Alcohols preparation from epoxides

Both Siegel et al. (122) and Lawrence et al. (123) have described automated systems for the purification of small arrays of amines and amides. A 48-member array of P-amino alcohols prepared from epoxides and amines was purified using SPE by Shuker et al. (124). Blackburn et al. (125) have described the purification of a 60-member 3-aminoimidazo[l,2-fl]pyridine array obtained from a multiple-component condensation, and Bussolari et al. (126) purified a small array of phenylpropyl amines obtained from dihydrocoumarins and amines. A few applications where ion-exchange resins have been substituted with other solid phases have also recently appeared. For example, the purification of several carbohydrate arrays tagged as hydrophobic O-laurates using Ci8 silica producing up to 10-30 mg of >90% pure individuals was described by Nilsson et al. (127), and Curran et al. purified fluorous-... 

Allyl silanes react with epoxides, in the presence of Bp3 OEt2 to give 2-allyl alcohols.The reaction of a-bromo lactones and CH2=CHCH2Si(SiMe3)3 and AIBN leads to the a-allyl lactone.On the other hand, silyl epoxides have been prepared from epoxides via reaction with iec-butyllithium and chlorotri-methylsilane. ° a-Silyl-A-Boc-amines were prepared in a similar manner from the A-Boc-amine. " Arylsilanes were prepared by reaction of an aryl-lithium intermediate with TfOSi(OEt)3. In the presence of BEs etherate, allyl silane and a-methoxy A-Cbz amines were coupled. Benzyl silanes coupled with allyl silanes to give ArCHa—R derivatives in the presence of VO(OEt)Cl2 " and allyltin compounds couple with allyl silanes in the presence of SnCl4. Allyl silanes couple to the a-carbon of amines under photolysis conditions. 

As described above, 1,2-azido alcohols can be stereospecifically prepared from epoxides. 1,2-Azido alcohols thus prepared reacted with triphenylphosphine or trialkyl phosphites to afford aziridines, where inversion of both centers of the original epoxides takes place (Scheme Intramolecular oxirane... 

To a mixture of 100 ml of THF and 0.10 mol of the epoxide (note 1) was added 0.5 g Of copper(I) bromide. A solution of phenylmagnesium bromide (prepared from 0.18 mol of bromobenzene, see Chapter II, Exp. 5) in 130 ml of THF was added drop-wise in 20 min at 20-30°C. After an additional 30 min the black reaction mixture was hydrolysed with a solution of 2 g of NaCN or KCN and 20 g of ammonium chloride in 150 ml of water. The aqueous layer was extracted three times with diethyl ether. The combined organic solutions were washed with water and dried over magnesium sulfate. The residue obtained after concentration of the solution in a water-pump vacuum was distilled through a short column, giving the allenic alcohol, b.p. 100°C/0.2 mmHg, n. 1.5705, in 75% yield. 

Due to the abundance of epoxides, they are ideal precursors for the preparation of P-amino alcohols. In one case, ring-opening of 2-methyl-oxirane (18) with methylamine resulted in l-methylamino-propan-2-ol (19), which was transformed to 1,2-dimethyl-aziridine (20) in 30-35% yield using the Wenker protocol. Interestingly, l-amino-3-buten-2-ol sulfate ester (23) was prepared from l-amino-3-buten-2-ol (22, a product of ammonia ring-opening of vinyl epoxide 21) and chlorosulfonic acid. Treatment of sulfate ester 23 with NaOH then led to aziridine 24. ... 

Epoxides from aldehydes, 46, 44 Equatorial alcohols, preparation by use of the lithium aluminum hydride-aluminum chloride reagent, 47, 19... 

The optically active iodide 153 (Scheme 43) can be conveniently prepared from commercially available methyl (S)-(+)-3-hydroxy-2-methylpropionate (154) (see Scheme 41). At this stage of the synthesis, our plan called for the conversion of 153 to a nucleophilic organometallic species, with the hope that the latter would combine with epoxide 152. As matters transpired, we found that the mixed higher order cuprate reagent derived from 153 reacts in the desired and expected way with epoxide 152, affording alcohol 180 in 88% yield this regioselective union creates the C12-C13 bond of rapamycin. 

Hodgson et al. have demonstrated that arylalkenes 139 and dienes 140 can readily be prepared from simple terminal epoxides in a highly stereoselective manner by employing LTMP as base in combination with aryl and vinyllithiums as nucleophiles at 0 °C (Scheme 5.31) [41]. Without addition of LTMP, secondary alcohols... 

Optically active allylic alcohols can only be prepared from optically active sulfinyl epoxides when the created double bond is conjugated to an aromatic system. One example is described below29. 

Previous syntheses of terminal alkynes from aldehydes employed Wittig methodology with phosphonium ylides and phosphonates. 6 7 The DuPont procedure circumvents the use of phosphorus compounds by using lithiated dichloromethane as the source of the terminal carbon. The intermediate lithioalkyne 4 can be quenched with water to provide the terminal alkyne or with various electrophiles, as in the present case, to yield propargylic alcohols, alkynylsilanes, or internal alkynes. Enantioenriched terminal alkynylcarbinols can also be prepared from allylic alcohols by Sharpless epoxidation and subsequent basic elimination of the derived chloro- or bromomethyl epoxide (eq 5). A related method entails Sharpless asymmetric dihydroxylation of an allylic chloride and base treatment of the acetonide derivative.8 In these approaches the product and starting material contain the same number of carbons. 

The first synthesis of Taxol was completed by Robert Holton and co-workers and is outlined in Scheme 13.53. One of the key steps occurs early in the synthesis in sequence A and effects fragmentation of 4 to 5. The intermediate epoxide 4 was prepared from a sesquiterpene alcohol called patchino. 35 The epoxide was then converted to 5 by a BF3-mediated rearrangement. 

The transition-state model of this reaction has been proposed as (1), based on X-ray analyses of single crystals prepared from Ti(OPr )4, (R,R)-diethyl tartrate (DET), and PhCON(OH)Ph and from Ti(OPr )4, and (R,R) N,/V -dibenzyltartramide.30-32 The Z-substituent (R2), located close to the metal center, destabilizes the desired transition state and decreases enantioselectivity (vide supra). When the Z-substituent is chiral, face selection induced by the substituent strongly affects the stereochemistry of the epoxidation, and sometimes reversed face selectivity is observed.4 In contrast, the. E-substituent (R1) protrudes into an open space and E -allylic alcohols are generally good substrates for the epoxidation. 

The original epoxidation with titanium-tartrate is homogeneous, but it can be carried out heterogeneously without diminishing enantioselectivity by using titanium-pillared montmorillonite catalyst (Ti-PILC) prepared from titanium isopropoxide, (+)-DAT, and Na+-montmorillonite.38 Due to the limited spacing of Ti-PILC, the epoxidation becomes slower as the allylic alcohol gets bulkier. 

A combination of DAT and a metal alkoxide other than titanium alkoxide serves as a poor catalyst for the epoxidation of allylic alcohols. However, the combination of DAT and silica-supported tantalum alkoxides (2a) and (2b) prepared from Ta(=CHCMe3)(CH2Cme3)3 and silica(5oo) shows high enantioselectivity in the epoxidation of E-allylic alcohols, though chemical yields are not very great (Scheme 4).3... 

Kinetic resolution can also be accomplished via eliminative pathways. Thus, the enantiomerically enriched allylic alcohol 102 can be prepared from the meso epoxide 96 with up to 96% ee by the action of LDA in the presence of the chiral diamine 101 and 1,8-diazabicyclo-[5.4.0]undec-7-ene (DBU). The DBU is believed to function as an aggregation modifier, and the active catalyst is theorized to be a heterodimer of the lithium amide (deprotonated 101) and DBU, although some nonlinear effects have been observed at low DBU concentrations <00JA6610>. Dipyrrolidino derivatives (e.g., 104) have also demonstrated utility with regard to kinetic resolution <00H1029>. 

Via Asymmetric Epoxidation and Related Reactions. Denis et al.35 synthesized the taxol side chain derivative via Sharpless epoxidation. Starting from cw-cinnamyl alcohol, the corresponding epoxide compound was prepared with 76-80% ee. Subsequent azide ring opening gives a product that possesses the side chain skeleton (Scheme 7-78). 

As shown in Eq. 9.48, optically active alkylidene lactones having an iodoalkyl substituent were prepared from the corresponding optically active epoxy alcohol by means of the Sharpless epoxidation. These represent precursors of optically active functionalized cyclopentanes and cyclohexanes, respectively, as shown in the equation [92]. 

Access to P-mannosides [209] is illustrated by the preparation of 179 from P-glucoside 178 by oxidation of the equatorial 2-OH followed by stereoselective reduction to give the axial alcohol an efficient indirect route to the a-mannosides [206] utilizes the P-thioglucoside 182, readily obtained from epoxide 173, proceeding via an oxidation-reduction protection sequence to give P-thiomannoside glycosyl donor 184, from which a-mannoside 185 can be stereoselectively prepared. 

The regioselective ring-opening of epoxides 34 (R1 = Me, vinyl, Ph etc.) with aminolead compounds R23 PbNEt2, prepared from lithium diethylamide and R23 PbBr, gives good yields of the amino alcohols 3567. 

Although it was also Henbest who reported as early as 1965 the first asymmetric epoxidation by using a chiral peracid, without doubt, one of the methods of enantioselective synthesis most frequently used in the past few years has been the "asymmetric epoxidation" reported in 1980 by K.B. Sharpless [3] which meets almost all the requirements for being an "ideal" reaction. That is to say, complete stereofacial selectivities are achieved under catalytic conditions and working at the multigram scale. The method, which is summarised in Fig. 10.1, involves the titanium (IV)-catalysed epoxidation of allylic alcohols in the presence of tartaric esters as chiral ligands. The reagents for this asyimnetric epoxidation of primary allylic alcohols are L-(+)- or D-(-)-diethyl (DET) or diisopropyl (DIPT) tartrate,27 titanium tetraisopropoxide and water free solutions of fert-butyl hydroperoxide. The natural and unnatural diethyl tartrates, as well as titanium tetraisopropoxide are commercially available, and the required water-free solution of tert-bnty hydroperoxide is easily prepared from the commercially available isooctane solutions. 

While most of the iminium salts studied are cyclic, several acyclic iminium salts have also been investigated. In 1997, Armstrong and coworkers reported the use of acyclic iminium salt 83 as chiral epoxidation promoter (Fig. 27) [156, 157]. 1-Phenylcyclohexene oxide could be obtained in 100% conversion and 22% ee with stoichiometric amounts of 83. In 2002 acyclic iminium salt 84, prepared from L-prolinol, was investigated by Komatsu and coworkers, and cinnamyl alcohol was epoxidized in 70% yield and 39% ee (Fig. 27) [158]. 

Unprotected 2-acylcyclobutanones 21 are only stable in solution. They are obtained from the corresponding cyclopropylidene ketones 17 if the double bond is fully substituted. If not, they must be prepared from the corresponding cyclopropylidene alcohols 18 through a sequence of epoxidation, oxidation and rearrangement.53 54... 

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