Aldehydes from allylic alcohols, arylation

When allylic alcohols are used as an alkene component in the reaction with aryl halides, elimination of /3-hydrogen takes place from the oxygen-bearing carbon, and aldehydes or ketones are obtained, rather than y-arylated allylic alcohoIs[87,88]. The reaction of allyl alcohol with bromobenzene affords dihydrocinnamaldehyde. The reaction of methallyl alcohol (96) with aryl halides is a good synthetic method for dihydro-2-methylcinnamaldehyde (97). 

Vinyl substitution of primary or secondary allylic alcohols with aryl halides usually produces 3-aryl aldehydes or ketones, respectively. The reaction is believed to involve an addition of the intermediate arylpalladium halide to die double bond, placing the aryl group mainly on the more distant carbon from the hydroxy group, followed by palladium hydride elimination, a reverse readdition and another elimination with a hydrogen atom on the carbon bearing the hydroxy group. The product is probably a ir-com-plex of the enol which ultimately either dissociates or collapses to a a-complex with palladium on the... 

A three-component reaction based on the umpolung of re-allylpalladium (II) complexes indium metal was reported by Grigg and co-workers (Scheme 8.31) [74]. In this reaction, the electrophilic nature of the n-allyl palladium species generated from aryl halides and allenes is reversed by transmetallation with indium metal. The resultant nucleophilic allylindium reagent subsequently adds to the third component - aldehyde [75] or imine [76] - to give the corresponding homo-allylic alcohol 64 or amine 65 respectively. 

Other unsaturated substrates arylated by various diaryl iodonium salts included butenone, acrylic acid, methyl acrylate and acrylonitrile [46]. Allyl alcohols with diaryliodonium bromides and palladium catalysis were arylated with concomitant oxidation for example, from oc-methylallyl alcohol, aldehydes of the general formula ArCH2CH(Me)CHO were formed [47]. Copper acetylide [48] and phenyl-acetylene [49] were also arylated, with palladium catalysis. 

Asymmetric addition of (CH1=CH)1Zn to aldehydes. The chiral tridendate ligand 1, derived from (+ )-camphor-10-sulfonic acid, effects highly enantioselective addition of R2Zn to aldehydes. Significantly, even divinylzinc adds to aryl and aliphatic aldehydes to furnish (R)-allylic alcohols in 82-96% ee. 

Notable new general syntheses of butenolides include the addition of the three-carbon synthon Li(PhS)C=CMeC02Me to aldehydes R CHO (R = alkyl or aryl) to yield the thioethers (19), the related reaction of lithio-j8-lithio-acrylates R CLi=CR C02Li with benzaldehyde to give compounds (20 R = H or Me), and the formation of (21) from the iodinated allyl alcohol ICMe=CHCH20H and carbon monoxide in the presence of bis(triphenylphos-phine)palladium(ii) chloride. Chloral reacts with dimethyl (benzylamino)fu-marate to yield the butenolide (22), whereas aromatic aldehydes give hydroxy-pyrrolinones (23). The total synthesis of piperolide (24) has been reported. 

Kim et al. have reported a facile one-pot stereoselective synthesis of ( )-cinnamyl alcohols 113 via the treatment of MBH adducts, derived from aryl aldehydes and ethyl acrylate, with TFA. However, a similar reaction of MBH adducts derived from aryl aldehydes and acrylonitriles with TFA gave the ( )-allyl alcohols 111 in low yields (Scheme 3.40). " Since Basavaiah s method works well for nitrile-containing adducts [for ( )-selective nitriles] and the trifluoroacetic acid method works well with ester-containing adducts [for ( )-selective esters], these two methods are considered to be complementary for the preparation of stereochemically defined cinnamyl alcohols. 

Reduction of halides.1 The reagent prepared from NaBH3CN and SnCl2 in a 2 1 ratio does not reduce primary or secondary alkyl halides or aryl halides in ether at 25°, but does reduce tertiary, allyl, and benzyl halides. It is thus comparable to NaBH3CN-ZnCl2 (12, 446). Aldehydes, ketones, and acid chlorides are reduced to alcohols, but esters and amides are inert. 

The at complex from DIB AH and butyllithium is a selective reducing agent.16 It is used tor the 1,2-reduction of acyclic and cyclic enones. Esters and lactones are reduced at room temperature to alcohols, and at -78 C to alcohols and aldehydes. Acid chlorides are rapidly reduced with excess reagent at -78 C to alcohols, but a mixture of alcohols, aldehydes, and acid chlorides results from use of an equimolar amount of reagent at -78 C. Acid anhydrides are reduced at -78 C to alcohols and carboxylic acids. Carboxylic acids and both primary and secondary amides are inert at room temperature, whereas tertiary amides (as in the present case) are reduced between 0 C and room temperature to aldehydes. The at complex rapidly reduces primary alkyl, benzylic, and allylic bromides, while tertiary alkyl and aryl halides are inert. Epoxides are reduced exclusively to the more highly substituted alcohols. Disulfides lead to thiols, but both sulfoxides and sulfones are inert. Moreover, this at complex from DIBAH and butyllithium is able to reduce ketones selectively in the presence of esters. 

The stereochemical outcome of allylic silacyclobutanes is explained in terms of a six-membered chairlike transition state18 (Scheme 3.2p). The aldehyde would coordinate to the Lewis acidic silicon19 to form a pentacoordinated complex, from which the allyl group transfer occurs subsequently to give homoallylic alcohols. In transition states A and B, the aryl or alkyl group (R) of the aldehydes prefers to occupy an equatorial position to produce anti- and. syn-alcohols from the (E)-and (Z)-allylic silacyclobutanes, respectively. 

Phosphonates have also been prepared from alcohols and (Ar0)2P(=0)Cl, NEts and a TiCl4 catalyst. ° The reaction of (R0)2P(=0)H and aryl iodides with a Cul catalyst leads to aryl phosphonates. " Polymer-bound phosphonate esters have been used for olefination. Dienes are produced when allylic phosphonate esters react with aldehydes. 

Kobayashi has demonstrated that a chiral zirconium catalyst derived from 3,3 dibromo or 3,3 dichloro BINOL can catalyze the addition of substituted allyl stannanes to the imines derived from 2 hydroxyaniline and aryl or hetereoaryl substituted aldehydes (Scheme 1.25) [95]. The active catalyst is possibly generated by the bonding of the alcohol functionalities of the imine and of allylstarmane to the zirconium center. 

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