Chirality alkenes

Hydrogenation of each of the following chiral alkenes gives only a single stereoisomer. 

The origin of stereoselection in 1,3-dipolar cycloadditions to chiral alkenes 97G167. 

The reaction discussed in the previous section involves addition to an achiral alkene and forms an optically inactive, racemic mixture of the two enantiomeric products. What would happen, though, if we were to carry out the reaction on a single enantiomer of a chiral reactant For example, what stereochemical result would be obtained from addition of H2O to a chiral alkene, such as... 

Figure 9.16 Stereochemistry of the addition of H20 to the chiral alkene, (fl)-4-methyl-1-hexene.

Although significant progress in the field of asymmetric hydroformylation has been made, it is limited to a rather narrow substrate scope. An alternative approach to a stereoselective hydroformylation might employ substrate control of a chiral alkenic starting material. Of particular use... 

Asymmetric 1,3-dipolar cycloaddition of cyclic nitrones to crotonic acid derivatives bearing chiral auxiliaries in the presence of zinc iodide gives bicyclic isoxazolidines with high stereoselectivity (Eq. 8.51). The products are good precursors of (3-amino acids such as (+)sedridine.73 Many papers concerning 1,3-dipolar cycloaddition of nitrones to chiral alkenes have been reported, and they are well documented (see Ref. 63). 

Cycloaddition of nitrile oxides to alkenes with various chiral auxiliaries are summarized in Table 8.1, which shows chiral alkenes and differential excess (de). 

Asymmetric 1,3-dipolar cycloaddition of nitronates using chiral alkenes has been reported,... 

A wide range of catalysts is now known that will bring about B H addition to simple terminal alkenes. For group 9 complexes, catalytic activity follows the order [(dppe)Rh (nbd)]+ > [Rh(PPh3)3Cl] > [(COD)Ir(PCy3)(C5H5N)]+ (where dppe = 2-bis(diphenylphosphino) ethane and nbd = norbornadiene).19 Different facial selectivity is found for catalytic hydroboration reactions of these compounds with chiral alkenes (Equation (1)). Thus, [(dppe)Rh(nbd)]+ gives... 

It is of particular value from a synthetic viewpoint that, under Wacker-type conditions the cyclization is catalytic [Pd(OAc)2/Cu(OAc)2/MeOH,H20/ air/55°C]121 albeit not by a Wacker-type mechanism.123 Addition of the chiral alkene, (- )-/l-pinene, to the catalyzed cyclization of 2-(but-2-enyl)phenol causes asymmetric induction with an optical yield of 12%... 

Similar to the addition of secondary phosphine-borane complexes to alkynes described in Scheme 6.137, the same hydrophosphination agents can also be added to alkenes under broadly similar reaction conditions, leading to alkylarylphosphines (Scheme 6.138) [274], Again, the expected anti-Markovnikov addition products were obtained exclusively. In some cases, the additions also proceeded at room temperature, but required much longer reaction times (2 days). Treatment of the phosphine-borane complexes with a chiral alkene such as (-)-/ -pinene led to chiral cyclohexene derivatives through a radical-initiated ring-opening mechanism. In related work, Ackerman and coworkers described microwave-assisted Lewis acid-mediated inter-molecular hydroamination reactions of norbornene [275]. 

However, most asymmetric 1,3-dipolar cycloaddition reactions of nitrile oxides with alkenes are carried out without Lewis acids as catalysts using either chiral alkenes or chiral auxiliary compounds (with achiral alkenes). Diverse chiral alkenes are in use, such as camphor-derived chiral N-acryloylhydrazide (195), C2-symmetric l,3-diacryloyl-2,2-dimethyl-4,5-diphenylimidazolidine, chiral 3-acryloyl-2,2-dimethyl-4-phenyloxazolidine (196, 197), sugar-based ethenyl ethers (198), acrylic esters (199, 200), C-bonded vinyl-substituted sugar (201), chirally modified vinylboronic ester derived from D-( + )-mannitol (202), (l/ )-menthyl vinyl ether (203), chiral derivatives of vinylacetic acid (204), ( )-l-ethoxy-3-fluoroalkyl-3-hydroxy-4-(4-methylphenylsulfinyl)but-1 -enes (205), enantiopure Y-oxygenated-a,P-unsaturated phenyl sulfones (206), chiral (a-oxyallyl)silanes (207), and (S )-but-3-ene-1,2-diol derivatives (208). As a chiral auxiliary, diisopropyl (i ,i )-tartrate (209, 210) has been very popular. 

The chiral sites which are able to rationalize the isospecific polymerization of 1-alkenes are also able, in the framework of the mechanism of the chiral orientation of the growing polymer chain, to account for the stereoselective behavior observed for chiral alkenes in the presence of isospecific heterogeneous catalysts.104 In particular, the model proved able to explain the experimental results relative to the first insertion of a chiral alkene into an initial Ti-methyl bond,105 that is, the absence of discrimination between si and re monomer enantiofaces and the presence of diastereoselectivity [preference for S(R) enantiomer upon si (re) insertion]. Upon si (re) coordination of the two enantiomers of 3-methyl-l-pentene to the octahedral model site, it was calculated that low-energy minima only occur when the conformation relative to the single C-C bond adjacent to the double bond, referred to the hydrogen atom bonded to the tertiary carbon atom, is nearly anticlinal minus, A- (anticlinal plus, A+). Thus one can postulate the reactivity only of the A- conformations upon si coordination and of the A+ conformations upon re coordination (Figure 1.16). In other words, upon si coordination, only the synperiplanar methyl conformation would be accessible to the S enantiomer and only the (less populated) synperiplanar ethyl conformation to the R enantiomer this would favor the si attack of the S enantiomer with respect to the same attack of the R enantiomer, independent of the chirality of the catalytic site. This result is in agreement with a previous hypothesis of Zambelli and co-workers based only on the experimental reactivity ratios of the different faces of C-3-branched 1-alkenes.105... 

The high levels of enantioselectivity obtained in the asymmetric catalytic carbomagnesa-tion reactions (Tables 6.1 and 6.2) imply an organized (ebthi)Zr—alkene complex interaction with the heterocyclic alkene substrates. When chiral unsaturated pyrans or furans are employed, the resident center of asymmetry may induce differential rates of reaction, such that after -50 % conversion one enantiomer of the chiral alkene can be recovered in high enantiomeric purity. As an example, molecular models indicate that with a 2-substituted pyran, as shown in Fig. 6.2, the mode of addition labeled as I should be significantly favored over II or III, where unfavorable steric interactions between the (ebthi)Zr complex and the olefmic substrate would lead to significant catalyst—substrate complex destabilization. 

Methylsulfenylation of acyclic chiral alkenes such as 5 can also be regio- and stereoselective as a result of steric and electronic factors. 

Chiral active pharmaceutical ingredients, 18 725-726. See also Enantio- entries Chiral additives, 6 75—79 Chiral alcohols, synthesis of, 13 667-668 P-Chiral alcohols, synthesis of, 13 669 Chiral alkanes, synthesis of, 13 668-669 Chiral alkenes, synthesis of, 13 668—669 Chiral alkoxides, 26 929 Chiral alkynes, synthesis of, 13 668-669 Chiral ammonium ions, enantiomer recognition properties for, 16 790 Chiral ansa-metallocenes, 16 90 Chiral auxiliaries, in oxazolidinone formation, 17 738—739... 

Addition of (TMS)3SiH to a-chiral ( )-alkene 7 was found to take place with a complete Michael-type regioselectivity (Reaction 5.8) [26]. A complete syn stereoselectivity was observed for R = Me, and it was rationalized in terms of Felkin-Ahn transition state 8, which favours the syn product similar to nucleophilic addition. 

Isomerizations may take place over some catalysts more than over others. Regio- as well as stereoisomers may be formed [13, 49. Such side reactions are undesirable in the reduction of pro-chiral alkenes, and especially in the hydrogenation of some cycloalkenes. 

The reduction of an unsymmetrical ketone creates a new stereo center. Because of the importance of hydroxy groups both in synthesis and in relation to the properties of molecules, including biological activity, there has been a great deal of effort directed toward enantioselective reduction of ketones. One approach is to use chiral borohydride reagents.92 Boranes derived from chiral alkenes can be converted to borohydrides, and there has been much study of the enantioselectivity of these reagents. Several of the reagents are commercially available. 

The diastereoselectivity in the ene reaction of O2 with chiral alkenes bearing a stereogenic centre at the a-position with respect to the double bond has been extensively studied. Chiral alkenes which bear a substituent on the asymmetric carbon atom other than the hydroxy or amine functionality afford predominately erythro allylic hydroperoxides. The erythro selectivity was attributed to steric and electronic repulsions between... 

It has already been mentioned (Section III) that the study of the diastereoselection in the electrophilic addition of singlet oxygen to the n face of chiral alkenes is of primary interest for the achievement of a selective oxyfunctionalization reaction. Zeolite confinement and cation- 7r interactions might be expected to affect significantly the diastereoselectivity in the photooxygenation of chiral alkenes. 

TABLE 24. Regioselectivity and diastereoselectivity in the photooxygenation of chiral alkenes within zeoUte Na-Y and in solution (values in parentheses)... 

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