Stereoselective reactions hydroboration

If R and R are different, the two faces of the double bond become nonequivalent, permitting stereoselective reactions at the double bond. These effects have been explored, for example, using 4-silyl-2-pentenes. Reactions such as epoxidation and hydroboration proceed by preferential addition fiom the face opposite the bulky silyl substituents. 

The /3-lactone was formed by the cyclization of a 3-hydroxycarboxylic acid with sulfonyl chloride. An alternative synthesis attempted to control all stereochemical relationships in the molecule using the properties of silyl moieties attached to substrates and reagents <20040BC1051>. Stereoselective reactions of this type included the use of silyl groups in enolate alkylations, hydroboration of allylsilanes, and an anti Se2 reaction of an allenyl silane with an aldehyde and ry -silylcupration of an acetylene. The /3-lactone was again formed by the standard sulfonyl chloride cyclization method. 

Our earlier statements on substrate and reagent control of stereoselectivity during hydroborations are incorporated in Figure 3.25. Because of the obvious analogies between the old and the new reactions, the following can be predicted about the product distribution shown ... 

Hydroboration occurs by a concerted process and takes place through a four-membered cyclic transition state, formed by addition of a polarized B—H bond (boron is the more positive) to the alkene double bond (5.2). This is supported by the fact that the reaction is stereospecific, with syn addition of the boron and hydrogen atoms. The reaction can also be stereoselective, with hydroboration taking place preferentially on the less hindered side of the double bond. Stereospecific addition of borane to a 1-alkylcycloalkene such as 1-methylcyclohexene, gives, after oxidation of the organoborane product (see Scheme 5.21), almost exclusively the trans alcohol product (5.3). 

STEP 1. Reaction of a nucleophile and an electrophile to form a new covalent bond. The addition of borane to an alkene is initiated by coordination of the vacant 2p orbital of boron (an electrophile) with the electron pair of the pi bond (a nucleophile). Chemists account for the stereoselectivity of hydroboration by proposing the formation of a cyclic, four-center transition state. Boron and hydro-... 

Moreover, you will discover that the hydroboration of (+)-a-pinene is an example of a stereoselective reaction because only one of several possible stereoisomeric products is formed by addition of the borane reagent to only one face of the TT-bond of 65. 

The hydroboration of 65 is a stereoselective reaction in which borane approaches from only one face of the carbon-carbon double bond to give the dialkylborane 66. Provide a rationale for this observed stereoselectivity. 

The chiral pool refers to readily available optically active natural products, some of which are commercially used in quantities of 10 -10 tonnes per year [5], Among them, the most inexpensive compounds are a-amino acids, like monosodium L-glutamate, or carbohydrates, like dextrose or sorbitol. The success of the second method depends on the availability of particular catalysts. One rather special example, how efficient stereoselective synthesis can work, is the syn-selective aldol reaction followed by a stereoselective alkene hydroboration and ketone reduction (Figure 1.8) which were used by Paterson et aJ. [26] to synthesize intermediates for the antibiotic oleandomycin. According to Paterson et al., four new stereocenters are formed in only two synthetic steps [9]. For the purpose of separating racemic mixtures... 

Transition metal catalyzed hydroboration may alter the stereoselectivity of hydroboration of terminal alkynes. Miyaura and co-workers reported a rhodium-catalyzed frans-hydroboration of terminal alkynes (Fig. 17) [40]. Deuterium labeling studies strongly suggested that the reaction proceeded through a vinylidene intermediate, which explained the formation of Z-alkene products. 

The coupling of alkenylboranes with alkenyl halides is particularly useful for the stereoselective synthesis of conjugated dienes of the four possible double bond isomers[499]. The E and Z forms of vinylboron compounds can be prepared by hydroboration of alkynes and haloalkynes, and their reaction with ( ) or (Z)-vinyl iodides or bromides proceeds without isomerization, and the conjugated dienes of four possible isomeric forms can be prepared in high purity. 

The overall result of the sequence hydroboration -I- oxidation is a regioselective and-Markownikoff-addition of water to an alkene. This reaction is an important method in organic synthesis, since it can be made stereoselective and even enantioselective. 

This chapter has been organized into three sections. The first section deals with transition metal-catalyzed hydroboration in organic synthesis and this is divided into three subsections - mechanism, chemoselectivity, and stereoselectivity. The second section deals with the application of transition metal-catalyzed hydroalumination reactions in organic synthesis, and this is also divided into three subsections - mechanism, chemoselectivity, and stereoselectivity. The third section examines the application of both hydroborations and hydroaluminations in total synthesis. 

This reaction occurs rapidly at room temperature using a small excess of alkyne and either pinacol- (HBpin) or catecholborane (HBcat). When an excess of borane was used, the Z/E ratio of the products was slowly eroded, eventually attaining a thermodynamic distribution of isomers. Equilibration presumably occurs via addition/elimination of excess Rh-H. Miyaura s method provides a useful synthetic complement to knovm cis-hydroboration methods. Under optimized conditions, good yields and high stereoselectivity (>90 10) were achieved for a variety of alkenylboronates (Table 9.8). The best selectivities were generally obtained with the use of catecholborane and Et3N as an additive. As in related reactions, the presence of base seems to suppress undesired reaction pathways. 

---