Alkenes stereoselective addition

This cyclization has been used in an efficient synthesis of chokol A 11.219, an anti-fungal compound (Scheme 11.74). The acetal 11.216, in which the tartrate moiety functions as an economical chiral auxiliary, cyclized using palladium acetate to give an 8.5 1 mixture of stereoisomers. Aeidic hydrolysis removed the acetal to give a ketone 11.217, which could be taken through to the natural product 11.219 by selective reduction of the electron-poor alkene, stereoselective addition of a methyl group, allylic oxidation and desilylation. 

The orientation of addition of an unsymmetrical adduct, HY or XY, to an unsymmetrically substituted alkene will be defined by the preferential formation of the more stabilised carbanion, as seen above (cf. preferential formation of the more stabilised carbocation in electrophilic addition, p. 184). There is little evidence available about stereoselectivity in such nucleophilic additions to acyclic alkenes. Nucleophilic addition also occurs with suitable alkynes, generally more readily than with the corresponding alkenes. 

According to the stepwise electrophilic reaction mechanism, the differences in the stereochemistries of the products from the reactions of alkenes with cyclic 49 and acyclic 51 disulfonium dications can be explained by the larger rates of the intramolecular reactions. In the case of a cyclic dication, the carbocationic center in intermediate 94, which is formed as the result of initial attack by a S-S dication on a double C=C bond reacts with nucleophile intramolecularly, thus conserving the configuration of the substituents at the double bond. On the other hand, an acyclic dication undergoes transformation to two separate particles (95 and dimethylsulfide) with a consequent loss of stereoselectivity. Additional experiments with deuteretad alkenes confirm that reaction is not stereoselective, lending further support to the stepwise mechanism (Scheme 36).106... 

Diborations of 1,3-dienes are carried out in the presence of platinum(O) catalyst. In the Pt(PPh3)4-catalyzed dibora-tion of 1,3-dienes, 1,4-addition takes place to give (Z)-l,4-diboryl-2-alkenes stereoselectively (Equation (10)).62 In contrast, the Pt(dba)2-catalyzed reaction of 1,3-pentadiene affords 1,2-addition product, in which more substituted C=C bond is left intact (Scheme 5). The use of Pt(dba)2 as catalyst also enables the diborative dimerization of isoprene to occur (Equation (ll)).48... 

Regio- and stereoselective addition of 9-(phenylthio)-9-BBN to terminal alkynes is catalyzed by Pd(PPh3)4 to produce 9-[(Z)-/ -(phenylthio)alkyenyl]-9-BBN (Scheme 73) 283 Addition of styrene avoids catalyst deactivation by trapping free thiophenol generated in the reaction mixture. The produced alkenylboranes exhibit high reactivities for protonolysis with MeOH to produce 2-phenylthio-l-alkenes. 

A more recent report describes the regio- and stereoselective addition of aryltellurenyl iodides (prepared in situ from the corresponding ditellurides and iodine) to alkynes to afford the ( )-l-iodo-2-aryltelluro-l-alkenes, which treated with bromine give the corresponding dibromides. ... 

Highly efficient and stereoselective addition of tertiary amines to electron-deficient alkenes is used by Pete et al. for the synthesis of necine bases [26,27], The photoinduced electron transfer of tertiary amines like Af-methylpyrrolidine to aromatic ketone sensitizers yield regiospecifically only one of the possible radical species which then adds diastereospecifically to (5I )-5-menthyloxy-2-(5//)-furanone as an electron-poor alkene. For the synthesis of pyrrazolidine alkaloids in approximately 30% overall yield, the group uses a second PET step for the oxidative demethylation of the pyrrolidine. The resulting secondary amine react spontaneously to the lactam by intramolecular aminolysis of the lactone (Scheme 20) [26,27]. 

In the process of olefin insertion, also known as carbometalation, the 1,2 migratory insertion of the coordinated carbon-carbon multiple bond into the metal-carbon bond results in the formation of a metal-alkyl or metal-alkenyl complex. The reaction, in which the bond order of the inserted C-C bond is decreased by one unit, proceeds stereoselectively ( -addition) and usually also regioselectively (the more bulky metal is preferentially attached to the less substituted carbon atom. The willingness of alkenes and alkynes to undergo carbometalation is usually in correlation with the ease of their coordination to the metal centre. In the process of insertion a vacant coordination site is also produced on the metal, where further reagents might be attached. Of the metals covered in this book palladium is by far the most frequently utilized in such transformations. 

New examples of [n2 +, 2] photocycloaddition of maleic anhydride (318) to alkenes have been reported.262 The major product of addition to ketene (319), for example, is the spiro cyclobutane (320).263 The stereoselective addition of dichlorovinylene carbonate to phenanthrene has been described,264 and the photoaddition of this carbonate (321) to the alkene (322)... 

The Beckmann rearrangement is used in a similar way to produce the lactam 32, an intermediate in the synthesis of swainsonine 33. Stereoselective addition of dichloroketene to the enol ether 30 gave one isomer ( 95 5) of cyclobutanone 31. Beckmann rearrangement with a sulfonated hydroxylamine and dechlorination gave the lactam 32 in 34% yield over five steps7 from a precursor of 30. Note that the m-alkene 30 gives the trans cyclobutanone selectively. 

Water is essential for this reduction. This system reduces alkynes to rij-alkenes with high stereoselectivity. Addition of methyl propynoate (10 mole %) increases the reactivity and can effect reduction of alkynes to alkanes. 

Trtsubstitutedalkenes. Complete details have been published for preparation of these alkenes by addition of alkylcopper complexes to acetylenes. The paper includes numerous references to work of other laboratories as well, The paper also presents convincing evidence that the reaction involves xyn-addition with a high degree of stereoselectivity. ... 

Methanesulfenyl trifluoroacetate, formed in situ by treatment of 5-methyl methanethiosulfi-nate with trifluoroacetic acid anhydride at — 20 °C, undergoes stereoselective addition to a variety of alkenes affording the franj-product 1025. 

Bromine azide, prepared by different methods, undergoes addition to alkenes stereoselectively by an ionic mechanism 33- 37 (Table 2). Improved yields are obtained by using azidotrimethyl-silane and A-bromosuccinimide (NBS) in the presence of Nafion-FI as catalyst33. Alternatively, A-bromosuccinimide may be added to the mixture of the alkene and sodium azide in dimeth-oxyethane/water34. Aziridines were prepared stereoselectively by reduction of (i-bromo azides with lithium aluminum hydride34. 

There have been many studies on the use of chiral electrophilic selenium reagents for stereoselective additions to alkenes <1998JA3376, B-1999MI35, 1999T1, 2000AGE3740> with notable diastereoselectivity in some cases. 

In each of the stereoselective reactions described above, the double bond is formed by connecting two separate molecules. The steps leading to the alkene involve addition of a carbanion to the carbonyl carbon of an aldehyde or a ketone followed by an elimination process. 

Few examples exist in the literature concerning the stereoselective addition of acyl radicals to a radical acceptor in an acyclic manner. Equation (13.1) shows the efficient 1,2-asymmetric induction in the addition of aliphatic or aromatic acyl radicals to chiral acyclic alkenes 1 [7]. The corresponding a-hydroxy ketones 3 were produced with high syn selectivity (Table 13-1). This acyl radical addition is very exothermic, and it is hypothesized that Hammond s postulate can be invoked to predict a transition state that is very close in energy to the starting alkene 1. The X-ray structure of 1 was then used to rationalize the stereochemical outcome of this radical addition by determination of the least sterically hindered path for the approaching radical. 

In addition to thermal extrusion, a variety of reagents have been shown to facilitate the loss of sulfur from thiiranes and thiirenes <83HC(42/i)333>. The most frequently encountered reagents for this purpose are trivalentphosphines (both trialkyl and triaryl) which give alkenes stereoselectivity. 

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