Alkenes Sharpless asymmetric dihydroxylation

More recently, in light of the development of the Sharpless asymmetric dihydroxylation protocol [20], we have approached the synthesis of diols such as 14 (Scheme 2) from the alkene. Thus, treatment of the alkenyl D-glucosides 15 vmder the conditions of the Sharpless dihydroxylation gave a range of diols 16 with varying diastereoisomeric excesses (Table 1). One of these mixtures of diols, upon recrystallization, yielded the pure diastereoisomer, namely the diol 14. This procedure now gives a very rapid and efficient entry into one of the precursor diols for the synthesis of the optically-pure epoxides [21]. 

It was of obvious interest to prepare the inhibitors 60 as their pure dia-stereoisomers, 66 and 67. Following on from our successful treatment of alkenyl D-glucosides under Sharpless asymmetric dihydroxylation conditions [21], we treated the alkenes 64 with the a-AD - and AD -mLxes - the results are summarized in Table 2. In no case did we ever obtain a satisfactory diastereo-isomeric excess of the diol 68 over the diol 69, or vice versa. A similar lack of stereoselectivity was also obtained with the triol 70 and the amine 71 [48]. 

Transformation of alkene 9 into diol 30 is a Sharpless asymmetric dihydroxylation.8 Its catalytic cycle with K3Fe(CNV, as co-oxidant is shown below. 

Once this and the principle of stereocontrol of Sharpless asymmetric dihydroxylations is understood it is clear that both cis- and /ra/ ,v-disubsti luted alkenes allow for two orientations in the transition state. See for yourself by explicitly writing down the corresponding dihydroxylations according to the general format laid out in Figure 17.21 (part II) based on cis-... 

Jacobsen epoxidation turned out to be the best large-scale method for preparing the cis-amino-indanol for the synthesis of Crixivan, This process is very much the cornerstone of the whole synthesis. During the development of the first laboratory route into a route usable on a very large scale, many methods were tried and the final choice fell on this relatively new type of asymmetric epoxidation. The Sharpless asymmetric epoxidation works only for allylic alcohols (Chapter 45) and so is no good here. The Sharpless asymmetric dihydroxylation works less well on ris-alkenes than on trans-alkenes, The Jacobsen epoxidation works best on cis-alkenes. The catalyst is the Mn(III) complex easily made from a chiral diamine and an aromatic salicylaldehyde (a 2-hydroxybenzaldehyde). 

The Sharpless asymmetric dihydroxylation works best for tram disubstituted alkenes, while the Jacobsen epoxidation works best for cis disubstituted alkenes. Even in this small area, there is a need for better and more general methods. Organic chemistry has a long way to go. 

Asymmetric dihydroxylation Sharpless developed a catalytic system (AD-mix- 3 or AD-mix-a) that incorporates a chiral ligand into the oxidizing mixture which can be used for the asymmetric dihydroxylation of alkenes. The chiral ligands used in Sharpless asymmetric dihydroxylation are quinoline alkaloids, usually dihydroquinidine (DHQD) or dihydroquinine (DHQ) linked by a variety of heterocyclic rings such as 1,4-phthalhydrazine (PHAL) or pyridazine (PYR) (see section 1.6, reference 32 of Chapter 1). 

Aminohydroxylation of unsymmetrically substituted alkenes, in contrast to dihydroxylation, may give two possible regioisomers of aminoalcohol derivatives but asymmetric aminohydroxylation, by using the same catalytic system as that used for Sharpless asymmetric dihydroxylation, can be highly regioselective as well as enantioselective. 

Sharpless asymmetric dihydroxylation One-pot enantioselective synthesis of vicinal diols from simple alkenes. 406... 

Equation 12.16 is an example of the Sharpless-Katsuki asymmetric epoxi-dation of allylic alcohols, which is catalyzed by a Ti complex bound to a chiral tartrate ligand.38 A Mn-salen39 complex serves as catalyst for asymmetric epoxi-dation (Jacobsen-Katsuki reaction) of a wide variety of unfunctionalized alkenes, shown in equation 12.17.40 0s04 complexed with chiral alkaloids, such as quinine derivatives (equation 12.18), catalyzes asymmetric 1,2-dihydroxylation of alkenes (known as the Sharpless asymmetric dihydroxylation).41 The key step of all these transformations is the transfer of metal-bound oxygen, either as a single atom or as a pair, to one face of the alkene. 

The relative ease of cyclization with primary electrophilic centers prompted Smith and coworkers to use this method in their scalable route to (+)-spongistatin 1 (Scheme 15) [36]. Sharpless asymmetric dihydroxylation of alkene 48 provided diol 49, which underwent cyclization in the presence of sodium methoxide to afford THP 50 in 85 % yield over two steps as a single diastereomer. 

The catalytic asymmetric dihydroxylation reaction developed by Sharpless (Sharpless asymmetric dihydroxylation [SAD]) allows the straightforward oxidation of alkenes 76 to the corresponding cw-diols 77 with good to excellent yields and enantioselectivities without suffering from the presence of oxygen and moisture. The core of the catalytic system is based on an Os(VIII) metal center that coordinates the alkenes and transfers an oxygen atom to it using KsFe (CN)6 as terminal oxidant in the presence of enantiopure tertiary amines derived by dihydroquinidine 78 or... 

Phenatic acids are a class of potent antifungal natural products that were isolated from the culture of Strepto-myces sp. K03-0132. In particular, phenatic acid B 83 presents for possible stereoisomers because of the presence of two stereogenic centers. Fernandes and Chowd-hury presented the synthesis of all four stereoisomers with a procedure based on the creation of the stereocenters via Sharpless asymmetric dihydroxylation (Scheme 34.23). In detail, the alkene 84 was oxidized with AD-mix-(3 under standard conditions leading to the corresponding dihydroxylated product 85 with 88% yield and excellent 99% ee that was further elaborated for the synthesis of the two stereoisomers of phenatic acid B 83 reported in Scheme 34.23. The other two isomers were obtained employing the AD-mix-a in the dihydroxylation step with 87% yield and 98% ee. 

We already know how to produce 1,2-diols from the reactions of alkenes we studied in Chapter 11. We can make cis-diols using osmium tetroxide-mediated dihydroxylation, tra s-diols by ring opening of epoxides, and chiral diols by Sharpless asymmetric dihydroxylation (Figure 20.1). tra s-l,2-Amino alcohols can be prepared by ring opening of epoxides, and there is a version of the Sharpless dihydroxylation that leads to chiral amino alcohols. 

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 ... 

Since Sharpless discovery of asymmetric dihydroxylation reactions of al-kenes mediated by osmium tetroxide-cinchona alkaloid complexes, continuous efforts have been made to improve the reaction. It has been accepted that the tighter binding of the ligand with osmium tetroxide will result in better stability for the complex and improved ee in the products, and a number of chiral auxiliaries have been examined in this effort. Table 4 11 (below) lists the chiral auxiliaries thus far used in asymmetric dihydroxylation of alkenes. In most cases, diamine auxiliaries provide moderate to good results (up to 90% ee). 

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. 

About a decade after the discovery of the asymmetric epoxidation described in Chapter 14.2, another exciting discovery was reported from the laboratories of Sharpless, namely the asymmetric dihydroxylation of alkenes using osmium tetroxide. Osmium tetroxide in water by itself will slowly convert alkenes into 1,2-diols, but as discovered by Criegee [15] and pointed out by Sharpless, an amine ligand accelerates the reaction (Ligand-Accelerated Catalysis [16]), and if the amine is chiral an enantioselectivity may be brought about. 

Sharpless stoichiometric asymmetric dihydroxylation of alkenes (AD) was converted into a catalytic reaction several years later when it was combined with the procedure of Upjohn involving reoxidation of the metal catalyst with the use of N-oxides [24] (N-methylmorpholine N-oxide). Reported turnover numbers were in the order of 200 (but can be raised to 50,000) and the e.e. for /rara-stilbene exceeded 95% (after isolation 88%). When dihydriquinidine (vide infra) was used the opposite enantiomer was obtained, again showing that quinine and quinidine react like a pair of enantiomers, rather than diastereomers. 

After the "asymmetric epoxidation" of allylic alcohols at the very beginning of the 80 s, at the end of the same decade (1988) Sharpless again surprised the chemical community with a new procedure for the "asymmetric dihydroxylation" of alkenes [30]. The procedure involves the dihydroxylation of simple alkenes with N-methylmorpholine A -oxide and catalytic amounts of osmium tetroxide in acetone-water as solvent at 0 to 4 °C, in the presence of either dihydroquinine or dihydroquinidine p-chlorobenzoate (DHQ-pClBz or DHQD-pClBz) as the chiral ligands (Scheme 10.3). 

Other functionalized supports that are able to serve in the asymmetric dihydroxylation of alkenes were reported by the groups of Sharpless (catalyst 25) [88], Sal-vadori (catalyst 26) [89-91] and Cmdden (catalyst 27) (Scheme 4.13) [92]. Commonly, the oxidations were carried out using K3Fe(CN)g as secondary oxidant in acetone/water or tert-butyl alcohol/water as solvents. For reasons of comparison, the dihydroxylation of trons-stilbene is depicted in Scheme 4.13. The polymeric catalysts could be reused but had to be regenerated after each experiment by treatment with small amounts of osmium tetroxide. A systematic study on the role of the polymeric support and the influence of the alkoxy or aryloxy group in the C-9 position of the immobilized cinchona alkaloids was conducted by Salvadori and coworkers [89-91]. Co-polymerization of a dihydroquinidine phthalazine derivative with hydroxyethylmethacrylate and ethylene glycol dimethacrylate afforded a functionalized polymer (26) with better swelling properties in polar solvents and hence improved performance in the dihydroxylation process [90]. 

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