Cinchona alkaloid structure

There are a number of other synthetic substances analogous with or approximating to the cinchona alkaloid structure which it is more convenient to deal with in discussing the correlation of chemical structure with pharmacological action in this group (p. 469). 

Chondrodendron polyanthum, 371 Chondrodendron tomentosum, 363, 371, 373, 377, 391 alkaloids, 376 Chondrodine, 363, 364 Chondrofoline, 364, 365 Chrycentrine, 172, 313 Chiysanthemine, 773 Chrysanthemum cineraricefoHum, 773 Chuchuara, 781 Chuehuhuasha, 781 Cicuta virosa, 13 Cinchamidine, 419, 429 Cinchene, 439 Cinchenine, 438, 439, 440 apoCinchenine, 440, 441 Cincholoipon, 438 Cincholoiponic acid, 438, 443 Cinchomeronic acid, 183 Cinchona alkaloid structure, synthesis, 457 Cinchona alkaloids, bactericidal action of some derivatives, 478 centres of asymmetry, 445 constitution, 435 formulae and characters of transformation products, 449, 451 general formula, 443 hydroxydihydro-bases, 448, 452-4 melting-points and specific rotations, 446... 

The molecular modelling approach, taking into account the pyruvate—cinchona alkaloid interaction and the steric constraints imposed by the adsorption on the platinum surface, leads to a reasonable explanation for the enantio-differentiation of this system. Although the prediction of the complex formed between the methyl pyruvate and the cinchona modifiers have been made for an ideal case (solvent effects and a quantum description of the interaction with the platinum surface atoms were not considered), this approach proved to be very helpful in the search of new modifiers. The search strategy, which included a systematic reduction of the cinchona alkaloid structure to the essential functional parts and validation of the steric constraints imposed to the interaction complex between modifier and methyl pyruvate by means of molecular modelling, indicated that simple chiral aminoalcohols should be promising substitutes for cinchona alkaloid modifiers. Using the Sharpless symmetric dihydroxylation as a key step, a series of enantiomerically pure 2-hydroxy-2-aryl-ethylamines... 

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]. 

The reactions of the cinchona toxines are in general those to be expected of substances contmning the structural features known to be present. The ready formation of a-isonitroso derivatives (XXI), and the cleavage of the latter to cinchoninic acid derivatives and meroquinene or its congeners has been mentioned in Section I. The interesting reactions which permit reconstitution of the cinchona alkaloid structure from the toxines are discussed in Section IV. 

A catalytic enantio- and diastereoselective dihydroxylation procedure without the assistance of a directing functional group (like the allylic alcohol group in the Sharpless epox-idation) has also been developed by K.B. Sharpless (E.N. Jacobsen, 1988 H.-L. Kwong, 1990 B.M. Kim, 1990 H. Waldmann, 1992). It uses osmium tetroxide as a catalytic oxidant (as little as 20 ppm to date) and two readily available cinchona alkaloid diastereomeis, namely the 4-chlorobenzoate esters or bulky aryl ethers of dihydroquinine and dihydroquinidine (cf. p. 290% as stereosteering reagents (structures of the Os complexes see R.M. Pearlstein, 1990). The transformation lacks the high asymmetric inductions of the Sharpless epoxidation, but it is broadly applicable and insensitive to air and water. Further improvements are to be expected. 

It has already been shown that both the laevorotatory and dextrorotatory cinchona alkaloids on degradation yield scission products from the quinuclidine nucleus, which are structurally and optically identical, for example, meroquinenine, [a] -f- 27 6° d-/3-cincholoiponic acid. 

Not so long ago, the general opinion was that high enantioselectivity can only be achieved with natural, structurally unique, complex modifiers as the cinchona alkaloids. Our results obtained with simple chiral aminoalcohols and amines demonstrate the contrary. With enantiomeric excesses exceeding 80%, commercially available naphthylethylamine is the most effective chiral modifier for low-pressure hydrogenation of ethyl pyruvate reported to... 

Indicate the structural elements that are crucial for the functioning of the cinchona alkaloids as chiral modifiers. 

The structures of quinine, cinchonidine, quinidine, and cinchonine are shown in Figure 3. Other workers (16,17) have discussed these alkaloids and their use as catalysts in some detail. An excellent discussion of cinchona-alkaloid-catalyzed reactions prior to 1968 was given by Pracejus (18). In this section we discuss only four aspects of these reactions. 

The overall steric demands of the catalyst and the substrate are important in the spatial arrangement of the H-bonded complex. Consequently, although the less rigid ephedrinium salts have been used with some success, they are generally less effective than the derivatives of the cinchona alkaloids, the rigidity of which imposes a greater stereochemical restraint on the structure of the H-bonded complexes. 

The catalyst is a combination of a chemo-catalyst and a natural product taken from the cinchona alkaloids giving amazing results. In phosphine catalysed asymmetric catalysis these types of structures are lacking, as nature does not produce phosphines ( ) and the phosphines used in the early years of development of asymmetric homogeneous catalysis lacked the complexity of... 

FIGURE 1.2 Structure and stereochemistry of commercially available cinchona alkaloid CSPs, marketed under trade name CHIRALPAK by chiral technologies europe. QN denotes quinine- and QD quinidine-derived and AX refers to their anion-exchanger capabilities vide infra). 

Since the last major review of the biosynthesis of the monoterpenoid indole alkaloids (97), there have been several full and partial 98-104) reviews of various aspects of the work that has been conducted since 1974. Two major developments have dominated the field in this period, namely, the demonstrations that (i) strictosidine (33) is the universal precursor of the monoterpenoid indole alkaloids and (ii) selected cell-free systems of C. roseus have the ability to produce the full range of alkaloid structure types, including the bisindoles. This section traces some aspects of these developments, paying particular attention to work been carried out with C. roseus, and omitting work, important though it may be, on other monoterpenoid indole alkaloid-producing plants, e.g., Rauwolfia, Campto-theca, and Cinchona. 

The advent of chiral Brpnsted base catalysis began with the recognition that the Cinchona alkaloids serve as excellent catalysts [7-12] and privileged structures... 

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