Stereoselectivity aromatic electrophilic

The reaction can be performed in one flask with great operational ease a mixture of an aldehyde and p-anisidine is stirred in THF for 5-10 h at 50 °C. Then, without removing the water produced, Ni(acac)2, isoprene, and Et2Zn are added in this order at room temperature. The mixture is stirred at the same temperature for the period of time indicated (Table 8). The products 57 and 58 are isolated as a mixture by column chromatograph after the usual work-up. Table 8 demonstrates the scope regarding the kind of aldehyde that encompasses not only aromatic aldehydes but also aliphatic aldehydes and even the parent formaldehyde. Despite the diminished electrophilic reactivity of aldimines, the reaction is complete at room temperature within a reasonable reaction time. The reaction of aldimines proceeds in an opposite sense of stereoselectivity to that of aldehydes and selectively provides 1,3-syn isomers 57. 

One aspect of asymmetric catalysis has become clear. Every part of the molecule seems to fulfill a role in the process, just as in enzymic catalysis. Whereas many of us have been used to simple acid or base catalysis, in which protonation or proton abstraction is the key step, bifunctional or even multifunctional catalysis is the rule in the processes discussed in this chapter.Thus it is not only the increase in nucleophilicity of the nucleophile by the quinine base (see Figures 6 and 19), nor only the increase in the electrophilicity of the electrophile caused by hydrogen bonding to the secondary alcohol function of the quinine, but also the many steric (i.e., van der Waals) interactions between the quinoline and quinuclidine portions of the molecule that exert the overall powerful guidance needed to effect high stereoselection. Important charge-transfer interactions between the quinoline portion of the molecule and aromatic substrates cannot be excluded. 

Nitrile oxides are widely used as dipoles in cycloaddition reactions for the synthesis of various heterocyclic rings. In order to promote reactions between nitrile oxides and less reactive carbon nucleophiles, Auricchio and coworkers studied the reactivity of nitrile oxides towards Lewis acids. They observed that, in the presence of gaseous BF3, nitrile oxides gave complexes in which the electrophilicity of the carbon atom was so enhanced that it could react with aromatic systems, stereoselectively yielding aryl oximes 65 and 66 (Scheme 35). ... 

Using this method, the electrophilic aromatic substitution of the electron-rich arylamine 578 by the molybdenum-complexed cation 577 affords regio- and stereoselectively the molybdenum complexes 579. Cyclization with concomitant aromatization and demetalation using activated manganese dioxide leads to the carbazole derivatives 568 (8,10,560) (Scheme 5.26). 

F-Teda BF4 is effective for the selective addition of fluorine to steroids in good yield, re-gioselectively and, in many cases, stereoselectively at the 6- and 16-positions, under very mild reaction conditions (Table 7).92 Further, 6 will also efficiently fluorinate silyl and alkyl enolates, enamides, carbanions, a-alkenes and actived aromatic compounds (Table 8). As an extension of this method F-Teda BF+ has been used for the electrophilic fluorination of (fluorovinyl)tin compounds affording terminal fluoroalkenes (see Table 9).88... 

This reactivity proved to be a general process, providing the unique products in moderate yields following cyclopropanation and immediate treatment with silver tetrafluoroborate. These structures revealed that a cascade sequence was proceeding stereoselectively in every case to furnish a single product as the result of conrotatory 4jt electrocyclization, electrophilic aromatic substitution at the least hindered position on the arene moiety (para to the MeO) in favor of six-membered ring formation, and desilylation with protonation from the exo face of the bicyclic product. Dehydrochlorination to form a second cationic intermediate did not occur in this case, due to structural restrictions imposed by the bridged architecture of 81. 

We talked a lot about regioselectivity two chapters ago, when you learned how to predict and explain which product(s) you get from electrophilic aromatic substitution reactions. The functional group is the aromatic ring where it reacts is the reaction s regioselectivity. Going back further, one of the first examples of regioselectivity you came across was nucleophilic addition to an unsaturated ketone. Addition can take place in a 1,2- or a 1,4-fashion—the question of which happens (where the unsaturated ketone reacts) is a question of regioselectivity, which we discussed in Chapters 10 and 23. We shall leave all discussion of stereoselectivity until Chapters 31-34. 

Arene(tricarbonyl)chromium complexes undergo a number of synthetically important transformations not usually observed for uncomplexed arenes. The chromium tricarbonyl moiety facilitates nucleophilic, electrophilic, and radical reactions at the benzylic position. Upon complexation, one side of the aromatic ring and adjacent functionalities is blocked by the metal carbonyl moiety and highly stereoselective reactions are usually observed even at relatively remote positions. In addition, the protons of the complexed aromatic ring have a substantially higher acidity and are readily removed and further substituted by electrophiles. Finally, the aromatic ring is activated toward addition reactions using a variety of nucleophiles. 

A variety of common electrophiles can be used in conjunction with deprotonation of the benzylic position of complexed aUcylbenzenes. This includes alkyl iodides, aldehydes, ketones, and epoxides. Mitosanes can be prepared by deprotonation of the tricyclic complex (52) followed by addition of oxirane (Scheme 92). Depending on the substituent on the complexed aromatic ring, both regio-and stereoselective benzylic alkylations are observed. For example, deprotonation and alkylation of the benzylic position meta to the dimethylamino group of (53) is exclusively observed (Scheme 93). 

The same chiral auxiliary has also been used for the stereoselective synthesis of arene-chromium complexes treatment of an aromatic aminal with chromium hexacarbonyl gives the corresponding complex with high diastereomeric excess. This protocol was recently applied in a total synthesis of (—)-lasubine (eq 4). A successful application of 1,2-diaminocyclohexane (as its IR,2R enantiomer) as a chiral auxiliary is illustrated by the di-astereoselective alkylation of the potassium enolate of bis-amide (3) with electrophiles such as benzyl bromide to give bis-alkylated products with excellent diastereoselectivity (eq 5). Lower levels... 

Chiral oxazolidinone auxiliaries based on D-glucose were used for aldol reactions by Koell et al. [160]. The highest select vities were observed with auxiliaries equipped with the pivaloyl protecting group. The pivaloylated oxazolidinone 228 was transformed into the boron enolate according to the procedure of Evans [161] and subsequently reacted with aliphatic and aromatic aldehydes. The best results were obtained with isobutyric aldehyde (Scheme 10.77). The syn-dldo 229 was formed in 16-fold excess over the a/i Z-diastereomer and with an acceptable yield of 59%. The authors explain the stereoselectivity by a chair-like transition state according to Zimmermann-Traxler. The electrophile approaches at the less hindered r -face of the (Z)-configured enolate double bond. For A -phenacetyl substituents, an inversed stereoselectivity was observed as described above for these oxazolidinone auxiliaries. 

This chapter is also about functionalisation. But it deals with the addition of a difficult electrophile ( RO+ ) to familiar nucleophiles aromatic compounds, including the pyridines of chapter 32, and enols and enolates. As well as the difficulties of creating suitable reagents that control chemo- and regioselectivity, stereoselectivity and asymmetric induction are important. 

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