Allyl Alcohol Derivatives

Numerous chiral cyclic allyl alcohol derivatives have been used as the chiral alkene part in 1,3-dipolar cycloadditions. In general, the more rigid conformational 

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Cyclisation of the allylic alcohols derived from the condensation of 2-ferf.butylthiobenzaldehyde and methylketones provides a new route to substituted 2/f-l-benzothiopyrans <96TL5077>. 

Another domino process, designed by Polt and coworkers [16], deals with the consecutive transformation of an in situ-prepared aldehyde to give 3-amino allylic alcohols 7-31 from 3-amino acids. When the 3-amino acid ester derivative 7-29 is sequentially treated with iBu5Al2H and vinyl magnesium bromide, a 3 2 mixture of the allylic alcohol derivatives 7-30 is obtained in 60% yield, which can be hydrolyzed to give 7-31 (Scheme 7.10). 

The rhodium-catalyzed intramolecular hydrosilylation of allylic alcohol derived silyl ethers has been described. Oxidative cleavage of the resulting cyclized hydrosilylation products affords a route to optically active diols (Scheme 28).129,130... 

Etherification with 7r-Allylmetals Generated from Allylic Alcohol Derivatives 657... 

Etherification with 7r-Ally I metals Generated from Allylic Alcohol Derivatives... 

An important variant for transition metal-catalyzed carbon-nitrogen bond formation is allylic substitution (for reviews, see1,la lh). Nucleophilic attack by an amine on an 7r-allyl intermediate, generated from either an allylic alcohol derivative,2 16,16a 16f an alkenyloxirane,17-19,19a-19d an alkenylaziridine19,19a 19d, or a propargyl alcohol derivative,21,21a 21d gives an allylic amine derivative. 

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). 

The titanium reagent 1 reacts with allyl alcohol derivatives, such as halides, acetates, carbonates, phosphates, or sulfonates to afford allyltitanium complexes of the type (r 1-al-lyl)TiX(OiPr)2, as shown in Eq. 9.21 [42], As a variety of allylic alcohols are easily obtained,... 

Allyltitaniums from Allyl Halides or Allyl Alcohol Derivatives and Ti(ll) and their Synthetic Utility... 

The reaction proceeds through ligand exchange and a subsequent P-elimination akin to the oxidative addition of Cp2Zr to allylic ethers [58], In this way, allyltitanium compounds can be obtained from readily available allylic alcohol derivatives and inexpensive Ti(OiPr)4. The method allows the preparation of functionalized allyltitaniums bearing functional groups such as ester or halide (Scheme 13.28). 

The allylic acyloxylation of alkenes, the Kharasch-Sosnovsky reaction, Eq. 81, would be an effective route to nonracemic allylic alcohol derivatives, if efficient, enantioselective catalysts were available. The reaction is mediated by a variety of copper salts, and as such, has been the target of considerable research in an attempt to render the process enantioselective. The original reaction conditions described by Kharasch require high temperatures when CuBr is used as the catalyst (93). However, the use of CuOTf (PhH)0 5 allows the reaction to proceed at temperatures as low as -20°C. Unfortunately, long reaction times are endemic in these processes and the use of excess alkene (2-100 equiv) is conventional. Most yields reported in this field are based on the oxidant. 

The first attempts to develop reactions offering control over the absolute stereochemistry of a chiral center, created by y-selective substitution of an achiral allylic alcohol-derived substrate, involved the use of chiral auxiliaries incorporated in the nucleofuge. The types of stereodirecting groups utilized vary, and have included sulfoximines [15], carbamates [16], and chiral heterocyclic sulfides [17-19]. 

The first examples of iridium-catalyzed allylic substitution [1] occurred between stabilized carbon nucleophiles and both alkyl- and aryl-substituted allylic alcohol derivatives with exceptional selectivity for the branched substitution product. 

Evans and Nelson examined the stereospecificity of the rhodium-catalyzed allylic alkylation, with the expectation that it would provide additional insight into the mechanism for this particular reaction [16]. They reasoned that the enantiomerically enriched allylic alcohol derivative i would furnish the enantioenriched product iv, provided the initial enyl intermediate ii does not isomerize to the achiral rr-organorhodium intermediate iii prior to alkylation (k2>ki Scheme 10.3). Alternatively, the product of re-... 

The transition metal-catalyzed allylic substitution using hard or unstabilized nucleophiles has not been extensively studied, particularly with unsymmetrical allylic alcohol derivatives. This may be attributed to the highly reactive and basic nature of these nucleophiles and the inability to circumvent regiochemical infidehty in unsymmetrical systems. Hard nucleophiles may be characterized as those that undergo substitution with net inversion of stereochemistry [29], due to their propensity to add directly to the... 

Evans and Uraguchi also examined the rhodium-catalyzed allylic alkylation with hard nucleophiles [31]. Aryl organozinc halides proved optimal nucleophiles for the regio- and stereospecific allylic alkylation of enantiomerically enriched unsymmetrical allylic alcohol derivatives (Tab. 10.4). The reaction occurs with net inversion of absolute... 

Y. Nakamura, M. Okada, H. Horikawa, T. Taguchi, Preparation of c5-fluorinated homo-allylic alcohol derivatives via regioselective hydride reduction of allylic alcohol derivatives, J. Fluor. Chem. 117 (2002) 143-148. 

The carbo- and hetero-Diels-Alder reactions are excellent for the constmction of six-membered ring systems and are probably the most commonly applied cycloaddition. The 1,3-dipolar cycloaddition complements the Diels-Alder reaction in a number of ways. 1,3-Dipolar cycloadditions are more efficient for the introduction of heteroatoms and are the preferred method for the stereocontrolled constmction of five-membered heterocycles (1 ). The asymmetric reactions of 1,3-dipoles has been reviewed extensively by us in 1998 (5), and recently, Karlsson and Hogberg reviewed the progress in the area from 1997 and until now (6). Asymmetric metal-catalyzed 1,3-dipolar cycloadditions have also been separately reviewed by us (7-9). Other recent reviews on special topics in asymmetric 1,3-dipolar cycloadditions have appeared. These include reactions of nitrones (10), reactions of cyclic nitrones (11), the progress in 1996-1997 (12), 1,3-dipolar cycloadditions with chiral allyl alcohol derivatives (13) and others (14,15). 

One of the classical ways to perform diastereoselective 1,3-dipolar cycloaddition is by the addition of a 1,3-dipole to an allyl alcohol derivative (65, 107-120). Very recently, a short review article was devoted to this area (13). Among the most commonly applied acyclic allyl alcohol derivatives are alkenes 73-75 (Scheme 12.25). These alkenes have been used in reactions with nitrones. 

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