Asymmetric synthesis of alcohols

Allylation is carried out using an allylic chloride (1 equiv) magnesium (3 equiv), additive (1 

Similarly, the reaction of monosubstituted allylic barium reagents give rise to exceedingly high diastereoselectivity (Table 6.25) [1]. 

These results support the intermediate allylic boron ate complex formed from stereochemically homogeneous allylmetal and il-OMe-9-BBN, with a plausible chair-like transition state Tj. This transition state is further stabilized by the adjacent four-membered ring formed by the second metal [2]. The alternative transition state Tj is destabilized by the 1,3-diaxial repulsion of the bulky cyclooctyl ring of 9-BBN (Fig. 6.1). erythro-threo Assignments are made 

Yamamoto et al have further reported [4] a one-pot process for the stereoselective synthesis of (Z)-2-alkenylsilanes and -tins in high chemical and isomeric yields (Chart 6.24). The (Z)-2-alkenyltin prepared as illustrated in Chart 6.25 adds to aldehyde and complete eryfhro-selective coupling is realized via the thermal [5] or Lewis acid-mediated reaction [6] (Chart 6.25) to give homoal-lylic alcohols. 

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The high synthetic utility of alcohols 38 stems from the fact that terminal alkynes are among the most versatile functional groups for the further elaboration of a carbon skeleton. Asymmetric synthesis of alcohols 38 from aldehydes with the concurrent formation of the two stereogenic C atoms has been accomplished mainly by two methods. The first features synthesis of chiral nonracemic allenylmetal compounds from the corresponding chiral nonracemic propargyl alcohols and addition of the former to aldehydes [26] and the second method in-... 

Asymmetric Synthesis of Alcohols by Hydrosilylation of Ketones A Comparison of an Insolubilized (+) -DIOP Catalyst vs a Solution (+)-DIOP Catalysta... 

Synthesis of optically active alcohols. For asymmetric synthesis of alcohols, the carbanion salt (2) is generated from optically active (R)-melhyl p-tolyl sulfoxide (1). The optically active carbanion reacts with bcnzaldehyde (3) to give a I I diastereomeric mixture of 2-hydroxy-2-phenylethyl p-tolyl sulfoxides (4a) and (4b) in 84% yield-These can be separated by silica gel chromatography and fractional crystallizations to give (4a, oq, -t- 91.7°. 17% yield) and (4b, at, + 202.8", 15.5% yield). Raney nickel desulfurization of (4a) and (4b) gives (S)-( )-l-phcnylcthanol (5a, — 42.6 ) and... 

Hydroxymercuration. Starting from olefins, an asymmetric synthesis of alcohols is achieved by the hydroxymercuration-demercuration method in the presence of 8-cyclodextrin, albeit in relatively low optical yields. 

We chose to study asymmetric hydrosilylation for the preparation of alcohols (20) and amines (18) because the system permits structural modifications of both the chiral ligands and the silane. The possibility arose of a good matching with the substrate, leading to high stereoselectivity in the formation of the chiral product. We will only consider here the asymmetric synthesis of alcohols. 

Asymmetric synthesis of alcohols. This ligand is elfective for asymmetric addition of an alkyllithium to an aldehyde. In more recent work it has been found that the lithium anion (2) of 1, prepared with n-butyllithium, is particularly eifective for asymmetric addition of dialkylmagnesium compounds to aldehydes. AU the alcohols have the (R)-configuration. Toluene was found to be a superior solvent for this reaction lower temperatures increasfe optical yields. Only one example of use of an aliphatic aldehyde was reported only a low optical yield was obtained. ... 

A wide variety of methods exist for the asymmetric synthesis of alcohols with 1,2- and 1,3-stereocontrol relative to a second stereocenter (cf Scheme 4.22), such as aldol additions, substituted allyl metal additions to aldehydes, vinyl metal additions to a-chiral aldehydes, dihydroxylations, etc. When coupled with a subsequent Claisen rearrangement, a net 1,4- and 1,5-asymmetric induction can be achieved. A representative example will be shown others can be seen in subsequent sections. 

For a long time, kinetic resolution of alcohols via enantioselective oxidation or via acyl transfer employing, for example, lipases along with dynamic kinetic resolution have been the biocatalytic methods of choice for the preparation of chiral alcohols. In recent years, however, impressive progress has been made in the use of alcohol dehydrogenases (ADHs) and ketor-eductases (KREDs) for the asymmetric synthesis of alcohols by stereoselective reduction of the corresponding ketones. Furthermore, recent remarkable multienzymatic systems have been successfully applied to the deracemisation of alcohols via stereoinversion based on an enantioselective oxidation followed by an asymmetric reduction. 

The use of the chiral aminoborane (24) for the asymmetric synthesis of alcohols from ketones shows promise optical yields are in the range 14—23% for the three ketones tested. Stereoselective reduction of acetophenone and isobutyl methyl ketone has been observed on addition of the chiral phase-transfer catalyst (25) (derived from L-ephedrine) to sodium borohydride and the ketone in aqueous dichloromethane. ... 

The development 0/ the chemistry of boranes continues with outstanding results It has produced a convenient route to the less stable, terminally unsaturated compounds from the more stable, highly substituted ethylene derivatives , a facile procedure for the asymmetric synthesis of alcohols of high optical purity , and a... 

Pullarkat SA, Yi D, Li Y, Tan G-K, Leung P-H (2006) A novel approach toward asymmetric synthesis of alcohol functionalized C-chiral diphosphines via two-stage hydrophosphination of terminal alkynols. Inorg Chem 45 7455-7463... 

Scheme 5 details the asymmetric synthesis of dimethylhydrazone 14. The synthesis of this fragment commences with an Evans asymmetric aldol condensation between the boron enolate derived from 21 and trans-2-pentenal (20). Syn aldol adduct 29 is obtained in diastereomerically pure form through a process which defines both the relative and absolute stereochemistry of the newly generated stereogenic centers at carbons 29 and 30 (92 % yield). After reductive removal of the chiral auxiliary, selective silylation of the primary alcohol furnishes 30 in 71 % overall yield. The method employed to achieve the reduction of the C-28 carbonyl is interesting and worthy of comment. The reaction between tri-n-butylbor-... 

To extend the scope of asymmetric transannular C-H insertions, more highly functionalized medium-sized cyclic epoxides have been investigated. A triad of cydooctene oxides 34, 36, and 38, possessing protected diol units, gave the expected alcohols 35, 37, and 39 (Scheme 5.10) [17, 18] an asymmetric synthesis of (-)-xialenon A has been achieved starting from alcohol 39 [19]. In comparison,... 

Hodgson et al. showed that a series of bis- and tris-homoallylic terminal epoxides underwent intramolecular cydopropanation to give a range of bicydic alcohols. A short asymmetric synthesis of sabina ketone based on this chemistry was demonstrated (Scheme 5.20). A practical advantage with this process is that the volatile epoxides can be replaced with readily available chlorohydrins, an extra... 

One of the first examples of this type of reaction, using a chiral alcohol as an auxiliary, was the asymmetric synthesis of 2-hydroxy-2-phenylpropanoic acid (atrolactic acid, 3, R1 =C6H5 R3 = CH3) by diastereoselective addition of methyl magnesium iodide to the men-thyl ester of phcnylglyoxylie acid4,5 (Table 22). 

Allylsilanes are available by treatment of allyl acetates and allyl carbonates with silyl cuprates17-18, with antarafacial stereochemistry being observed for displacement of tertiary allyl acetates19. This reaction provides a useful asymmetric synthesis of allylsilanes using esters and carbamates derived from optically active secondary alcohols antarafacial stereochemistry is observed for the esters, and suprafacial stereochemistry for the carbamates20,21. 

Chiral alcohols have also been used in an asymmetric synthesis of sulphoxides based on halogenation of sulphides. Johnson and coworkers have found319 that the reaction of benzyl p-tolyl sulphide with JV-chlorobenzotriazole (NCBT) followed by addition of (—) menthol and silver tetrafluoroborate afforded diastereoisomeric menthoxysulphonium salts 267 which, upon recrystallization and hydrolysis, gave benzyl p-tolyl sulphoxide with 87% optical purity (equation 145). More recently, Oae and coworkers reported320 that optically active diaryl sulphoxides (e.e. up to 20%) were formed either by hydrolysis or thermolysis of the corresponding diaryl menthoxysulphonium salts prepared in situ from diaryl sulphides using ( —) menthol and t-butyl hypochlorite. 

Hodous BL, Ruble JC, Fu GC (1999) Enantioselective addition of alcohols to ketenes catalyzed by a planar-chiral azaferrocene catalytic asymmetric synthesis of arylpropionic acids. J Am Chem Soc 121 2637-2638... 

The subsequent epoxidation of these in situ formed allylic tertiary alcohols yielded the corresponding syn-e oxy alcohols with high levels of diastereo- and enantioselectivity, thus providing a novel one-pot asymmetric synthesis of acyclic chiral epoxyalcohols via a domino vinylation epoxidation reaction (Scheme 4.17). ... 

A classical approach to driving the unfavorable equilibrium of an enzymatic process is to couple it to another, irreversible enzymatic process. Griengl and coworkers have applied this concept to asymmetric synthesis of 1,2-amino alcohols with a threonine aldolase [24] (Figure 6.7). While the equilibrium in threonine aldolase reactions typically does not favor the synthetic direction, and the bond formation leads to nearly equal amounts of two diastereomers, coupling the aldolase reaction with a selective tyrosine decarboxylase leads to irreversible formation of aryl amino alcohols in reasonable enantiomeric excess via a dynamic kinetic asymmetric transformation. A one-pot, two-enzyme asymmetric synthesis of amino alcohols, including noradrenaline and octopamine, from readily available starting materials was developed [25]. 

Similarly, whole-cell Lactobacillus kefir DSM 20587, which possesses two alcohol dehydrogenases for both asymmetric reduction steps, was applied in the reduction of tert-butyl 6-chloro-3,5-dioxohexanoate for asymmetric synthesis of ft rf-butyl-(31 ,5S)-6-chloro-dihydroxyhexanoate (Figure 7.5), a chiral building block for the HMG-CoA reductase inhibitor [ 17]. A final product concentration of 120 him and a specific product capacity of 2.4 mmol per gram dry cell were achieved in an optimized fed-batch process. Ado 99% was obtained for (3R,5S)- and (3.S, 55)-te/ f-butyl-6-chloro-dihydroxyhexanoate with the space-time yield being 4.7 mmolL-1 h-1. 

The first asymmetric synthesis of (-l-)-abresoline was achieved from the chiral piperidine derivative 153, which upon treatment of its hydroxy side-chain substituent with carbon tetrabromide, triphenylphosphine, and triethyl-amine cyclized to the frarcr-quinazolidine 154. Deketalization and silyl protection of the phenolic group, followed by stereoselective reduction with lithium tri-t -butylborohydride (L-Selectride ), gave an alcohol, which after acylation and deprotection furnished (-l-)-abresoline 155 (Scheme 25) <2005TL2669>. 

O-Alkylation of 4-hydroxy-3-morpholino-l,2,5-thiadiazole 132 has been achieved with the chiral cyclic chloro-methyl sulfite 133 which subsequently suffers ring opening on treatment with simple alcohols <2001RCB436> or alkylamines <2002RJ0213> to afford the timolol analogues 134 with very little racemization (Scheme 20). This indicated an almost exclusive attack of the oxy anion on the exocyclic carbon atom and is a significant improvement on the previous oxirane method, which suffers from racemization. An alternative biocatalytic asymmetric synthesis of (A)- and (R)-timolol has also appeared <2004S1625>. 

An asymmetric synthesis of phosphonylated thiazolines has been described. The phosphonodithioacetate 46 was aminated with a chiral amino alcohol 47 to give the phosphonylated thioamide 48 in good yield. This was then cyclised using a Mitsunobu procedure to give the chiral thiazoline phosphonate 49 in good yields under mild conditions. Homer-Wadsworth-Emmons reaction of these phosphonylated thiazolines gave chiral vinylic thiazolines 50 <00S1143>. 

The asymmetric oxidation of organic compounds, especially the epoxidation, dihydroxylation, aminohydroxylation, aziridination, and related reactions have been extensively studied and found widespread applications in the asymmetric synthesis of many important compounds. Like many other asymmetric reactions discussed in other chapters of this book, oxidation systems have been developed and extended steadily over the years in order to attain high stereoselectivity. This chapter on oxidation is organized into several key topics. The first section covers the formation of epoxides from allylic alcohols or their derivatives and the corresponding ring-opening reactions of the thus formed 2,3-epoxy alcohols. The second part deals with dihydroxylation reactions, which can provide diols from olefins. The third section delineates the recently discovered aminohydroxylation of olefins. The fourth topic involves the oxidation of unfunc-tionalized olefins. The chapter ends with a discussion of the oxidation of eno-lates and asymmetric aziridination reactions. 

Allylic alcohol derivatives are quite useful in organic synthesis, so the asymmetric synthesis of such compounds via asymmetric hydrogenation of dienyl (especially enynyl) esters is desirable. The olefin functionality preserves diverse synthetic potential by either direct or remote functionalization. Boaz33 reported that enynyl ester and dienyl ester were preferred substrates for asymmetric hydrogenation using Rh-(Me-DuPhos) catalyst [Rh(I)-(R,R)-14], and products with extremely high enantioselectivity (>97%) were obtained (Schemes 6-11 and 6-12). 

Sharpless epoxidation reactions are thoroughly discussed in Chapter 4. This section shows how this reaction is used in the asymmetric synthesis of PG side chains. Kinetic resolution of the allylic secondary alcohol ( )-82 allows the preparation of (R)-82 at about 50% yield with over 99% ee (Scheme 7-23).19... 

Efforts have been made to apply r 3-allyltitanium chemistry to the asymmetric synthesis of homoallylic alcohols and carboxylic acids. The synthesis and reactions of chiral r 3 -allyl-titanocenes with planar chirality, or containing Cp ligands with chiral substituents, have been reported [6c,15,30—32]. The enantiofacial selectivity in the allyltitanation reactions has been examined for the complexes 12 [15], 13 [30], 14 [31], 15, 16, and 17 [32] depicted in Figure 13.2. 

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