmly reestablished. Quinine is the drug of choice for severe chloroquine-resistant malaria due to Plasmodium falciparum. In the U.S., the related alkaloid quinidine is recommended because of its wide availability and use as an antiarrhythmic agent. In many clinics in the tropics, quinine is the only effective treatment for severe malaria unfortunately, decreasing sensitivity of P. falciparum to quinine has already been reported from Southeast Asia. 

Alkaloids containing quinoline as the principal nucleus include anemonine from Anemone tha-lietroides, galipine from Angostura bark (Galipea officinalis), and the cinchona alkaloids, quinine, quinidine, cinchonine, and cinchonidine (Figure 11.8). 

Phase-transfer catalysis has been widely been used for asymmetric epoxidation of enones [100]. This catalytic reaction was pioneered by Wynberg et al., who used mainly the chiral and pseudo-enantiomeric quaternary ammonium salts 66 and 67, derived from the cinchona alkaloids quinine and quinidine, respectively [101-105],... 

The starting materials for the synthesis (few steps) of these phase-transfer catalysts, i.e. the cinchona alkaloids (—)-quinine, (+)-quinidine, (+)-cinchonine and (—)-cinchonidine, are commercially available in large quantities. 

Our approach to the antimalarial alkaloid quinine focuses on strategic application of the manganese-mediated hybrid radical-ionic annulation. Retrosyntheti-cally, this is illustrated (Scheme 5) by disconnection of either of two C-C bonds... 

Hydro-quinol, 1-4-Di-hydroxy Benzene.—The third isomeric dihydroxy benzene, viz., the para compound, i-4-di-hydroxy benzene, is known as hydro-quino or hydro-quinone. The latter name is derived from its relation to quinone (p. 636) from which it is obtained on reduction and which it yields on oxidation. Both hydro-quinol and quinone derive their names from the fact that they are obtained by the oxidation of quinic acid, an acid derived from the alkaloid quinine. The phenol is found in various plants or may be obtained from them by the hydrolysis of glucosides present, e.g., arbutin, which is a glucoside hydrolyzing into glucose and hydro-quinol. 

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