Allylic alcohols Sharpless asymmetric epoxidation

Asymmetric epoxidation of homoallylic alcohols. Sharpless asymmetric epoxidation of primary homoallylic alcohols with l-( + )-diethyl tartrate proceeds with only moderate enantiomeric selectivity (23-55% ee) and opposite to that observed with allylic alcohols. Unfortunately, operation at low temperatures to improve the enantiomeric excess also retards the rate drastically. Even so, this epoxidation provides a useful synthesis of (-l-)--y-amino-P(R)-hydroxybutyric acid (1). 

We will see Sharpless epoxidation reactions in the Double Methods section towards the end of the chapter. Interestingly, Sharpless other famous asymmetric method - dihydroxylation - has not found widespread use in kinetic resolution. This is probably because the AD is just too powerful or, to be anthropomorphic, too wilful. In other words, it is not sensitive to the chirality of the substrate and charges ahead and reacts with both enantiomers. That is not to say there are not examples of kinetic resolution with dihydroxylation,19 but they are more rare. However, the dihydroxylation is even more useful and much more general than the kinetic resolution of allylic alcohols by asymmetric epoxidation and was discussed in Chapter 25. A slightly complicated case of kinetic resolution of alcohols by asymmetric dihydroxylation is in the Double Methods section. 

Sharpless asymmetric epoxidation (SAE) is the epoxidation of allylic alcohols into asymmetric epoxides in high chiral purity (high enantioselectiv-ity). Transition metal catalyst Ti(OPr ) with chiral additive, diethyl tartarate (DET), generates chiral catalyst (Scheme 9.40) which is responsible for the enantioselective outcome, while, tert-butyl hydroperoxide (TBHP) serves as an oxidant. Although, this eatalytic system holds disadvantage of low turnover number (TON) with potential safety coneems for using concentrated solutions of peroxides, the reaction has nevertheless been extensively used in pharmaceutical industry [76]. 

The essential features of the Masamune-Sharpless hexose synthesis strategy are outlined in a general way in Scheme 4. The strategy is based on the reiterative- application of a two-carbon extension cycle. One cycle comprises the following four key transformations (I) homologation of an aldehyde to an allylic alcohol (II) Sharpless asymmetric epoxidation of the allylic alcohol ... 

The emergence of the powerful Sharpless asymmetric epoxida-tion (SAE) reaction in the 1980s has stimulated major advances in both academic and industrial organic synthesis.14 Through the action of an enantiomerically pure titanium/tartrate complex, a myriad of achiral and chiral allylic alcohols can be epoxidized with exceptional stereoselectivities (see Chapter 19 for a more detailed discussion). Interest in the SAE as a tool for industrial organic synthesis grew substantially after Sharpless et al. discovered that the asymmetric epoxidation process can be conducted with catalytic amounts of the enantiomerically pure titanium/tartrate complex simply by adding molecular sieves to the epoxidation reaction mix-... 

The construction of key intermediate 18 can be conducted along similar lines. Sharpless asymmetric epoxidation of allylic alcohol 22 using (+)-DET furnishes epoxy alcohol 52b (Scheme 11). Subjection of the latter substance to the same six-step reaction sequence as that leading to 54a provides allylic alcohol 54b and sets the stage for a second SAE reaction. With (+)-DET as the... 

A noteworthy feature of the Sharpless Asymmetric Epoxidation (SAE) is that kinetic resolution of racemic mixtures of chiral secondary allylic alcohols can be achieved, because the chiral catalyst reacts much faster with one enantiomer than with the other. A mixture of resolved product and resolved starting material results which can usually be separated chromatographically. Unfortunately, for reasons that are not yet fully understood, the AD is much less effective at kinetic resolution than the SAE. 

The development of Sharpless asymmetric epoxidation (SAE) of allylic alcohols in 1980 constitutes a breakthrough in asymmetric synthesis, and to date this method remains the most widely applied asymmetric epoxidation technique [34, 44]. A wide range of substrates can be used in the reaction ( ) -allylic alcohols generally give high enantioselectivity, whereas the reaction is more substrate-dependent with (Z)-allylic alcohols [34]. 

Allylic alcohols can be converted to epoxy-alcohols with tert-butylhydroperoxide on molecular sieves, or with peroxy acids. Epoxidation of allylic alcohols can also be done with high enantioselectivity. In the Sharpless asymmetric epoxidation,allylic alcohols are converted to optically active epoxides in better than 90% ee, by treatment with r-BuOOH, titanium tetraisopropoxide and optically active diethyl tartrate. The Ti(OCHMe2)4 and diethyl tartrate can be present in catalytic amounts (15-lOmol %) if molecular sieves are present. Polymer-supported catalysts have also been reported. Since both (-t-) and ( —) diethyl tartrate are readily available, and the reaction is stereospecific, either enantiomer of the product can be prepared. The method has been successful for a wide range of primary allylic alcohols, where the double bond is mono-, di-, tri-, and tetrasubstituted. This procedure, in which an optically active catalyst is used to induce asymmetry, has proved to be one of the most important methods of asymmetric synthesis, and has been used to prepare a large number of optically active natural products and other compounds. The mechanism of the Sharpless epoxidation is believed to involve attack on the substrate by a compound formed from the titanium alkoxide and the diethyl tartrate to produce a complex that also contains the substrate and the r-BuOOH. ... 

Although the Sharpless asymmetric epoxidation is an elegant method to introduce a specific defined chirality in epoxy alcohols and thus, in functionalized aziridines (see Sect. 2.1), it is restricted to the use of allylic alcohols as the starting materials. To overcome this limitation, cyclic sulfites and sulfates derived from enantiopure vfc-diols can be used as synthetic equivalents of epoxides (Scheme 5) [12,13]. 

The epoxidation of allylic alcohols can also be effected by /-butyl hydroperoxide and titanium tetraisopropoxide. When enantiomerically pure tartrate ligands are included, the reaction is highly enantioselective. This reaction is called the Sharpless asymmetric epoxidation.55 Either the (+) or (—) tartrate ester can be used, so either enantiomer of the desired product can be obtained. 

ASYMMETRIC EPOXIDATION OF ALLYLIC ALCOHOLS SHARPLESS EPOXIDATION... 

Since its discovery in 1980,7 the Sharpless expoxidation of allylic alcohols has become a benchmark classic method in asymmetric synthesis. A wide variety of primary allylic alcohols have been epoxidized with over 90% optical yield and 70-90% chemical yield using TBHP (r-BuOOH) as the oxygen donor and titanium isopropoxide-diethyl tartrate (DET, the most frequently used dialkyl tartrate) as the catalyst. One factor that simplifies the standard epoxidation reaction is that the active chiral catalyst is generated in situ, which means that the pre-preparation of the active catalyst is not required. 

The asymmetric dihydroxylation protocol was the second massive contribution by Professor Barry Sharpless to synthetic organic chemistry. The first procedure, introduced with Katsuki, involves the catalytic asymmetric epoxida-tion of allylic alcohols. A typical example is shown in Scheme 17, wherein ( )-allylic alcohol (23) is epoxidized with tert-b utyl hyd roperox ide, in the presence of titanium tetra-isopropoxide and optically active diethyl tartrate to give the... 

The MABR-promoted rearrangement, when applied to optically active epoxy substrates, has been shown to proceed with rigorous transfer of the epoxide chirality. Accordingly, used in combination with the Sharpless asymmetric epoxidation of allylic alcohols,5 this rearrangement represents a new approach to the synthesis of various... 

More than a decade of experience on Sharpless asymmetric epoxidation has confirmed that the method allows a great structural diversity in allylic alcohols and no exceptions to the face-selectivity rules shown in Fig. 10.1 have been reported to date. The scheme can be used with absolute confidence to predict and assign absolute configurations to the epoxides obtained from prochiral allylic alcohols. However, when allylic alcohols have chiral substituents at C(l), C(2) and/or C(3), the assignment of stereochemistry to the newly introduced epoxide group must be done with considerably more care. 

Sharpless "asymmetric epoxidation" has been used in the enantioselective synthesis of several natural products, including the kinetic resolution of allylic alcohols [11] and the creation of ... 

In connection with the synthetic work directed towards the total synthesis of polyene macrolide antibiotics -such as amphotericin B (i)- Sharpless and Masamune [1] on one hand, and Nicolaou and Uenishi on the other [2], have developed alternative methods for the enantioselective synthesis of 1,3-diols and, in general, 1, 3, 5...(2n + 1) polyols. One of these methods is based on the Sharpless asymmetric epoxidation of allylic alcohols [3] and regioselective reductive ring opening of epoxides by metal hydrides, such as Red-Al and DIBAL. The second method uses available monosaccharides from the "chiral pool" [4], such as D-glucose. 

Scheme 8 summarizes the introduction of the missing carbon atoms and the diastereoselective epoxidation of the C /C double bond using a Sharpless asymmetric epoxidation (SAE) of the allylic alcohol 64. The primary alcohol 62 was converted into the aldehyde 63 which served as the starting material for a Horner-Wadsworth-Emmons (HWE) reaction to afford an E-configured tri-substituted double bond. The next steps introduced the sulfone moiety via a Mukaiyama redox condensation and a subsequent sulfide to sulfone oxidation. The sequence toward the allylic alcohol 64 was com-... 

Asymmetric synthesis of stavudine and cordycepin, anti-HIV agents, and several 3 -amino-3 -deoxy-P-nudeosides was achieved utilizing this cycloisomerization of 3-butynols to dihydrofuran derivatives [16]. For example, Mo(CO)6-TMNO-promoted cyclization of the optically active alkynyl alcohol 42, prepared utilizing Sharpless asymmetric epoxidation, afforded dihydrofuran 43 in good yield. Iodine-mediated introduction of a thymine moiety followed by dehydroiodination and hydrolysis of the pivaloate gave stavudine in only six steps starting from allyl alcohol (Scheme 5.13). 

Sharpless Asymmetric Epoxidation This is a method of converting allylic alcohols to chiral epoxy alcohols with very high enantioselectivity (i.e., with preference for one enantiomer rather than formation of racemic mixture). It involves treating the allylic alcohol with tert-butyl hydroperoxide, titanium(IV) tetra isopropoxide [Ti(0—/Pr)4] and a specific stereoisomer of tartaric ester. For example,... 

With a twist on the Sharpless asymmetric epoxidation protocol, Yamamoto and co-workers <99JOC338> have developed a chiral hydroxamic acid (17) derived from binaphthol, which serves as a coordinative chiral auxiliary when combined with VO(acac)j or VO(i-PrO)j in the epoxidation of allylic alcohols. In this protocol, triphenylmethyl hydroperoxide (TiOOH) provides markedly increased enantiomeric excess, compared to the more traditional t-butyl hydroperoxide. Thus, the epoxidation of E-2,3-diphenyl-2-propenol (18) with 7.5 mol% VO(i-PiO)3 and 15 mol% of 17 in toluene (-20 °C 24 h) provided the 2S,3S epoxide 19 in 83% ee. 

In their stereorational synthesis of (+)-[10.10] 61b, they reacted the epoxide 107 with a 1 1 3-butenylmagnesium bromide-cuprous iodide complex in dimethyl-sulfide-THF at low temperature. The predominant SN2 pathway gave the (+)-( )-allyl alcohol 108 whose Sharpless asymmetric epoxidation in dichloromethane at —23 °C for 10 min provided the corresponding epoxy alcohol and recovered (+)-(R)-allyl alcohol 108 (78 % yield and 95 % optical purity). The (R)-configuration was assigned following the Sharpless model61 for allylic alcohol epoxidation. 

Sharpless asymmetric epoxidation of open-chain allylic alcohols, an important discovery of the previous decade, was extensively used in carbohydrate synthesis [9-12], Presently, many aliphatic substrates can be elaborated into sugars [5,6 see also Chap. 9). 

Titanium-pillared montmorillonite may be used as a heterogeneous catalyst for the Sharpless asymmetric epoxidation of allylic alcohols (Scheme 20) (46). The enantiomeric purities of the epoxy products are comparable with those achieved using homogeneous Ti isopropoxide with molecular sieves as water scavengers (Chapter 4). Since basal spacing of the recovered catalyst after the reaction is unaltered, the catalyst can be recycled. 

Asymmetric epoxidation, dihydroxylation, aminohydroxylation, and aziridination reactions have been reviewed.62 The use of the Sharpless asymmetric epoxidation method for the desymmetrization of mesa compounds has been reviewed.63 The conformational flexibility of nine-membered ring allylic alcohols results in transepoxide stereochemistry from syn epoxidation using VO(acac)2-hydroperoxide systems in which the hydroxyl group still controls the facial stereoselectivity.64 The stereoselectivity of side-chain epoxidation of a series of 22-hydroxy-A23-sterols with C(19) side-chains incorporating allylic alcohols has been investigated, using m-CPBA or /-BuOOH in the presence of VO(acac)2 or Mo(CO)6-65 The erythro-threo distributions of the products were determined and the effect of substituents on the three positions of the double bond (gem to the OH or cis or trans at the remote carbon) partially rationalized by molecular modelling. 

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