Organism Cinchona

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-... 

Pinworm is a helminHi infection that is universally common most oHier helminth infections are predomi-lianHy found in countries or areas of the world that lack proper sanitary facilities. Malaria is rare in the United States, but it is sometimes seen in individuals who have traveled to or lived in areas where this disease is a healtii problem. The first antimalarial drug, quinine, is derived from the bark of the cinchona tree. Amebiasis is seen Hiroughout the world, but it is less common in developed countries where sanitary facilities prevent Hie spread of the causative organism. 

Cathanthus roseus Nicotiana tabacum Cinchona robusta Tabernaemontana divaricata 3-1 STR (2 1 wv) D 4.5 cm batch and chemostat N 2.5 -16.7 s Q 0.33 wm t < 30 d biomass production total organic carbon extracellular protein membrane integrity substrate consumption [107]... 

The mobility factor acknowledges the fact that organic molecules seem to move about on surfaces. For example, Blackmond and Augustine and associates have identified an induction period in the cinchona alkaloid modified... 

Catalytic enantioselective nucleophilic addition of nitroalkanes to electron-deficient alke-nes is a challenging area in organic synthesis. The use of cinchona alkaloids as chiral catalysts has been studied for many years. Asymmetric induction in the Michael addition of nitroalkanes to enones has been carried out with various chiral bases. Wynberg and coworkers have used various alkaloids and their derivatives, but the enantiomeric excess (ee) is generally low (up to 20%).199 The Michael addition of methyl vinyl ketone to 2-nitrocycloalkanes catalyzed by the cinchona alkaloid cinchonine affords adducts in high yields in up to 60% ee (Eq. 4.137).200... 

The chapter Chiral Modification of Catalytic Surfaces [84] in Design of Heterogeneous Catalysts New Approaches based on Synthesis, Characterization and Modelling summarizes the fundamental research related to the chiral hydrogenation of a-ketoesters on cinchona-modified platinum catalysts and that of [3-ketoesters on tartaric acid-modified nickel catalysts. Emphasis is placed on the adsorption of chiral modifiers as well as on the interaction of the modifier and the organic reactant on catalytic surfaces. 

The Cinchona tree remains the only economically practical source of quinine. Although the development of synthetic quinine is considered a milestone in organic chemistry, it has never been produced industrially as a substitute for naturally occurring quinine. Nevertheless, the implications of the total synthesis of quinine in new strategies for the development of safer and more efficient antimalarial drugs, as we will show in the course of the next paragraphs, is priceless. But, let us discuss this total synthesis first. 

In this chapter, we discuss recent (reported mainly during 2000-2005) asymmetric reactions catalyzed by chiral bases. Because practicality is an important factor in the present asymmetric catalysis, we restricted our discussion mainly to the reactions giving over 90% ee unless the conversion is novel. We notice, however, that there are many potentially useful and scientifically interesting reactions, in which enantioselectivity does not exceed the practical range at this moment. Chiral organic base (proline and cinchona alkaloids)-catalyzed reactions were discussed in Chapter 11 by Lelais and MacMillan. 

Following the reaction, simple extraction provided access to both the hemiester prodnct and the alkaloid withont chromatography and the recovered cinchona alkaloid conld be reused with no deterioration in the ee or yield. This method has found use in the synthesis of P-amino alcohols and in natural product synthesis [198-201] and has recently been reported as an Organic Syntheses method [202],... 

Quinine—Chemical taken from the bark of the cinchona tree and used to treat fevers and to prevent malaria, an infection of a single-celled organism through a mosquito bite. 

Quinine is one of several alkaloids derived from the bark of the cinchona tree. The mechanism by which it exerts its antimalarial activity is not known. It does not bind to DNA at antimalarial dosages. It may poison the parasite s feeding mechanism, and it has been termed a general protoplasmic poison, since many organisms are affected by it. 

The availability of ctetq) advanced synthons that carry the required chirality is an advantage, particularly in projects aimed at industrial total synthesis. Natural products are often used as synthons, ideally fi om a renewable source, such as microbial fermentations. In a few cases, biotechnology has become an ahemative source. The total theses of the antitumor agent esperamicin A and the immunosuppressant FK-506 are exanq>les. In both cases, the synthon was quinic acid (Barco 1997), cheaply obtained by biotechnology (Chapter 14.1.e) rather than fi om the environmentally noxious extraction fi om the bark of Cinchona spp. Used to build up combinatorial libraries, quinic acid has gained further inq)ortance in organic thesis (Phoon 1999). 

The modification of platinum-group metals by adsorbed chiral organic modifiers has emerged as an efficient method to make catalytic metal surfaces chiral. The method is used to prepare highly efficient catalysts for enantioselective hydrogenation of reactants with activated C = O and C = C groups. The adsorption mode of the chiral modifier is crucial for proper chiral modification of the active metal surfaces. The most efficient chiral modifiers known today are cinchona alkaloids, particularly CD, which yields more than 90% enantiomeric excess in the hydrogenation of various reactants. 

This section will be organized according to catalyst systems a) Tartrate modified catalysts, b) Cinchona modified catalysts and c) Electrochemical systems. We are aware of no other reaction types where systematic investigations have been reported. 

---