Dihydroquinine

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. 

Hydroquinine (Dihydroquinine), C20H26O2N2.2H2O. This base was isolated by Hesse from the mother liquors of quinine sulphate manufacture and is present to the extent of 5 to 6 per cent, in commercial sulphate of quinine, from which it is best isolated by the mercuric acetate process. The demand for hydroquinine as such and as a material for the preparation of hydrocupreine has led to its manufacture from quinine by catalytic hydrogenation. It crystallises from ether or benzene in needles, m.p. 173 5° (dry), — 235 7° (c = M/40, N/10 H2SO4) or... 

Hydrocupreine (Dihydrocupreine), CigH2402N2. This alkaloid does not occur naturally, but can be produced by demethylating dihydroquinine or reducing cupreine. It crystallises from dilute alcohol in minute needles or from a mixture of chloroform and benzene in warty masses, m.p. 230° (dec.) with some sintering at 185-200°, is readily soluble in chloroform, alcohol or hot benzene, and much less so in ethyl acetate, insoluble in light petroleum, — 155-5° (G. and Wi ° 148-7°... 

Using the (— )-Aowocincholoipon produced as described, Rabe and Schultze, by the same sequence of reactions, have produced (—)-dihydro-quininone (m.p. 98-9[a]f, ° — 70-0° (final value EtOH)), which on hydrogenation in presence of palladium gave a mixture of bases, of which (—)-dihydroquinidine and (-j-)-dihydroquinine were isolated. The characters of these mirror-image isomerides of dihydroquinidine and dihydroquinine respectively have been given already with the directions of rotation at the centres of asymmetry C , C , C , C (see table, p. 446). 

The important role played by the quinicines (rubatoxanones, quina-toxines) in the syntheses of the dihydrocinchona alkaloids and the possibility that such substances might be used for the preparation of products approaching quinine in therapeutical interest, has led to the production of a large number of quinolyl ketones of various types and the corresponding secondary alcohols, and other derivatives obtainable from them, of which mention may be made of Rubtzov s syntheses of several isomerides of dihydroquinine. ... 

Q =6-Methoxy-quinolyl in formulae (p, 449). Quinidine (0-5) Quinine (I-O) Dihydro-quinidine (0-5-1-0) Dihydroquinine (1-2) opoQuinidine methyl ether (1-0) a-isoQuinine (0-02). j8-i.9oQuinine (0-C9) a-isoQuinidine (0-0C5) 8-isoQuinidine (01) y-isoQuinidine (inactive) a-Hydroxydi- hydroquinine (0-54) Niquidine (1-45) isoNiquidine (1-05) Niquine (0-86)... 

On these results the primary cinchona alkaloids and their dihydroderivatives arrange themselves in the following descending order of activity (1) dihydroquinine, (2) quinine, (3) dihydroquinidine, (4) cincho-nidine and quinidine, (5) cinchonine, dihydrocinchonidine and dihydrocinchonine. 

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. 

Another important reaction associated with the name of Sharpless is the so-called Sharpless dihydroxylation i.e. the asymmetric dihydroxylation of alkenes upon treatment with osmium tetroxide in the presence of a cinchona alkaloid, such as dihydroquinine, dihydroquinidine or derivatives thereof, as the chiral ligand. This reaction is of wide applicability for the enantioselective dihydroxylation of alkenes, since it does not require additional functional groups in the substrate molecule ... 

The actual catalyst is a complex formed from osmium tetroxide and a chiral ligand, e.g. dihydroquinine (DHQ) 9, dihydroquinidine (DHQD), Zj -dihydroqui-nine-phthalazine 10 or the respective dihydroquinidine derivative. The expensive and toxic osmium tetroxide is employed in small amounts only, together with a less expensive co-oxidant, e.g. potassium hexacyanoferrate(lll), which is used in stoichiometric quantities. The chiral ligand is also required in small amounts only. For the bench chemist, the procedure for the asymmetric fihydroxylation has been simplified with commercially available mixtures of reagents, e.g. AD-mix-a or AD-mix-/3, ° containing the appropriate cinchona alkaloid derivative ... 

Osmium tetroxide oxidations can be highly enantioselective in the presence of chiral ligands. The most highly developed ligands are derived from the cinchona alkaloids dihydroquinine (DHQ) and dihydroquinidine (DHQD).45 The most effective... 

Both quinine and dihydroquinine favored the required (S)-enantiomer. A small ee difference of the product might be due to inconsistent purity of the naturally obtained cinchona alkaloids. It was noted that quinidine (the pseudo-enantiomer of quinine) gave the (R)-enantiomer with a similar 55% ee. Since quinine was... 

In 1980, Hengtges and Sharpless published a seminal report that dihydroxylation occurred in a good enantioselective manner when the reaction was carried out in the presence of a chiral amine, dihydroqunidine acetate (DHQD-Ac) or dihydroquinine acetate (DHQ-Ac). DHQD and DHQ are diastereomers to each other, but they behaved like enantiomers in this reaction (Scheme 42).167... 

The 1,2-diol is liberated easily from cyclic osmate ester by either reductive or oxidative hydrolysis.213 Importantly, the ligand acceleration has been utilized extensively for the production of chiral 1,2-diols from (achiral) olefins using optically active amine bases (such as L = dihydroquinidine, dihydroquinine and various chiral diamine ligands).215... 

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... 

In summary, the reaction of osmium tetroxide with alkenes is a reliable and selective transformation. Chiral diamines and cinchona alkakoid are most frequently used as chiral auxiliaries. Complexes derived from osmium tetroxide with diamines do not undergo catalytic turnover, whereas dihydroquinidine and dihydroquinine derivatives have been found to be very effective catalysts for the oxidation of a variety of alkenes. OsC>4 can be used catalytically in the presence of a secondary oxygen donor (e.g., H202, TBHP, A -methylmorpholine-/V-oxide, sodium periodate, 02, sodium hypochlorite, potassium ferricyanide). Furthermore, a remarkable rate enhancement occurs with the addition of a nucleophilic ligand such as pyridine or a tertiary amine. Table 4-11 lists the preferred chiral ligands for the dihydroxylation of a variety of olefins.61 Table 4-12 lists the recommended ligands for each class of olefins. 

Also fifteen years of painstaking work and the gradual improvement of the system, the Sharpless team announced that asymmetric dihydroxylation (AD) of nearly every type of alkene can be accomplished using osmium tetraoxide, a co-oxidant such as potassium ferricyanide, the crucial chiral ligand based on a dihydroquinidine (DHQD) (21) or dihydroquinine (DHQ) (22) and metha-nesulfonamide to increase the rate of hydrolysis of intermediate osmate esters 1811. 

DHQ)PHN and (DHQ)2PHAL are the respective abbreviations of dihydroquinine 9-phenan-thryl ether and of dihydroquinidine 1,4-phthalazinediyl diether. 

Asymmetric catalytic osmylation.s Chiral cinchona bases are known to effect asymmetric dihydroxylation with 0s04 as a stoichiometric reagent (10, 291). Significant but opposite stereoselectivity is shown by esters of dihydroquinine (1) and of dihydroquinidine (2), even though these bases are diastereomers rather than enantiomers. 

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